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BRITISH ASSOCIATION

FOR THE ADVANCEMENT
OF SCIENCE

REPORT

OF THE

ANNUAL MEETING, 1933
(103rp YEAR)

EEICESTER
SEPTEMBER 6-13

LONDON

OFFICE OF THE BRITISH ASSOCIATION
BURLINGTON HOUSE, LONDON, W.1

1933

bie

a BAAN ay aE

ill

CONTENTS.

PAGE
PMMCHHSEAND COUNCIL: TO33—34 oss sisters Aicivlare sc ois G vip lac cise sere Vv
SECTIONAL OFFICERS, LEICESTER MEETING, 1933 ..............-- ix

ANNUAL MEETINGS: PLACES AND DATES, PRESIDENTS, ATTENDANCES,
Receipts, SuMs PaID ON ACCOUNT OF GRANTS FOR SCIENTIFIC

EREOSESE(LSST—FOS9)iaionions wisrolsccis a's seisiata cr stemleaiem StavewlGvan liek xii
FNSTALEATION OF THE, PRESIDENT.(.\¢ 0 fcc. 8 custo ee vtne dou lee tees XVi
NARRATIVE OF THE LEICESTER MEETING ................0-00000- XVil
REPORT OF THE COUNCIL TO THE GENERAL COMMITTEE (1932-33).. xix
GENERAL TREASURER’S ACCOUNT (1932-33) ...-2--eeececeeecucece XXIV
MeIMMERCED - OOMMITTERS (1933-34) < . once nee cess ce see scnece sen XXXVili
RESOLUTIONS AND RECOMMENDATIONS (LEICESTER MEETING) ....... xliv

THE PRESIDENTIAL ADDRESS :

Some Chemical Aspects of Life. By Sir FREDERICK GOwWLAND
IIOPEINS Pres RAGS sig jciecepqsisusis e..0) + foLedeaeuct® oasyars “1giep « pitherses I

SECTIONAL PRESIDENTS’ ADDRESSES :
Seasonal Weather and its Prediction. By Prof. Sir GILBERT

UAT EER SCO 5lb BERESE« sche Gis b cage seve Seis SLA ee Sele oid es 25
Natural Colouring Matters and their Analogues. By Prof. R.

HROBINSON PRIN sD sizcit« idinca sen allecatbis,s ole CekeReraiate. sibeysss levers eos 45
A Correlation of Structures in the Coalfields of the Midland

Province. By Prof. W. G. FEARNSIDES, F.R.S. .......... 57
The Mechanical View of Life. By Dr. J. Gray, F.R.S........ 81
Geography as Mental Equipment. By the Rt. Hon. Lorp

IVERSON, COGS OLY te whe da. s Kl aateibalniete asia wih Si Seteca uilgrebers 93
ane Gold’ Standard. By Prof. J. H. JonEs .........0.....0-: 109
Some Experiences in Mechanical Engineering. By R. W. ALLEN,

Se PRU NS Ructh are intare weyanne won SCT TS RRS oO See ees 129
What is Tradition? By the Rt. Hon. Lorp RaGLan.......... 145

The Activity of Nerve Cells. By Prof. E. D. AprIAN, F.R.S... 163

iv CONTENTS

PAGE

The Status of Psychology as an Empirical Science. By Prof. F.
PAVRTCING) 3-52 ov da evevandt ain Ope! «ste, al OMe enw cat nelohesd eke Lonaremie ts 17

The Types of Entrance Mechanisms of the Traps of Utricularia.
| EAUOLET (Oy Beal Dey) chal 1 og DRE en aise I RADY AL Gita 5 tkin So Sc 183

The Development of the National System of Education. By
Wee PETOLUAND a. e terns oie cic tin eae reas Ane es ery Ei Sek 219
Chemistry and Agriculture. By Dr. A. LAUDER.............. 243
IREPORTS ON ‘THE SEATE OF SCIENCE, (ETC, 9-2 nae... s\s + = ls eee 265
SECTIONAL) URANSAGIIONS rs ofors' 216 <' sfa\e =e ete acts ~ ohepeht = Sletten 427
HB VENTING DISCOURSES (sais aleve cue e)a) +(e leveie) = ote win ayeie) «, 9 «le eka eee etait eee 578
CONFERENCE OF DELEGATES OF CORRESPONDING SOCIETIES ........ 589

On Prant GrowTH Hormones (Auxin-a and Auxin-6). By Prof.
Dr AIS OGCU oars aero 3s 2 naeliced SEG IP =< SC He - aa ae 600

REFERENCES TO PUBLICATION OF COMMUNICATIONS TO THE SECTIONS 610

APPENDIX.

A ScIENTIFIC SURVEY OF LEICESTER AND DISTRICT .............. I-100

British 2

Association for the Adbancement

of Science,

The Lorp LIEUTENANT OF LEICESTER-
SHIRE (Sir ARTHUR HazLeErRicG, Bt.,

er.).

The Rt. Worshipful the Lorp Mayor
oF LEIcESTER (Councillor ARTHUR
Hawkes, J.P.).

‘The Lorp BisHop oF LEICESTER (The
Rt. Rev. C. C. B. Barpsiey, D.D.).

e Hicu SHERIFF OF LEICESTERSHIRE
(Joun H. Coray).

is Grace the DUKE oF RUTLAND.
The Rt. Hon. the Eart FERRERS, F.S.A.

e VISITOR OF UNIVERSITY COLLEGE,
LEICESTER (Prof. GILBERT MURRAY,
MOA, LD. D.Litt.) E.BrA.).

OFFICERS & COUNCIL, 1933-34.

PATRON.
HIS MAJESTY THE KING.

PRESIDENT, 1933.
Sir FREDERICK GOWLAND Hopkins, D.Sc., Sc.D., LL.D., Pres.R.S.

PRESIDENT, 1934.

Sir WILLIAM BaTE Harpy, F.R.S.

VICE-PRESIDENTS FOR THE LEICESTER MEETING.

The PRINCIPAL OF UNIVERSITY COL-
LEGE, LEICESTER (F. L. ATTEN-
BOROUGH, M.A.).

The PRESIDENT OF THE LEICESTER
LITERARY AND PHILOSOPHICAL
Society (H. Percy GEE, J.P.).

Col. C. J. Bonp;, €.M:G.) FE UR.C:S.

Councillor AsTLEY V. CLARKE, M.A.,
MED DAs) .P:

Major E. G. GILLiLan.
Lt.-Col. R. E. Martin, C.M.G., M.A.,
D.L.

Alderman Sir JONATHAN NortH, D.L.,
zP;

The Rev. BERNARD UFFEN, A.T.S.

OFFICERS AND COUNCIL

VICE-PRESIDENTS ELECT FOR THE ABERDEEN MEETING, 1934.

vi

The Hon. the LorD PROvosT OF
ABERDEEN (HENRY ALEXANDER,
PS McA).

The PRINCIPAL AND VICE-CHANCELLOR
OF THE UNIVERSITY OF ABERDEEN
(Sir GEORGE ADAM SmitH, D.D.,
DE eittalb). Jb BcAs).

The Most Hon. the
ABERDEEN AND TEMAIR,
G.C.M.G., G.C.V.O., K.T.

The Rt. Hon. the Eart oF CAITHNESS,
CBE EE. Dy pk:

The Rt. Hon. the Viscount ARBUTH-
NOTT.

The Rt. Hon. Lorp Mzsron, K.C.S.I.,
ELD:

Sir THOMAS JAFFREY, Bart., LL.D.
Sir RoBERT WILLIAMS, Bart., D.L.,

12 (Or

MARQUIS OF |

Sir GoprrEy P. Cortins, K.B.E.,
C.M.G., M.P.

Sir ARTHUR KEITH, LL.D., D.Sc.,
BRIS:

Sir GEORGE ABERCROMBY, Bart., D.S.O.
Prof. Sir JoHn Marnocu, K.C.V.O.,
D.L.

Sir ASHLEY W. MackIntTosH, K.C.V.O.,
LED:

Sir ALEXANDER MACEWEN.

| James R. Rust, LL.D.

CHARLES Murray, C.M.G., LL.D.

Prof. H. M. Macpbona.p, F.R.S.

Prof. J. J. R. Macteop, D.Sc., LL.D.,
PRES!

Prof. J. A. MacWiriiam, LL.D.,
Bike:
Dr: J.B: Orr, DS OF Discs eh ks.

Prof. R. W. Rerp, LL.D.

GENERAL TREASURER.

Sir Jostan Stamp, G.B.E., D.Sc.,

F.B.A.

GENERAL SECRETARIES.

Protech. STRATTON, D.S.O.,| Prof. P. G. H. BosweE tt, O.B.E., D.Sc.,
O.B.E., M.A IEERESE
SECRETARY.

O. J. R. Howartn, O.B.E., Ph.D.

ASSISTANT SECRETARY.
H. Woo.LpripcE, B.Sc.

ORDINARY MEMBERS OF THE COUNCIL.

Prof. F. AVELING.

Dr. F. A. BatHer, F.R.S.

Prof. R. N. RupMosE Brown.
Prof. F. BALFouR BROWNE.

Sir Henry DALE, C.B.E., F.R.S.
Prof. J. DREVER.

Dr. A. FERGUSON.

Prof. R. B. FoRRESTER.

Sir HENRy Fow er, K.B.E.
Prof. W. T. Gorpon.

Prof. Dame HELEN GWYNNE-VAUGHAN,

G.B.E.
Dr. H. S. Harrison.

Sir JAMES HENDERSON.

Prof. G. W. O. Howe.

Dr. C. W. KIMMINsS.

Sir P. CHALMERS MITCHELL, C.B.E..,,
Bese

Dr. C. Tate Recan, F.R.S.

Sir Joun Russe Lt, O.B.E.,

Dr. N. V. SIDGWICcK, E.RS.

Dr. G. C. Stimpson, C.B., F.

Prof. J. F. THORPE, CBE

H. T. Tizarp, C.B., F.R.

Prof. A. M. TYNDALL, 18),

Dr. J. A. VENN.

3

Se
R.

Prof. F. E. Weiss, F.R.S.

OFFICERS AND COUNCIL Vii

EX-OFFICIO MEMBERS OF THE COUNCIL.

Past Presidents of the Association, the President for the year, the President
and Vice-Presidents for the ensuing Annual Meeting, past and present General
Treasurers and General Secretaries, and the Local Treasurers and Local Secretaries
for the Annual Meetings immediately past and ensuing.

PAST PRESIDENTS OF THE ASSOCIATION.

Sir J. J. THomson, O.M., F.R.S. H.R.H. The Prince oF Watks, K.G.,
Sir E. SHARPEY-SCHAFER, F.R.S. DiGee BRAS:

Sir OLIVER LopGE, F.R.S. | Prof. Sir ARTHUR KEITH, F.R.S.

Sir ARTHUR SCHUSTER, F.R.S. | Prof. Sir WiLtt1am H. Brace, O.M.,

Sir ARTHUR Evans, F.R.S. eG ABa oy TRS
Prof. Sir C. S. SHERRINGTON, O.M., | Sir THomas H. Horranp, K.C.I.E.,

GBB OE UR:S: | K.C.S.1., F.R.S.
Prof. The Rt. Hon. Lorp RUTHERFORD | Prof. F. O. Bower, F.R.S.

oF NEtson, O.M., F.R.S. | Gen. The Rt. Hon. J. C. Smuts, P.C.,
Prof. Sir Horace Lams, F.R.S. hGe ling MES ReS

Sir ALFRED [-wine, K.C.B., F.R.S.

PAST GENERAL OFFICERS OF THE ASSOCIATION.

Sir E. SHARPEY-SCHAFER, F.R.S. Sirk, EAsSMITEH. heG.st,; Cobi..1SeC.
Dr. D. H. Scott, F.R.S. RES:
Prof. J. L. Myres, O.B.E., F.B.A.

HON. AUDITORS.
Prof. A. L. BowLrey. | Prof. W. W. Warts, F.R.S.

HON. CURATOR OF DOWN HOUSE.
Sir BucKsTON BrRowngE, F.R.C.S., F.S.A.

LOCAL OFFICERS
FOR THE LEICESTER MEETING.

CHAIRMAN OF LOCAL GENERAL COMMITTEE.
Alderman Sir JonaTtHAaN Nortu, D.L., J.P.

CHAIRMAN OF LOCAL EXECUTIVE COMMITTEE.
Col. C. J. Bonn, C.M.G., F.R.C.S.

LOCAL HON. SECRETARIES. LOCAL GENERAL SECRETARY.
F. P. ArmitacE, C.B.E., M.A. H. Purr, A.C.LS.
Coutn D. B. Ettis, M.C., M.A. i

LOCAL HON. TREASURERS.
H. A. PRITCHARD. | Gopls CAGISADD; | JjsE:

viii OFFICERS AND COUNCIL

EQUIPMENT OFFICER. | TRANSPORT OFFICER.
J. O. THompson. | J. M. Krrxwoop.
CHAIRMEN OF SUB-COMMITTEES.

FINANCE - - - - H. Percy GEE, J.P.

PUBLICATIONS) - - - T. Kinepom, M.A.

HOSPITALITY )

Mua - - ASTLEY V. CLaRKE, M.D., D.L., J.P.
ENTERTAINMENTS - - Alderman CHARLES SQUIRE.
EXCURSIONS - - - W. Keay, F.R.I.B.A., M.Inst.C.E.

LOCAL OFFICERS
FOR THE ABERDEEN MEETING.

CHAIRMAN OF LOCAL GENERAL COMMITTEE.
The Hon. the Lord Provost oF ABERDEEN (HENRY ALEXANDER, M.A.).

VICE-CHAIRMAN OF LOCAL GENERAL COMMITTEE.
The PRINCIPAL AND VICE-CHANCELLOR OF THE UNIVERSITY OF ABERDEEN
(Sir GEorGE ADAM SmitTH, M.A., D.D., LL.D., D.Litt., F.B.A.).

LOCAL HON. SECRETARIES. | LOCAL GENERAL SECRETARY.
Lt.-Col. Epwarp W. Watt, T.D.,M.A. | D. B. Gunn, M.B.E., M.A., LL.B.
Prof. H. M. Macponartp, O.B.E., |

|

M.A., F.R.S.
LOCAL HON. TREASURER. LOCAL TREASURER.
Marianus Lunan, J.P. InR=aG. Dursin;Ay-Re, Pov

OFFICERS OF SECTIONS, 1933 ix

SECTIONAL OFFICERS.

A.—MATHEMATICAL AND PHYSICAL SCIENCES.

President.—Sir G. T. WALKER, C.S.I., F.R.S.

Vice-Presidents.—Prof. H. L. Bross, Prof. E. H. NEvILLE, Prof. J. J. Noran,
Prof. A. O. RANKINE, O.B.E., W. Taytor, O.B.E.

Recordey.—Dr. ALLAN FERGUSON.

Secretaries —M. G. BENNETT, Dr. EzER GRIFFITHS, F.R.S., Dr. R. O. REDMAN,
Dr. D. M. Wrincu.

Local Secretavy.—Dr. L. G. H. Huxiey.

B.—CHEMISTRY.

President.—Prof. R. Roprinson, F.R.S.

Vice-Presidents—Dr. E. F. ArMstTRoNG, F.R.S., S. F. Burrorp, Prof. T. M.
Lowry, C.B.E., F.R.S., Dr. W. H. Mitts, F.R.S., Prof. J. C. Poitip, O.B.E.,
F.R.S., Dr. F. L. Pyman, F.R.S., Rt. Hon. Lord TRENT.

Recordey.—Prof. T. S. Moore.
Secretavies.—Prof. J. E. Coates, Dr. J. M. GuLLanp.
Local Secretary. —Dr. L. HuNTER.

C.—GEOLOGY.

President.—Prof. W. G. FEARNSIDES, F.R.S.

Vice- Presidents —Prof. P. G. H. BoswELt, O.B.E., F.R.S., Prof. W. S. Bourton,
W. Keay, Dr. E. E. Lower, Dr. Bernarp Smita, F.R.S., Prof. H. H.
SWINNERTON, Prof. L. J. WILts.

Recordey.—Dr. A. K. WELLs.

Secretavies—B, HiLToN Barrett, Dr. H. C. VERSEY.

Local Secretayy.—H. .H. GrEGory.

D.—ZOOLOGY.

President.—Dr. J. Gray, F.R.S.
Vice-Presidents —Col. C. J. Bonn, C.M.G., Dr. E. E. Lowe, Dr. TH. MorTENSEN,
Rt. Hon. Lord RotuscuHixLp, F.R.S.
Recorder.—G. L. Purser.
Secretary.— Prof. W. M. -TATTERSALL.
Local Secretayy.—Mrs. HUNTER.

E.—GEOGRAPHY.

President.—Rt. Hon. Lord Meston, K.C.S.I.

Vice-Presidents—Dr. P. W. Bryan, Prof. F. DEBENHAM, Prof. H. J. FLEuRE,
Sir Epwarp A. Gait, K.C.S.I., C.LE., Prof. J. L. Myres, O.B.E., H. H.
PEACH. ene one / : ‘

Recorder—H. Kine. ;

Secretaries —J. N. L. Baxer, Dr. R. O. BucHanan,

Local Secretary.—Miss G. M. Sarson.

x OFFICERS OF SECTIONS, 1933

F.—ECONOMIC SCIENCE AND STATISTICS.
President.—Prof. J. H. Jones.

Vice-Presidents —Prof. R. B. FoRRESTER, Prof. H. M. Hatiswortu, C.B.E.,
R. F. Harrop, A. RADFORD, R. V. RODWELL, Prof. J. G. SMITH.

Recordey.—Dr. K. G, FENELON.

Secretaries.—Dr. J. A. Bowtz, Dr. P. Forp,

Local Secretary.—H. A. SILVERMAN.

A Department of Industrial Co-operation—Chaiyman, Dr. J. A. BowiE ; Secretary,

R. J. Mackay—arranged a special programme in connection with this and
other Sections.

G.—ENGINEERING.
President.—R. W. ALLEN, C.B.E.

Vice-Presidents.—Lt.-Col. E. Kitson Crarx, L. W. KeEersHaw, W. TAYLor,
O.B.E., Prof. MILES WALKER, F.R.S.

Recordey.—]. S. WILson.
Secretavies—Dr. S. J. DAvizs, J. E. MONTGOMREY.
Local Secretary.—T. STANFORD GRIFFIN.

H.—ANTHROPOLOGY.
President.—Rt. Hon. Lord RAGLan.
Vice-Presidents —M. C. BuRKITT, Prof. V. GoRDON CHILDE, Dr. CyRit Fox,
Prof. R. RuGGLEs Gates, F.R.S., Dr. MARGARET A. MURRAY.
Recordey.—Miss R. M. FLEMING.

Secretaries—Dr. S. Bryan ApDams, Prof. C. DARYLL FoRDE (acting), V. E.
NASH-WILLIAMS.

Local Secretary.—Dr. N. I. SpRiaes.

I.— PHYSIOLOGY.
President.—Prof. E. D. ADRIAN, F.R.S.
Vice-Presidents.—Col. C. J. Bonp, C.M.G., Sir Henry Date, C.B.E., Sec.R.S.,
Prof. H. HARTRIDGE, F.R.S., Prof. H. E. Roar, Prof. R. Rosison, F.R.S.
Recordey.—Prof. R. J. BRocKLEHURST.
Secretary.—Dr. F. J. W. RouGuton.
Local Secretary—Dr. R. McD. Catrns.

J.—PSYCHOLOGY.
President.—Prof. F. AvVELING.

Vice-Presidents.—Dr. SHEPHERD Dawson, Prof. BEATRICE EDGELL, E. FARMER,
Dr. Lt. Wynn Jones, Prof. K. Lewin, Prof. E. C. TOLMAN.

Recordey—Dr. Mary COoLttins.

Secretavy.— Dr. S. J. F. Puirport.

Local Secretayy.—Mrs. N. M. BARNES.

K.—BOTANY.
President.— Prof. F. E. Lioyp.

Vice-Presidents.—Maj. the Hon. RicHarpD Coxe, Prof. J. H. Priestiry, Dr.
E. N. Mites THOMAS,

Recordey.—Prof. H. S. HotpeEn,

Secretaries —Dr. B. Barnes, Dr. E. V. Laine, Miss L. I. Scorr.

Local Secyetayy.—Dr. E. J. B. Bisu.

OFFICERS OF SECTIONS, 1933 xi

L.—EDUCATIONAL SCIENCE.
President.—J. L. HOLLAND.
Vice-Presidents—Principal F. L. ATTENBOROUGH, W. M. HELLER, Principal
H. Stewart, C.M.G.
Recovdey.—G. D. DUNKERLEY.
Secretaries —S. R. HumBy, Miss HELEN MASTERS.
Local Secretary —W. A. BROCKINGTON, C.B.E.

M.—AGRICULTURE.
President.—Dr. A. LAUDER.

Vice-Presidents—Ald. P. F. Astitt, J. M. Catz, Dr. T. MILBuRN, ALFRED
TuRNER, Prof. R. G. WHITE.

Recordey.—Dr. E. M. CROWTHER.
Secretary W. GODDEN.
Local Secretary —T. HAckKING.

CONFERENCE OF DELEGATES OF CORRESPONDING
SOCIETIES.

President—Dr. R. E. MorTIMER WHEELER.
Secretary.— Dr. C. TIERNEY.
Local Secretary —W. K. BEDINGFIELD.

xil ANNUAL MEETINGS

TABLE OF

|
Date of Meeting Where held Presidents One alls
|

1831, Sept. 27...... | York ... | Viscount Milton, D.C.L., F.R.S. —_ —
1832, June 1g ...| Oxford ..... --| The Rev. W. Buckland, F.R.S._ ...... -- _
1833, June 25 ...| Cambridge .. The Rev. A. Sedgwick, F.R.S. ......... = _—
1834, Sept. 8 | pene | Sir T. M. Brisbane, D.C.L., F.R.S. ...) ,— =
1835, Aug. Dublin.. | The Rev. Provost Lloyd, L LL.D.,F.R.S. _ oo
1836, Aug. Bristol..... ...| The Marquis of Lansdowne, F.R.S. ... —_ _
1837, Sept. |) Liverpool), ....2-<s<5<: The Earl of Burlington, F.R.S.......... = _
1838, Aug. Newcastle-on-Tyne | The Duke of Northumberland, F.R.S. _ —_—
1839, Aug. | Birmingham ......... | The Rev. W. Vernon Harcourt, F.R.S. —_ a
1840, Sept. 17 ....| Glasgow ..... The Marquis of Breadalbane, F.R.S. os _—
1841, July 2o...... Plymouth . The Rev. W. Whewell, F.R.S. . 169 65
1842, June 23...... Manchester. .| The Lord Francis Egerton, HGS 303 169
1843, Aug. 17 ...... Cork:....<.. .| The Earl of Rosse, F.R.S. ..........-.+4- 109 28
1844, Sept. 26......| York ..... | The Rev. G. Peacock, DD., EF: Rese. 226 150
1845, June 1g ...| Cambridge .. . Sir John F, W. Herschel, Bart. Fale RS. 313 36
1846, Sept. Io...... Southampton | .| Sir Roderick I. Murchison, Bart.,F.R.S.| 241 Io
1847, June 23 ...| Oxford.......... ...| Sir Robert H. Inglis, Bart., F.R.S. ...| 324 18
1848, Aug. 9 ...... Swansea ....... ...| The Marquis of Northampton, Pres.R.S. 149 3
1849, Sept. 12 Birmingham .........| The Rev. T. R. Robinson, D.D.,F.R.S. 227 12
1850, July 21 ......| Edinburgh .... Sir David Brewster, K. igh F.R. 8 Beene 235 9
1851, July 2 .| Ipswich .. ...| G. B. Airy, Astronomer Royal, F.R.S. 172 8
1852, Sept. 1 Belfast... ...| Lieut.-General Sabine, F.R.S. . 164 Io
1853, Sept. 3 ...... Ve Gi beer ...| William Hopkins, F.R.S........... I4I 13
1854, Sept. 20...... Liverpool .. The Earl of Harrowby F.R.S. . wale 23
1855, Sept. 12...... Glasgow ....... | The Duke of Argyll, F.R.S. ............ 194 33
1856, Aug. 6 ...... Cheltenham . | Prof.C.G.B.Daubeney, M.D., F.R.S. . 182 14
1857, Aug. 26...... Dubbin< 23.22: The Rev. H. Lloyd, D.D., F. RS. 236 15
1858, Sept. 22...... eedSs =. .25405 ...| Richard Owen, M.D., D. (es 1 Ree SS 222 42
1859, Sept. 14...... Aberdeen “| HLR.H. The Prince Consort ......-.++- 184 27
1860, June 27_ ...| Oxford ..... ..., Che Lord Wrottesley, M.A., F.R.S. ... 286 21
L861; Sept. 4. s----s Manchester.. ili irbai 321 113
TRG e OCLs S, — s.0e8 Cambridge 239 15
1863, Aug. 26......| Newcastle-on-Tyne | Sir William G. Armstrong 203 36
1864, Sept. 13...... SAE cocesnctcseneess ted Sir Charles Lyell, Bart., 287 40
1865, Sept. 6 ...... Birmingham . ...| Prof. J. Phillips, M.A., u: 292 44
1866, Aug. 22...... Nottingham . .... William R. Grove, Q. Ge F. 207 31
1867, Sept. 4 ...... Dundee ..... ...| The Duke of Buccleuch, K Ter 167 25
1868, Aug. 19...... Norwich .. ..| Dr. Joseph D. Hooker, F.R. 196 18
1869, Aug. 18 Exeter .. .| Prof. G. G. Stokes, D.C.L., 204 21
1870, Sept. .| Liverpool .. 23|\ Prof. at. ED. Huxley, RL.D., F: 314 39
| 1871, Aug. .| Edinburgh ...| Prof. Sir W. Thomson, LL.D., 246 28
1872, Aug. | Brighton ..... ...| Dr. W. B. Carpenter, F.R.S.. 245 36
1873, Sept. Bradford .| Prof. A. W. Williamson, F. 212 27
1874, Aug ..| Prof. J. Tyndall, LL.D., F. 162 13
1875, Aug. .., Sir John Hawkshaw, F.R.S. 239 36
1876, Sept. .| Prof. T. Andrews, M.D., F. 221 35
| 1877, Aug. Prof. A. Thomson, M.D., 173 19
| 1878, Aug. ...| W. Spottiswoode, M.A., F. R. 201 18
| 1879, Aug. ...| Prof. G. J. Allman, M.D., F.R. 184 16
1880, Aug. ..| A. C. Ramsay, LL. -D., FLR-S: *aietatene 144 Ir
| 1881, Aug. | Sir John Lubbock, Ba irt. A GB) Se 272 28
| 1882, Aug. | Dr. C. W. Siemens, ERS, oa 178 17

| 1883, Sept. Prof. A. Cayley, D.C.L., 203 |
| 1884, Aug. .| Prof. Lord perieach, F, R.S 235 20
1885, Sept. Sir Lyon Playfair, K.C.B. 225 18
1886, Sept. ..| Sir J. W. Dawson, C.M.G. 314 25
1887, Aug. Manchester .. ..| Sir H. E. Roscoe, Dic ; 428 86
1888, Sept. (BACH) 5 Mee, peer eree Sir F. J. Bramwell, F.R.S. 266 36
1889, Sept. Newcastle-on-Tyne | Prof. W. H. Flower, eae 277 20
1890, Sept. BECUS ioc cacasnscnatnenes Sir F. A. Abel, C.B., F.R. 259 21
1891, Aug. Cardiff Dr. W. Huggins, F.R.S. ... 189 24
1892, Aug. Edinburgh .. Sir A. Geikie, LL.D., F.R. : 280 14
| 1893, Sept. ae Nottingham. ae| Prof, 70S. Burdon Sanderson, F. : 201 17
1894, Aug. Oxford ..... ..| The Marquis of Salisbury, K.G., F.R.S. 327 2i
1895, Sept. Ipswich ..| Sir Douglas Galton, K.C.B., F.R.S... 214 13
1896, Sept. Liverpool ..| Sir Joseph Lister, Bart., Pres, RSs. 330 31
1897, Aug. Toronto -.| Sir John Evans, K.C.B., F.R.S. ...... 120 8
1898, Sept. Bristol ... eo oir W.. jronkes, FIRS. G.vccasavcseunensba 281 19

1899, Sept. PYOVED ny ccceadateeredess Sir Michael Foster, K.C.B.,Sec. R.S. ... 296 20. |

* Ladies were not admitted by purchased tickets until 1843. + Tickets of Admission to Sections only.
[Continued on p. xiv.

ANNUAL MEETINGS Xiii

ANNUAL MEETINGS.

Sums paid
Old INEWIO|) 4-5: ne on account
Annual | Annual fat Ladies | Foreigners} Total Pet of Grants Year
Members| Members| “'°S Tickets for Scientific
Purposes
_ _— = =- _ 353 == = 1831
— —_— _— — => > = — 1832
—_— _ _ = _ goo = — 1833
_ _ — _ _— 1298 _— £20 0 0 1834
— —_— —_ _ _ _ = 167 0 oO 1835
— —_ _— _ —_ 1350 — 435 0 0 1836
— = _ _ _ 1840 =— g22 12 6 1837
— — — 1too* _— 2400 —_ Q32. (2 2 1838
== on == ae 34 1438 2 1595 II oO 1839
-— = —_ —_— 40 1353 — 1546 16 4 1840
46 317 —_— 60* — 891 _ 1235 I0 11 1841
75 376 33t 331* 28 1315 2S 1449 17 8 1842
185 _ 160 _- — = 1565 I0 2 1843
45 190 ‘ot 260 —_ _— _ 981 12 8 1844
94 22 407 172 35 1079 = 831 9 9 1845
6 39 270 196 36 857 —_— 685 16 o 1846
197 40 495 203 53 1320 aii 208 5 4 1847
54 25 376 197 15 819 £707, 0 0| 275 ir 8 1848
33 447 237 22 1071 963 0 oO} 159 19 6]. 1849
42 510 273 44 1241 1085 0 o| 345 18 o 1850
47 244 I4I 37 710 620 0 o 391 9 7 1851
60 510 292 9 1108 1085 0 o| 304 6 7 1852
57 367 236 6 876 903 0 oO 205 0 oO 1853
121 765 524 10 1802 1882 0 o 380 19 7 1854
IOI 1094 543 26 2133 23Ir Oo © 480 16 4 1855
48 412 346 9 III5 1098 0 oO 734 13 9 1856
120 goo 569 26 2022 2015 0 oO 507 15 4 1857
gI 710 509 13 1698 I93I 0 O 618 18 2 1858
179 1206 821 a2: 2564 2782 0 0 684 Ir 1 1859
59 636 463 47 1689 1604 0 Oo 766 19 6 1860
125 1589 791 15 3138 3944 0.0] IIII 5 10 1861
57 433 242 25 1161 1089 oO oO] 1293 16 6 1862
209 1704 1004 25 3335 3640 0 o | 1608 to 1863
103 I11g 1058 13 2802 2965 0 oO] 1289 15 8 1864
149 766 508 23 1997 2227 0 0 | T5917 'I0 1865
105 * g60° 771 It 2303 2469 0 0] 1750 13 4 1866
118 1163 771 z 2444 2613 0 0] 1739 4 oO 1867
II7 720 682 45t 2004 2042 0 0] 1940 0 O 1868
107 678 600 17 1856 I93I 0 oO| 1622 0 Oo 1869
195 II03 910 14 2878 3096 0 o| 1572 0 Oo 1870
127 976 754 21 2463 2575 © o| 1472 2 6 1871
80 937 912 43 2533 2649 0 0| 1285 0 oO 1872
99 796 601 It 1983 2120 0 0} 1685 0 0 1873
85 817 630 12 I95I 1979 © O| 1151 16 oO 1874
93 884 672 17 2248 2397 0 0 960 0 Oo 1875
185 1265 712 25 2774 3023 0 0 | 1092 4 2 1876
59 446 283 Ir 1229 1268 0 o|] 1128 9 7 1877
93 1285 674 17 2578 2615 0 Oo 725 16 6 1878
74 529 349 13 1404. 1425 © 0| 1080 11 11 1879
4 389 147 12 915 899 0.9] 731.7 7 1880
176 1230 514 24 2557 2689 0 oO 476 8 1 1881
79 516 189 21 1253 1286 0 o| 1126 111 1882
323 952 841 5 2714 | 3369 0 0] 1083 3 3] 1883
219 826 74 26&60H.§) 1777 1855 0 oO] 1173 4 0 1884
122 1053 447 6 2203 2256 o o| 1385 0 Oo 1885
179 1067 429 II 2453 2532 10) 0 995 0 6 1886
244 1985 493 92 3838 4335 o o|} 118618 o 1887
100 639 509 12 1984 2107" Go |) T5rr" 6 "5 1888
113 1024 579 21 2437 244I O OO] 1417 OIL 1889
92 680 334 12 1775 1776 0 Oo 789 16 8 1890
152 672 107 35 1497 1664 0 o| 1029 I0 Oo 1801
I4I 733 439 50 2070 2007 0 0 864 10 o 1892
57 773 268 17 1661 1653 0 Oo 907 15 6 1893
69 941 451 77 232 | 2175 © o| 58315 6] 1894
31 493 261 22 1324 1236 0 Oo 97715 5 1895
139 1384 873 41 3181 3228 0 o|] 1104 6 I 1896
125 682 100 41 1362 1398 0 o| 1059 10 8 1897
96 1051 639 33 2446 2399 © O| 1212 0 0 1898
68 548 120 27 1403 1328 o o| 1430 14 2 1899

t IncludingLadies. § Feliows of the American Association were admitted as Hon. Members for this Meeting.
b [Continued on p. xv.

ANNUAL MEETINGS

Table of

Date of Meeting Where held Presidents tia teats
1900, Sept. 5 ...... eadtord), wss.2:-050s-3 Sir William Turner, D.C.L., F.R.S. ...| 267 13
rgor, Sept. I1...... Glasgow ..... Prof. A. W. Riicker, D.Sc., Sec. R.S. 310 37
1902, Sept. I0...... Belfast ..... ....| Prof. J. Dewar, LL.D., F.R.S. ......... 243 21
1903, Sept. 9 ...... Southport .. .| Sir Norman Lockyer, K.C.B., F.R.S. 250 21
1904, Aug. I7...... Cambridge ..... Rt. Hon.A. J. Balfour, M.P.,F.R.S....| 419 32
1905, AU. 15.....- South Africa .. Prof. G. H. Darwin, LL.D., F.R.S. ... II5 40
1906, Aug. I ...... ODI Neco creas Prof. E. Ray Lankester, LL.D., F.R.S. 322 10
1907, July 31...... Leicester ...| Sir David Gill, K.C.B., F.R.S. ......... 276 19
1908, Sept. 2 ...... Dublin........ .| Dr. Francis Darwin, FERS. . 294 24
1909, Aug. 25...... Winnipeg Prof. Sir J. J. Thomson, F. 117 13
Igio, Aug. 31...... Sheffield ........ Rev. Prof. T. G. Bonney, F. 293 26
1gt1, Aug. 30...... Portsmouth .. Prof. Sir W. Ramsay, K.C. 284 21
1912, Sept. 4 ......| Dundee ........ ....| Prof. E. A. Schafer, F.R.S. 288 14
1913, Sept. 1o......| Birmingham "| Sir Oliver J. Lodge, F.R.S. . 376 40
1914, July-Sept. | Australia..... Prof. W. Bateson, F.R.S. .... 172 13
IQI5, Sept. 7 .....- Manchester Prof. A. Schuster, F.R.S. 242 19
1916, Sept. 5 ...... Newcastle-on-T yne 164 12
1917 (No Meeting) ...... Sir Arthur Evans, F.R.S. ..........-- — =
1918 (No Meeting) ...... _ _
Ig19, Sept. 9 ...... Bournemouth......... Hon. Sir C. Parsons, K.C.B., F.R.S....| 235 47
1920, Aug. 24...... @ardiff, 9... 8b seks. Prof. W. A. Herdman, C.B.E., F.R.S. 288 Ir
192m," Sept..7 <5. Edinburgh .. Sir T. E. Thorpe, C.B., F.R.S. ......... 336 9
1922, Sept. 6 ...i.. AVL O caetendavaces ene Sir C. S. Sherrington, G.B.E., Pres. R.S. 228 13
1923, Sept. 12...... iverpool) ...cc.ssss0s Sir Ernest Rutherford, F.R.S. .,....... 326 12
1924, Aug. 6 ...... BE OUONIEG | nas dnciat'es oho Sir David Bruce, K.C.B., F.R.S. 119 7
1925, Aug. 26...... Southampton ...... Prof. Horace Lamb, F.R.S. .......200++ 280 8
1926, Aug. 4 ...... Oxford Ve sceesdoc- bss ga = The Prince of Wales, K.G., g

pabeaciewesseiesemesnct eeu -muuece es 35 9

1927, Aug. 31...... TCCOS). ve cipacsecanessbas Sir Arthur Keith, F.R. s 2 ER REA ee 249 9

1928, Sept. 5 ......| Glasgow Sir William Bragg, K.B.E., F.R.S. 260 10
1929, July 22...... South Africa Sir Thomas Holland, K. Ge Ss. I.,

K.C.LE., F.R.S. Pad Sree 81 t

1930, Sept. 3 ...... BSTIStOL | pe cuyccusao ops Prof. F. O. Bower, F. R. A 221 5
1931, Sept. 23...... London ... ....-| Gen. the Rt. Hon. J. C. Smuts, P.C.,

IC CET het Ros: faatiesscohanecapdecespuabe-'e 487 14

1932, Aug. 31...... VOLK icespscas .| Sir Alfred Ewing, K.C. 3. F, R.S. 2 206 4

1944, mept. O..,..- Leicester Sir F. Gowland Hopkins, Pres. RS... 185 37

1 Including 848 Members of the South African Association.

2 Including 137 Members of the American Association.

3 Special arrangements were made for Members and Associates joining locally in Australia, see
Report, 1914, p. 686. The numbers include 80 Members who joined in oider to attend the Meeting of
L’Association Frangaise at Le Havre.

* Including Students’ Tickets, tos.

® Including Exhibitioners granted tickets without charge.

‘ied

ANNUAL MEETINGS XV

Annual Meetings—(continued).

Old New ee rhe on bs ey Slee
Annual Annual pat Ladies |Foreigners| Total for , ee Year
Members Members Tickets : niche c
8 82 9 1915 |f180r o oO /f£1072 10 Oo | 1900
aA ae ‘ni a40 20 Igi2 2046 0 0 920 9 II | Igor
an 86 647 305 6 1620 1644 0 0 947 0 O| Igo2
319 90 688 365 21 1754 1762 0 O| 845 13 2 | 1903
449 113 1338 317 121 2789 2650 0 o| 887 18 It | 1904
937" 411 430 181 16 2130 | 2422 0 0} 928 2 2 | 1905
356 93 817 352 22 1972 1811 0 0 | 882 o g | 1906
339 61 659 251 42 1647 1561 0 O 757 12 10 | 1907
465 112 1166 222 14 2297 2317 0 oO | 1157 18 8 | 1908
290! 162 789 go 7 1468 1623 0 O| 1014 9 9 | Ig09
379 57 563 123 8 1449 1439 0 0 963 17 0 | I9I0
349 61 A414 81 31 I241 1176 0 ©O| 922 0 O| Igir
368 95 1292 359 88 2504 2349 0 O 845 7 6] 1912
480 149 1287 291 20 2643 2756 0 Oo 978 17 I 1913
139 4160 539 _ 21 5044" | 4873 0 oO | 1861 16 4*| 1914
287 116 6284 141 8 1441 1406 0 0 | 1569 2 8 | 1915
250 76 251° 73 _ 826 821 0 © | 985 18 10 |} 1916
an — — = — — _ 677°T7" 2 cis
_— _ = a Si — — 326 13 3 | 191
254 102 6884 153 3 1482 1736 © O| 410 0 0O| IgI9
Annual Members
Id
sare Prayer ee ey oer Ge Stpdente
Regular eeting i . ickets
Meo te cs sid (ied Tickets
Report
136 ag2 57t 42 120 20 1380 | 1272 10 0 | 1251 13 0°] r920
133 410 1394 121 343 22 2768 2599 15 0 518 I 10 1921
go 294 757 89 235° 24 1730 1699 5 ©O| 772 O 7 | 1922
Compli-
mentary?
123 380 1434 163 550 308 3296 | 2735 15 0 | 77718 6°| 1923
37 520 1866 41 89 139 2818 3165 19 0} 1197 5 9 | 1924
264 2 II 1752 1630 5 ©} 1231 0 O| 1925
97 - 878 6 9 74 8 63
xox 453 2338 169 225 69 3722, | 3542 0 ©] 9t7 1 6| 1926
- 84 334 1487 82 264 161 2670 2414 5 O 761 10 O | 1927
76 554 1835 64 201 74 3074 | 3072 10 0 | 1259 10 0 | 1928
24 177 42274 |) — 161 83 1754 | 1477 15 0 | 1838 2 1 | 1929
68 310 1617 97 267 54 2639 2481 15 oO 683 5 7 | 1930
78 656 | 2994 157 454 449 5702"* | 4792 10 0 | 1146 7 6 | 1931
44 226 1163 45 214 125 2024 1724 5 O| 1183 13 Ir | 1932
39 236 1468 82 147 74 2268 2428 2 0 41z 19 1134) 1933

® Including grants from the Caird Fund in this and subsequent years.

? Including Foreign Guests, Exhibitioners, and others.

* The Bournemouth Fund for Research, initiated by Sir C. Parsons, enabled grants on account of
scientific purposes to be maintained.

* Including grants from the Caird Gift for research in radioactivity in this and subsequent years
to 1926.
a oe us paid in Canada were $5 for Meeting only and others pro rata; there was some gain
on, exchange.

4 Including 450 Members of the South African Association.

43 Including 413 tickets for certain meetings, issued at 5s. to London County Council school-teachers.
%* For nine months ending March 31, 1933.

INSTALLATION OF THE PRESIDENT

January 6, 1933.

On Friday, January 6, 1933, at Birkbeck College, London, on the
occasion of the joint meeting of Organising Sectional Committees,
Sir Frederick Gowland Hopkins, Pres. R.S., was installed in the
Presidency of the Association in succession to Sir Alfred Ewing, K.C.B.,
F.R.S.

Sir Alfred Ewing said that under the new statute of the Association,
which came into effect a year ago, the President came into office in
January and held it throughout the year. It was an excellent rule, for
it educated the President in the work of the Association and its various
committees before his chief duty fell to be performed at the Annual
Meeting in theautumn. There was no need for him to say how fortunate
the Association was in securing Sir Frederick Hopkins as President—a
man already so pre-eminent as to be President of the Royal Society.
Last year it had been, so to speak, the turn of that part of science which
dealt with the constitution. of non-living matter and with purely
mechanical processes, which can certainly kill, but cannot make alive.
Now they turned, perhaps with relief and greater hope, to the still more
difficult science of life—of whose fascinating problems no one could
speak with more authority and clearer discernment than Sir Frederick
Hopkins. One felt certain that in his hands the Association would lose
nothing of the public attention and interest its great annual conference
continued to command. More than ever, he believed, the public wished
to know about the advances of science—partly because these were now
confessedly tentative and incomplete, and partly also because they might
provide some guidance in the urgent perplexities of our social affairs.

It seemed not unlikely, and probably it was desirable, that in future
meetings of the Association scientists would make a more conscious
effort to relate their studies to social problems. Science was now playing
so large a part in human life, both for good and for evil, that they could
not logically stand aloof: they were bound to recognise the immense
consequence of discovery and invention, not only on man’s philosophy
but on his habits of living and his relations to his fellows. Science
had brought new powers, and with them new dangers—grave dangers
of which the community were scarcely yet aware. It was clearly the duty
of science to point these out. The first step towards escape from these
dangers was to have them fully realised.

NARRATIVE’ OF THE’ LEICESTER
MEETING.

On Wednesday, September 6, at 8.30 P.M. the Inaugural General Meeting
was held in the De Montfort Hall, when the Rt. Worshipful the Lord
Mayor of Leicester (Councillor Arthur Hawkes, J.P.) welcomed the
Association to Leicester, and the President of the Association, Sir
Frederick Gowland Hopkins, Pres. R.S., delivered an Address (for which
see p. 1), entitled Some Chemical Aspects of Life.

On Friday, September 8, in the Great Hall of Wyggeston Boys’ School,
at 8.15 P.M., Sir Josiah Stamp, G.B.E., General Treasurer. of the
Association, delivered an Evening Discourse entitled Must Science ruin
Economic Progress ? (for an abstract of which see p. 578).

On Monday, September 11, in the Lancaster Hall, at 8.15 P.m., Prof.
Jocelyn F. Thorpe, C.B.E., F.R.S., delivered an Evening Discourse,
with cinematograph and illustrations and experiments, entitled The
Work of the Safety in Mines Research Board (for an abstract of which

see p. 584).

* * * * * *

Public Lectures were given by Sir Henry Fowler, K.B.E., on Tuesday,
September 5, on Transport for a Century, and by Prof. Julian Huxley,
‘on Saturday, September 9, on Ants and Men.

* * * * * *

The Lord..Mayor and Lady Mayoress of the City of Leicester
(Councillor Arthur’ Hawkes, J.P., and Mrs. Hawkes) entertained
members of the Association at a Reception in the De Montfort Hall on
Thursday evening, September 7.

The. President (His Grace the Duke of Rutland), the Chairman
(Sir Jonathan North), the Principal and Members of the College Council
of University College, Leicester, entertained members of the Association
at a Garden Party in the grounds of University College on Monday
afternoon, September 11.

The President (Mr. H. Percy Gee, J.P.) and Council of the Leicester
Literary and Philosophical Society entertained members of the Association
at a Reception in the City Art Gallery and Museum on Tuesday evening,
September 12.

Numerous other institutions and works in the city and neighbourhood
afforded facilities and entertainment to members during the meeting.

An exhibition indicating the value of planning in connection with
modern problems in town and country was held under the joint auspices
of the Council for the Preservation of Rural England, the University
College, Leicester, and Section E (Geography) of the Association, and
helped to illustrate papers read in the Section.

XViii NARRATIVE OF THE LEICESTER MEETING

An exhibition of machinery, scientific instruments, and electrical
instruments was held in connection with Section G (Engineering), and
consisted of products of firms in Leicester and Leicestershire.

* * * * * *

A special service was held in the Cathedral on Sunday, September 10,
when officers and other members of the Association accompanied the
Lord Mayor (Councillor Arthur Hawkes) and the City Council in state
from the Town Hall. The preacher was the Rt. Rev. the Lord Bishop of
Carlisle (whose sermon was published in the Church Times, September 15).

An official Free Church service and other special services were held.
* * * * * *

On Saturday, September 9g, general excursions took place to Charnwood
Forest; Stanton Ironworks, Holwell; Kenilworth and Warwick ;
Stratford-on-Avon (where one party witnessed a performance of Macbeth
at the Memorial Theatre) ; Belvoir Castle (by kind permission of the
Duke of Rutland). Among other excursions and visits, those devoted
to the interests of special Sections are mentioned among the Sectional
Transactions in later pages.

* * * * * *

At the final meeting of the General Committee, on Tuesday,
September 12, it was resolved :

That the British Association most warmly thanks the City and County
of Leicester for their hospitable reception. It deeply appreciates the
unsparing efforts of the Lord Mayor and Corporation, and of the Local
Officers and Committees, in making arrangements for the convenience
of the meetings and for the comfort of visiting members, as also the judicious
choice and admirable organisation of the excursions. The thanks of the
Association are further due to the many institutions, works, and individuals
_ in the City and neighbourhood for their generous aid in securing the success
of the Meeting; and the support of the citizens of Leicester who have
joined the Association as members is very gratefully recognised.

On Wednesday, September 13, the President and General Secretaries
and certain other members waited upon the Lord Mayor (Councillor
Arthur Hawkes) at the Town Hall, in order to take formal leave of him
and other local officers for the Meeting.

REPORT OF THE COUNCIL, 1932-33.

OBITUARY.

I—The Council has had to deplore the loss by death of the following
office-bearers and supporters :—

Dr. G. C. Bourne, F.R.S. Sir Philip Magnus
G. R. Carline Sir Daniel Morris, K. C.M.G.
A. Chaston Chapman, F.R.S. Sir Ronald Riss; K.C.B.,
Sir Dugald Clerk, K.B.E., F.R.S. K.C.M.G., F.R.S.
Prof. T. Craib Rev. Dr. A. H. Sayce
Dr. J. E. Crombie Lt.-Col. J. Stephenson, C.I.E.,
Prof. J. C. Fields, F.R.S. F.R.S.
Sir Walter Fletcher, K.B.E., Sir J. Arthur Thomson
F.R.S. Prof. W, C. Unwin, F.R.S.
Bernard Hobson A. Silva White
Sir Everard im Thurn, K.C.M.G., Dr. A. Wilmore
C.B.

Dr. J. E. Crombie’s and Mr. Bernard Hobson’s benefactions to the
Association are referred to in a later paragraph.

REPRESENTATION.

II].—Representatives of the Association have been appointed as
follows :—
Sixth International Congress on Scientific
Management . Mr. R. J. Mackay
American Association for the Advance-
ment of Science, annual meeting,

1932-33 - Z : . Prof. W. F. G. Swann
University of London : ‘laying of founda-

tion stone of new buildings : The President
Royal Society of Teachers, conference on

research . Mr. J. L. Holland
Royal Cornwall Relytechnic Society, cen-

tenary . 5 F ‘ . Dr. G. C. Simpson,

C.B., F.R.S.

Board of Trade Discussion on Conference
of International Bureau of Weights
and Measures . ; ; F . Dr... Ezer Griffiths,
F.R.S.

RESOLUTIONS.

III.—Resolutions referred by the General Committee to the Council
for consideration, and, if desirable, for action were dealt with as follows.
The resolutions will be found in the Report for 1932, pp. xliii-xliv.

(a) The recommendation from Section C (Geology) concerning the
photography of certain special topographical features in north-east
Yorkshire and elsewhere was referred to the Air Ministry, but this
authority was unable to take the action desired.

=x REPORT OF THE COUNCIL, 1932-33

(b) Following upon recommendations from Sections E (Geography)
and M (Agriculture), a deputation waited upon the Ministry of Agri-
culture, and was assured that as far as possible the publication of
Agricultural Statistics, Parts 1 and 2, should be expedited, and the needs
of students in agricultural geography should be met.

(c) The attention of the Home Office and the Ministry of Transport
was called to the resolution from Section G (Engineering) concerning
the desirability of action against noises caused by motor vehicles.

(d) The Council conveyed to the Museums Association their approval
of the system of interchange of specimens in museums, and expressed
the hope that the system would be extended. (Resolution of Section
H, Anthropology.)

(ec) A recommendation that the final report of the Colour Vision
Committee should be communicated to the Ministry of Transport,
in so far as it referred to the shape of traffic lights, was adopted: ‘The
report was communicated accordingly, and certain information was
supplied to the Ministry at its request.

The Council forwarded the following resolution to H.M. Secretary of
State for the Colonies :—

The Council of the British Association have noted with great interest
the highly important archeological and geological discoveries made in the
Kendu-Homa area of Kenya Colony, and the promise they give that even
more valuable results will be obtained there in the future. The Council
therefore express the strong hope that it may be possible to reserve the
superficial deposits of this area (which at a minimum may be taken as a
strip two miles in width from the shore, from Kendu Point to Homa
Point, on Lake Victoria, a distance of 12 miles) for excavation only by
qualified scientific investigators.

Down House.

IV.—The following report for the year 1932-33 has been received from
the Down House Committee :—

The number of visitors to Down House during the year ending June 6,
1933, has been 7,022, compared with 7,638 in 1931-32, and 5,210 in 1930-
31. The decrease during the present as compared with last year is
accounted for by the fact that last year included the Association’s centenary
week, when a large number of members visited the house.

Among recent acquisitions reference should be made to the barometer
used by Darwin on the voyage of H.M.S. Beagle, which has been placed
at Down House by the Royal Society on loan. It has been restored to
working order by Messrs. Negretti & Zambra, with the kind advice of the
Meteorological Office.

Darwin’s dining-room table has been added to the collection by purchase.

The Old Study was copied as nearly as possible, and with great success,
as one of the rooms of scientific men exhibited at the Ideal Home Exhibition
this year. :

The Committee have acknowledged with deep gratitude a gift of {150
a year for five years from the Pilgrim Trust to the funds of the Association
in respect of its trusteeship under Sir Buckston Browne’s gift of Down
House. The preliminary steps which led to the making of this gift were

REPORT OF THE COUNCIL, 1932-33 Xxi

taken by Sir Alfred Ewing during the year of his presidency of the
Association.

The following financial statement shows income on account of Down
House, and current expenditure, for the financial year ending March 31,
1933; compared with that for the year ending June 30, 1932. ‘The overlap
between the two years is accounted for by the recent change of dates for
the Association’s financial year.

The figure for income from the Endowment Fund during the past year
is in a measure deceptive as certain dividends have been paid gross, which
previously were paid less tax to be subsequently reclaimed ;_ so that this
year includes both a gross payment and a refund on the preceding year.
The gross. amount of interest and dividends for a full year is £994 10s.

Income 1931-32 1932-33
£7) SOT dd iE? ts) Tas
By Dividends on endowment fund. é TAT. eaAlae 7700 Or 3
,, Income tax recovered . 3 ‘ ; Bo cant eee 250 st 7
,, Rents. ‘ ; : ‘ : : EA7 OO! +) 135) 1040
» Donations . : : 919 I ee ee
», Sale of Postcards and Catalogues : eb faa aay 74, en No)
as Balance, being excess of expenditure (Hin-
ning iosts). as below, over income : TSoltyeuos 40 7 114

£1,296 8 5 1,240 11 13

Expenditure (running costs)

1931-32 1932-33
ier Se: vcs eae xt,
To Wages and National Insurance : : 840 10 11 807 2 10
», Rates, Land Tax, Insurances ; { 720 PICS 64 10 II
», Coal, Coke, etc. . ; ‘ ; ; 125 16 2° 104 9 9
» ‘Water 2 r4i rorni6 orang) 6
», Lighting and Drainage Plants s (including
petrol and oil) . sorry 1 69.17 6
», Repairs and Renewals ‘ . ‘ . Adinust 20 39° 8, 67
», Garden Materials F 4 ; ; Vs haby eae 58 10 9
,» Household Requisites . : ‘ ; 16 5 6 16 19 33
ys Transport and Carriage : : : 4 4 6 ie are
» Auditors : ; 23° TOO 22 10 10
», Postcards and Chiatopues (printing) P 44 6 11 9 0 oF
s, Postages, Telephone, Stationery, etc. ot 519 2 27 8 10
* Approx: £1,206 8 5 1,240 11 14

2 Capital > Expenditure, 1932-33

fe Gs

Improvement of drainage system . t . . ; 326 15 0
5, stokehole . : , F F ; 12 14 6

Radiator alterations . ' : : j : ‘ 16, 0) 40
£65 9 6

b2

xxii REPORT OF THE COUNCIL, 1932-33

In connection with so-called ‘ capital’ expenditure by the Association
upon Down House, detailed in last year’s report, the statement was then
made that the works of restoration, etc., included under this heading
were within sight of completion. They have now been completed, and
the ‘ capital’ expenditure account has been closed at the total sum of
£3,292 15s. 2d., including catalogues in stock £110 (£119 less approximate
cost of catalogues sold, £9).

The Council have granted a lease of the cottage of Homefield to Sir
Arthur and Lady Keith or the survivor of them, and have authorised
Sir Arthur Keith to make agreed improvements in the property and
structural additions to the cottage at his own charges. They have also
granted an annual tenancy of a piece of land about three-quarters of an
acre in extent to the Royal College of Surgeons.

FINANCE.

V.—The Council have received reports from the General Treasurer
throughout the year. His accounts have been audited and are presented
to the General Committee. As the General Committee last year adopted
a proposal that the financial year of the Association should run from
April 1 to March 31, the present audited accounts cover a period of nine
months after June 20, 1932, the close of the last financial year under the
former plan. A pro forma account of expenditure and income for the
year as from April 1, 1932, has therefore been added.

Expenditure from Lt.-Col. Alan Cunningham’s bequest for the
preparation of new mathematical tables in the theory of numbers has
been made or sanctioned as follows :—Purchase of calculating machine ;
preparation of tables of ideal numbers (Dr. E. L. Ince) ; publication of
Factor Table to 100,000.

The Council have been informed that the Seismology Committee of
the Association is a prospective beneficiary in the sum of £1,000 under
the will of Dr. J. E. Crombie.

They have also been informed that the Association is a beneficiary
in the sum of {£1,000 under the will of Mr. Bernard Hobson, ‘ to be
invested and the proceeds annually devoted to the promoting of definite
geological research, the trust fund to be called the Bernard Hobson Fund.’
The Council propose that they should administer this fund, that it shall
be competent for the Committee of Section C (Geology) to recommend
grants as a charge upon the fund, and that grants may be made from it
in response to special applications arising in the course of any year.

The Council recommend that a sum not exceeding {£400 should be
allocated to grants to Research Committees from general funds for the
ensuing year.

PRESIDENT (1934), GENERAL OFFICERS, COUNCIL AND COMMITTEES.

VI.—The Council nominate as President of the Association for the
year 1934 (Aberdeen Meeting) Sir William Bate Hardy, F.R.S.

REPORT OF THE COUNCIL, 1932-33 XXili

VII.—The General Officers have been nominated by the Council as
follows :—

General Treasurer, Sir Josiah Stamp, G.B.E.
General Secretaries, Prof. F. J. M. Stratton, O.B.E., Prof. P. G. H.
Boswell, O.B.E., F.R.S.

VIII.—Council—The retiring Ordinary Members of the Council are:
Sir Daniel Hall, K.C.B., F.R.S., Mr. A. R. Hinks, C.B.E., F.R.S., Sir
Henry Lyons, F.R.S., Prof. E. B. Poulton, F.R.S., Prof. A. C. Seward,
F.R.S.

The Council have nominated as new members Dr. F, Aveling, Prof.
R. N. Rudmose Brown, Prof. F. Balfour Browne, leaving two vacancies
to be filled by the General Committee without nomination by the Council.

The full list of nominations of Ordinary Members is as follows :—

Dr. F. Aveling Sir James Henderson

Dr. F. A. Bather, F.R.S. Dr. C. W. Kimmins

Prof. R. N. Rudmose Brown Sir P. Chalmers Mitchell, C.B.E.,

Prof. F. Balfour Browne F.R.S.

SirHenry Dale,C.B.E.,Sec.R.S. Dr. C.Tate Regan, F.R.S.

Prof. J. Drever Sir John Russell, O.B.E., F.R.S.

Dr. A. Ferguson Dr. N. V. Sidgwick, FR. Ss:

Prof. R. B. Forrester Dr. G. C. Simpson, C.B., F.R.S.

Sir Henry Fowler, K.B.E. Prof. J. F. Thorpe, C.B.E. F. R.S.

Prof. W. T. Gordon H. T. Tizard, C.B., F.R. S.

Prof. Dame Helen Gwynne- Prof. A. M. Tyndall, F.R.S.
Vaughan, G.B.E. Prof. F. E. Weiss, F.R.S.

Dr. H.S. Harrison

IX.—General Committee—Dr. R. E. Gibbs, Dr. C. C. Hurst, Capt.
W. N. McClean, Prof. A. G. Ogilvie, Dr. Edgar Stedman, Mrs. Ellen
Stedman, and Mr. H.E. Wimperis, C.B.E., have been admitted as members
of the General Committee.

X.—Corresponding Societies Committee—The Corresponding Societies
Committee has been nominated as follows :—The President of the
Association (Chairman ex-officio), Mr. T. Sheppard (Vice-Chairman),
Dr. C. Tierney (Secretary), the General Treasurer, the General Secre-
taries, Mr. C. O. Bartrum, Dr. F. A. Bather, F.R.S., Sir Richard
Gregory, F.R.S., Mr. J. V. Pearman, Sir David Prain, F.R.S., Sir
John Russell, F.R.S., Prof. W.M. Tattersall.

GENERAL TREASURER’S ACGOUNT,
1932-33.

Tuer General Committee at the York Meeting last year adopted the
Council’s proposal that the financial year of the Association should
‘run from April 1 to March 31, instead of from July 1 to June 30 as
heretofore. The audited accounts herewith, therefore, cover a period
of nine months only, from July 1, 1932 (the previous accounts having
been completed to June 30 of that year), to March 31, 1933. The
usual figures for comparison with the preceding year are omitted
from these accounts.
The auditors have furnished the following notes :

Members’ Subscriptions (Annual) are mainly in respect of ‘sales of tickets
at the York Meeting, 1932. Preliminary programmes for the ensuing
meeting are not issued until April; therefore the advance sale of
tickets does not materially affect the present account.

Advertisements are chiefly on printed matter for the Meeting (programmes,
&c.). At the date of the accounts these are not completed. The
revenue shown in the nine months accounts is, therefore, practically
nil,

Dividends credited in the accounts are the actual amounts received, some
being in respect of six months, some nine months and others twelve
months. The dividends credited to General Income and Expenditure
Account are on balance short by {21 os. 6d. In the case of the Caird
Income and Expenditure Account, the majority of the dividends are
for twelve months, and on balance there is an actual excess of £46 19s. 4d.
This, also applies to Down House, where the amount of excess is
£31 6s. 3d. ;

Income Tax Recovered credited in accounts is the actual amount received
and is for twelve months.

Dividends received Gvoss——During the period certain dividends (on
Government Stocks) were received gross instead of net, The
additional amounts included in the accounts, which would in a normal
way be included in Income Tax Recovered in the following year,

amount to:
General Income and Expenditure Account TIZIZ8 6 A
Caird Income and’Expenditure Account . ry. ABE gato
Cunningham Bequest. ; ; 5 ? 8 9 9
Down House Income and Expenditure Account 30 18 9
Bonus on Conversion of War Stocks credited in the accounts is non-
recurring.

Donations to Centenary Fund credited in the accounts, £62 16s. 6d., are
also non-recurring.

Yarrow Fund Realisation. The amount credited to Income and Expendi-
ture Account, £156, is not according to scale. It is normally at the
rate of approximately £340 p.a.

General Expenses includes £100 for special accountants’ fees in connection
with the Centenary Meeting, 1931.

Grants.—The amount included in the accounts is in respect of grants
actually paid. The further grants which have been authorised but

GENERAL TREASURER’S ACCOUNT XKV

not yet claimed amount to £152 os. 1d. on General Account, and {100
Caird Fund. These are noted on the accounts. The majority of
these grants will, it is expected, be claimed before August 31 next.

In order to afford a clearer idea of the past year’s working, a pro
forma account of expenditure and income on general funds for the
year ending March 31, in the simplest form, is appended to the audited
accounts. The comparative figures there given are the averages
(with slight adjustments) used by the Council when considering their
report.on finance to the General Committee last year.

Some of the above remarks by the auditors apply to this pro formd
account equally. On the side of expenditure, general expenses are
higher than the average, owing mainly to the non-recurrent special
accountants’ fees referred to. ,. It is hoped that the excess of expenditure
over income on account of Down House will not recur, thanks to the
generous gift of the Pilgrim Trustees to which reference is made in
the report of the Council. The reduction of printing costs anticipated
in last year’s Report of the Council is taking effect ; on the other hand
no material reduction in the increased costs of postage can be expected
under present conditions. On the side of income, reference has been
made above to non-recurrent items, and to the fact that the full normal
realisation of capital from the Yarrow Fund (which was heavily drawn
upon in connection with the Centenary Meeting in 1931) has not been
given effect. ‘The receipts from sale of publications have fallen, owing
in part to the reductions of prices authorised last year. The growth
of advertisement revenue, under the existing conditions of depression,
cannot be expected to continue. The receipts from membership
subscriptions were much below the average of the preceding ten years.

Nevertheless, after taking into consideration all the items in the
account which are either abnormal or non-recurrent, it is estimated
that, omitting those items, the account would have been approximately
balanced, even if there had been charged upon it a full. year’s
transfer of £500 to the Contingency Fund, But if the position
appears so far satisfactory, it must be emphasised that the Association
is still restricted in its activities by insufficient funds; it has.always to
be remembered that the Yarrow Fund is a wasting asset; and the
Association is in no position (without trenching further upon its capital)
to meet all the applications for assistance of important researches and
other scientific activities which are brought before it every year. The
expansion of the Association’s membership and the strengthening of its
financial foundations should be the object of all those who would
further its interests.

JostaH C. STAMP,

General Treasurer.

XXVI GENERAL TREASURER’S ACCOUNT

Balance Sheet,

LIABILITIES.
To General Fund— 5 £ s. da. £, Sista,
As at July 1, 1932
As per contra . . . 10,942 19

(Subject to depreciation in value of Investments)

», Caird Fund—

As at July 1, 1932
As per contra 4 . 9,582 16
(Subject to depreciation in value of Investments)

,», Caird Fund Revenue Account—

Balance at July 1, 1932 . 192 0 0
Less Excess of Expenditure over Income for the nine
months . 7 . > * 33 I 4
‘as per contra —_—__ 158 18

(Contingent liability for grants authorised at York Meeting,
1932, but not yet claimed, £100)

»» Sir Charles Parsons’ Gift—
As per contra . ° - 5 : a A . = I0,000 oO

1 Sir Alfred Yarrow’s Gift—

As per last Account . 6,298 14 8
Less Transferred to Income and Expenditure Account
under terms of the Gift 5 . <tOISS'D 16)
as per contra ————_ 6,142 14
,, Life Compositions—
As per last Account » 4 5 = . 4 - 2,087°'2 2
Add received during year ~ = E 5 $ es 37 10 oO

2,124 I2 2
Less Transferred to Income and Expenditure Account 45 00

as per contra ————-_ 2,079 12
», Toronto University Presentation Fund—

As per last Account . e a ‘ . 5 - 182 18 10
Add Dividends . . 5 c 2 ‘ k P 4f\ 6
Bonus on Conversion . = > 5 z “ 5 I~ E5440
189 I 4
Less Awards given ° . : ° “ 3 * 6 2 6

as per contra ——_ 182 18 10

»» Lt.-Col. A. J. C. Cunningham’s Bequest—

For the preparation of New Tables in the Theory of
Numbers.
As per last Account . Z ‘ . : ‘ « 3,007 Ig 0
Add—

Income Tax recovered for 12 months ended June 3°,
1932. 3 2 < . 5 ‘ 32 3 10
Dividends . 5 e c = ; = 4 78 7 5

3,118 x0. 3
Less Grant made ' . ; . s 2 150 0 0
as per contra ———————-__ 2,968 10 3
To Down House Endowment Fund—
As per contra . 5 . ‘ : 5 ° : 20,000 0 Oo

Carried forward : £62,058 9 Ir

GENERAL TREASURER’S ACCOUNT

XXVii
March 31, 1933.
ASSETS.
By General Fund— £i se ai ‘Re OMe 5
Investments as per Schedule (p. xxxiv) “ fj F; 10,888 10 2
Cashat Bank .° . 3 : 5 . 5 54 811
——————-___ 10,942 19 I
»» Caird Fund—
Investments as per Schedule (p. xxxiv) ° ° . 9,582 16 3
», Caird Fund Revenue Account—
Cash at Bank . 4 s . 2 4 A ‘a 158 18 8
»» Sir Charles Parsons’ Gift—
Investment as per Schedule (p. xxxiv) . : & é 10,000 o 0
»» Sir Alfred Yarrow's Gift—
Investment as per Schedule (p. xxxiv) . 3 é ‘ 6,142 14 8
», Life Compositions—
Investments as per Schedule (p. xxxiv) = . ° 2,079 12 2
»» Toronto University Presentation Fund—
Investments as per Schedule (p. xxxv) = - - 178 II 4
Cashat Bank . . a F C . ° 4° 9716
182 18 10
», Lt.-Col. A. J. C. Cunningham's Bequest—
Investments as per Schedule (p. xxxv) 6 A o 2,702 19 2
Cash at Bank . . e F < 4 5 265 11 I
———— 2,968 10 3
» Sir Buckston Browne’s Gift in memory of Darwin—Down House,
Kent . . ‘ A . . . ° A Not valued.
Do. Endowment Fund—
Investments as per Schedule (p. xxxv F J . ad . . 20,000 0 O
Carried forward . . £62,058 9 11

XXViil GENERAL TREASURER’S ACCOUNT

Balance Sheet,

LIABILITIES—continued.

£ s.—d £ s. da,
Brought forward

62,058 9 II
o REVENUE ACCOUNT— .
Sundry Creditors. 4 = F : nw 119-6 14
Do. Do. (Down House) 5 : ; : i 22 16 11
», Income and Expenditure Account—
Balance at July 31,1932 . 3 i 7,017, 4. 5
Less Unexpended Grant in aid
of Expenses, 1929 (South
African Meeting), not re-
coverable . 74.55). 10)
Less Excess of Expenditure
over Income for the nine
months t 4 : Ft a 2 16
——— 250° FUG
6,758 16 11
Contingency Fund A 3) “3975. 401 0
———___ 7,276 0 2
(Contingent liability for grants authorised at York Meeting, —_——_—.
1932, but not yet claimed, £152 os. 1d.) £69,334 10 ‘I

I have examined the foregoing Account with the Books and Vouchers and certify
the Investments, and have inspected the Deeds of Down House and the Mortgage on
Approved.

ArTHUR L. BowLry :
W.W. Watts } Auditors.

1933.

GENERAL TREASURER’S ACCOUNT

March 31, 1933—continued.

XXIx

ASSETS—continued.

Brought forward - fs ; = 2 ;

By REVENUE ACCOUNT—
Investments as per Schedule (p. xxxy)
» Down House Suspense Account— *
As per last Account
Purchase of Land adjoining Down House
Stock of Catalogues at Down House . ;
Sundry Debtors and Payments in advance
Do. (Down House) : - :
Cash at Bank a ‘ 3
Do. in Hand .

the same to be correct. Ihave also verified the Balances at the Bankers and

Isleworth House.

d. a Pe |

62,058 9 11
°
°
°
°
I
9
6-
°
7,276 0 2

£69,334 10 1

W. B. Kren, Chartered Accountant.

XXX GENERAL TREASURER’S ACCOUNT

Income and

For THE Nine MontTHS

EXPENDITURE.
£s. da. ara Sarees
To Heat, Lighting and Bares: : = . r 23) 14 1
ie Stationery . 4 : j = 5 4 4613 3
», Rent 5 : . 4 ° - : ° ; F 15 0
», Postages . ' 5 : 5 : = = + 135 12 8
5 1 Ee Expenses" 4 < ° c - - 16618 2
Exhibitioners . ° . : - 3 a A . 53 5 of
Pa ” General Expenses. - 4 & “ * = 323 17 5
750 7 I
», Salaries and Wages A 2 A 5 5 - - 1,474 16 9
, Pension Contribution (1 year) 4 c 5 6 A é < 75 0 0
”” Printing, Binding, etc. ° . . ‘ - . ° Ou ee ee
————— 3243 13 1
», Grants to Research Committees :—
Film Committee . , : 5 . = 5 a 200
General Sciencein School . - . ° 15 I9 IL
Biology of a Tropical River in British Guiana 4 5 5 20 0 0
= ae 37 Ig Il
(Grants authorised at the York Meeting, 1932, but not yet claimed
amount to £152 os. 1d.)
To Balance, being excess of Income over Sepentince for the nine
months . * . . . ° . ° 179 19 7
£3,461 12 7
» Contingency Fund
Amount allocated in accordance with Council Minute, i.e.
£500 p.a., Proportion for nine months. . . 375.9) (0.
£375 9 Oo

GENERAL TREASURER’S ACCOUNT XXXi
.
Expenditure Account
ENDED MARCH 31, 1933
INCOME.
Pi) BRoIOgetas, J,
By Annual Regular Members, including £11 for 1933/4. . . go 13 0
», Annual Temporary Members, including £22 1s. for 1933/4. 5 92217 0
», Annual Members with Report, i jee £18 ros. for 1933/4 . 213 Io oO
», Lransferable Tickets . . . 47 10 O
», Students’ Tickets . A é : fe . 93 Io o
»» Life Compositions, Amount transferred ‘ . is < r 45 0 0
», Sale of Publications . < a 2 4 ! 4 3 , 402 8 10
», Advertisement Revenue . : 5 4 4 1
», Income Tax recovered for 12 months ended. 30 June, 1932 a 288 7 9
», Unexpended Balance of Grants, returned . 5 < 16 5 10
», Liverpool Exhibitioners . . : A é. 4 2210 0
», Dividends :—
Consols 2} percent.Stock . “ . : 5 ~ ‘316 0
India 3 per cent. Stock ‘ a : 74 5 «0
Great Indian Peninsula Railway ‘ B’ Annuity 5 5 3 26 Io II
44 per cent. Conversion Loan = 5 A _ : 48 18 6
Ditto Sir Charles Parsons’ Gitt - - 5 5 + 39315 0
3 per cent. Local Loans : : : = 60 16 8
3% per cent. War Loan ; 374% 3
Ditto Ditto (Series A), Sir Alfred Yarrow’s Gift 7 57) 9 4
33 per cent. Conversion Loan 3 ; fr ‘ : 81 12 8
996 I9 5
», Sir Alfred Yarrow’s Gift—
Amount transferred . : 156 0
Bonus on Conversion of War Stock—Sir A. Yarrow’s Gift 6219 8
Do, Do, Other . : : : 18 10 6
81 10 2
- pra tea on Mortgage ° . . 2 . 1710 0
Sundry Donations: Centenary Fund . ° . 6 - ° 62 16 6
£3,461 12 7
By Balance brought down 179 19 7
»» Down House Income and Expenditure Account—Balance, being
Excess of Income over Expenditure for the nine months
transferred A - a e . Io 17 Ir
» Balance transferred ‘to Balance Sheet 6. E 7 E ps 184. 2 6
£375 0 0

XXXii GENERAL TREASURER’S ACCOUNT

Caird Fund, Income

For THE Nine MONTHS

EXPENDITURE.
Suid. £ s. @.
To Grants paid— he
Seismology Committee 5 - - 5 - 300. #070
Zoological Record Committee 5 i ‘ s . 2 50 0 Oo
Derbyshire Caves Committee * . 5 5 " ” 50 0 0
Plymouth Table Committee es 5 s 5 ‘ 50 0 0
Athlit Caves Investigation . ; ; = : 75.0 0
Freshwater Biological Station Committee . A < f 50 0 0
375.9, 0
(Grants authorised at the York Meeting, 1932, but not yet claimed
amount to £100)
£375.09. ©
————————

Down House Income
For THE NINE MONTHS

EXPENDITURE,
£ snSe0ds Lsnxst a.
To Wages of Staff (net) a , 3 r 3 ¢ < Ls,,607,%) 3
», Rates, Insurance, etc. ‘ . : : 8 5 3 9 49'9 0
», Coal, Coke, etc. J : ; 3 95;° 0) 2
in Lighting and Drainage (including oil and petrol) . : : . 54 0 3
, Water .. . = ‘ : - II 9 4
a ” Repairs and Renewals 2 E : z : 5 5 P 28 9 4
,, Garden Material, etc. : ; ‘ - 2 : : 5 4114 I
», Household Requisites, etc. é 5 : 2 : : 9 16 6
», Transport and Carriage . : 5 : 5 . ; - I) 2 2E
», Accountants’ Fees . A y = 22 10 10
»» Printing, Postages, Telephone, Stationery, ete. . = $ Ig 1r 8
— Se 949 5 5
To Balance carried down . - 5 2 F 5 = 7 767 5
£1,016 12 10
To Repairs and alterations to Buildings, etc. o 65 9 6
»s Balance, being Excess of Income over Expenditure for ‘the nine months. 10 17 II

£78 “7-55

GENERAL TREASURER’S ACCOUNT xxxili

and Expenditure Account
ENDED MarcH 31, 1933

INCOME.

By Dividends—

Canada 34 percent. Stock .

London, Midland & Scottish Railway Consolidated 4 per cent,
Preference Stock .

Southern Railway Consolidated 5 per cent. Preference Stock é

», Income Tax recovered for 12 months ended 30th June 1932. *
»» Balance, being excess of Expenditure over Income for 9 months .

Notr—
Balance atr July1932_—g
Less Excess of Expenditure as above .

Balance at date as per Balance Sheet .

and Expenditure Account
ENDED MARCH 31, 1933

By Rents Receivable .
», Income Tax recovered for the 12 months ended j une 30, 1932
», Dividends—
4% per cent. India Stock A 2
Fishguard & Rosslare Railway 3h} per cent. Stock :
New South Wales 5 per cent. Stock : - j
Great Western Railway 5 per cent. Stock
Australia 5 per cent. Stock 1945/75 ,,
Western Australia 5 percent.Stock .
Birkenhead Railway 4 per cent. Stock .

», Donations ° ° *
», Sale of Postcards, ete.

By Balance brought down .

£ s. da. issn a
India 34 per cent. Stock e c ‘ F f 3 : 63 4 1
65 12 6
47 5 0
75 0 0

251 I 7

90 17, I

33 I 4

£375 0 0
192 0 O
a8 x. #
158 18 8

INCOME.

ese "Saris Di BSs) tes

103 I0 oO

2555107.
123 15 0
7815 0
46:17 6
125 5 0
93 15 0
93 15 0
Vey hee

637 2 6

Dae oo

bee

£1,016012 10

ee

GOerons

£76 7 5

XXXIV GENERAL TREASURER’S ACCOUNT

Schedules of Investments, etc.

General Funds— £----s5-d:
£4,651 ros. 5d. Consolidated 2} per cent. Stock at cost . = 4 + 9,042) 33
£3,600 India 3 per cent. Stock at cost . ° . ° : = 33522) 2G
£879 14s. 9d. Great Indian Peninsula Railway ‘B’ Aenuity at cost . « 9827-355) «a
£52 12s. 7d. War Stock (Post Office Issue) at cost . A . . al 54 5 2
£834 16s. 6d. 44 per cent. Conversion Stock at cost . . «> 9835! £2: (4
£1,400 War Stock 34 per cent. at cost . 3 5 ri 4 : - 1,393 16 11
£94 7s. 44 per cent. Conversion Stock at cost 3 . = Py C 62 15 0
£326 gs. 10d. 34 per cent. Conversion Stock at cost . é a . 250 0.0
(Value at date, £10,311 6s. 8d.) £10,888 10 2

Caird Fund—
£2,627 os. tod. India 34 per cent. Stock at cost . 2,400 13 3
£2,100 London Midland & Scottish Railway Consolidated . 4 per seants

Preference Stock at cost . ° ° . - 2,190 4 3
£2,500 Canada 33 per cent. Registered Stock eeaciza at ore | 2 2,397 I 6

£2,000 Southern Railway Consolidated 5 per cent. Preference Stock at cost 2,594 17 3

(Value at date, £7,159 7s. 11d.) £9,582 16 3

Sir Charles Parsons’ Gifi—
£10,300 44 per cent. Conversion Stock at cost = “ “5 3 £10,000 0 Oo

(Value at date, £11,458 15s.)

Sir Alfred Yarrow’s Gift—
£6,142 14S. 8d. 34 per cent. War Loan 5 i = i . £6,142 14 8

(Value at date, £6,219 ros. 4d.)

Life Compositions—

£2,949 12s. 4d. Local Loans at cost é A 4 5 a A - 1,923 12 2
£156 34 per cent. War Loan 5 = . 5 - = = . #56 ga

(Value at date, £2,783 2s. 2d.) £2,079 12 2

GENERAL TREASURER’S ACCOUNT

xXXXV

Schedules of Investments, etc.—continued

Toronto University Presentation Fund—
£175 34 percent. WarLoanatcost . . . . . 5
(Value at date, £177 3s. 9d.)

Lt.-Col. A. J. Cunningham's Bequest—
£1,187 6s, tod. Consolidated Stock 24 percent. . C 5
£300 Port of London 34 per cent. Stock 1949/99 . A
£100 Commonwealth of Australia 43 percent. Stock .
£100 New Zealand 5 per.cent Stock .
£800 India 6 percent. Stock atcost . .
£1,274 4s. 10d. Local Loans 3 per cent. Stock at ae . 3 i

(Value at date, £3,359 18s. 7d.)

Down House Endowment Fund—

£5,500 India 4} per cent. Stock 1958/68 at cost . é 5 A
£2,500 Australia 5 per cent. 1945/75 at cost . .

G'S. ide
- 178 114

» 653
216
93
103

- 801 12

- 836 6

ooo0o

wmoodcosy

a)

£2,702 19

» 5,001 17 4
2,468 19 0

£3,000 Fishguard and Rosslare Railway 34 per cent. Guaranteed Pare

Stock at cost é 4 7 - °
£2,500 New South Wales sp per ee Stock 7945/65 atcost . 0
£2,500 Western Australia 5 per cent. Stock 1945/75 at cost . By
£3,340 Great Western Railway 5 per cent. Guaranteed Stock at cost
£2,500 Birkenhead Railway 4 per cent. Consolidated Stock at cost .

(Value at date, £22,540 6s.)

Revenue Account—
£2,098 1s. 9d. Consolidated 24 per cent. Stock at cost
£4,338 6s. 2d. Conversion 3} per cent. Stock at cost
£400 3% per cent. War Loan Inscribed Stock at cost
Second Mortgage on Isleworth House, Orpington, Kent .

(Value of Stocks at date, £6,353 18s. 10d.)

+ 2,139 17
+ 2,467 7
a sages

3,436 7
=) #2;023') 9

wouwrnwow

£20,000 0 0

1,200 0

+ 3,300 0
404 16

joo oO

ooco

£5,604 16 o

—

XXXVi GENERAL TREASURER’S ACCOUNT

Pro forma Account of Income

For THE YEAR APRIL I, 1932—

EXPENDITURE

Averages, £ £ s.id.

24 To Heat, light, and power 2 : ‘ { , é : 29 9 I0

75 », Stationery : . z n A . : : 5714 7

I », Rent : ‘ 5 \ _ ; 5 i 2 Xr a. ¢
I70 », Postages . : 5 “ 3 : : 5 b stg 6 AB Na 7

I60 », Travelling expenses . : 5 " : 5 FE ON es

52 », Exhibitioners . ; : 6 : P : 4 53 5 6

210 ,, General expenses 3 ‘ : : : , . nt} BAinl Sor

2,026 », Salariesand Wages . : ; ‘ : ‘ t . 15958 .o 9

75 », Pension contribution . : F : ¢ 5 : y "50.0

I,700 », Printing, binding, etc. . 5 x 3 . 1,186 6 4

_ ;, Grants to Research Committees from mee funds Fi . 259 14 I

_ ,, Down House, excess of expenditure over income (including

‘capital’ expenditure) . a ‘ 2 : ‘ . 105 17 5t

,», Transfer to Contingency Fund (nine months) 5 ‘ - 8750-0

£4,877 13 1

Down House accounts for the year will be found in the

GENERAL TREASURER’S ACCOUNT XXXVii

and Expenditure (General Funds)

—Manrcu 31, 1933

INCOME
Averages, £ : f s. a.
12,500 By Annual Membership subscriptions “ : . : - 1,933 15 0
= | ,, Life compositions, amount transferred d ‘@ . P 45 00
: \566 ,, Sale of publications | - - ¥ v A “ 1 wa7Fzis 24
: ; 242 », Advertisement revenue 4 3 ( ‘ 4 et B57 5 3
== », Unexpended balances of grants, returned. . J 16 5 10
: 22 ,», Liverpool exhibitioners : r : e e 22 10 Oo
—- ,, Centenary Fund donations , b é - 2 . GF tty 8
' : 250 », Income tax recovered for 1931-32 5 j ’ r . 288 7 9
—_ ,, Bonus on conversion of War Stock _,. 4 ' ls ‘ 81 I0 2
f ,, Interest and dividends ; ‘ ¥ - _ £1,335 19, 0
», Interest on mortgage = 5 ; 26 5.0
,, Sir Alfred Yarrow’s gift, capital transferred . 156 0 Oo
HH | 1,577 1,518 4 0
> ;, Excess of expenditure over income forthe year . - ‘ 44 8 4}
£4,877 13 1

_ Report of the Council (Down House Committee’s report).

RESEARCH COMMITTEES, Etc.

APPOINTED BY THE GENERAL COMMITTEE, MEETING IN
LEICESTER, 1933.

Grants of money, if any, from the Association for expenses connected
with researches are indicated in heavy type.

SECTION A.—MATHEMATICAL AND PHYSICAL SCIENCES.

Seismological Investigations.—Dr. F. J. W. Whipple (Chairman), Mr. J. J. Shaw,
C.B.E. (Secretary), Prof. P. G. H. Boswell, O.B.E., F.R.S., Dr. C. Vernon
Boys, F.R.S., Sir F. W. Dyson, K.B.E., F.R.S., Dr. Wilfred Hall, Dr. H.
Jeffreys, F.R.S., Prof. Sir Horace Lamb, F.R.S., Mr. A. W. Lee, Prof. H. M.
Macdonald, F.R.S., Prof. E. A. Milne, M.B.E., F.R.S., Mr. R. D. Oldham,
F.R.S., Prof. H. H. Plaskett, Prof. H. C. Plummer, F.R.S., Prof. A. O.
Rankine, O.B.E., Rev. J. P. Rowland, S.J., Mr. D. H. Sadler, Prof. R. A.
Sampson, F.R.S., Mr. F. J. Scrase, Capt. H. Shaw, Sir Frank Smith, K.C.B.,
C.B.E., Sec. R.S., Dr. R. Stoneley, Mr. E. Tillotson, Sir G. T. Walker,
C.S.1., F.R.S. £100 (Caird Fund grant).

Calculation of Mathematical Tables.—Prof. E. H. Neville (Chairyman), Dr. L. J.
Comrie (Secretary), Prof. A. Lodge (Vice-Chaiyman), Dr. J. R. Airey,
Prof. R. A. Fisher, F.R.S., Dr. J. Henderson, Dr. E. L. Ince, Dr. J. O.
Irwin, Dr. J. C. P. Miller, Dr. E. S. Pearson, Mr. F. Robbins, Mr. D. H.
Sadler, Dr. A. J. Thompson, Dr. J. F. Tocher, Dr. J. Wishart. £100.

SECTIONS A, E, G—MATHEMATICAL AND PHYSICAL SCIENCES,
GEOGRAPHY, ENGINEERING.

To inquire into the position of Inland Water Survey in the British Isles and the
possible organisation and control of such a survey by central authority.—
Vice-Adml. Sir H. P. Douglas, K.C.B., C.M.G. (Chairman), Lt.-Col. E. Gold,
D.S.O., F.R.S. (Vice-Chairman), Capt. W. N. McClean (Secretary), Mr. E. G.
Bilham, Dr. Brysson Cunningham, Prof. C. B. Fawcett, Dr. A. Ferguson,
Dr. Ezer Griffiths, F.R.S., Mr. W. T. Halcrow, Mr. T. Shirley Hawkins,
O.B.E., Mr. W. J. M. Menzies, Mr. H. Nimmo, Dr. A. Parker, Mr. D. Ronald,
Capt. J.C. A. Roseveare, Dr. Bernard Smith, F.R.S., Mr. C. Clemesha Smith,
Mr. F. O. Stanford, O.B.E., Brig. H. S. L. Winterbotham, C.M.G., D.S.O.,
Capt. J. G. Withycombe, Dr. S. W. Wooldridge. £40.

SECTIONS A, J—MATHEMATICAL AND PHYSICAL SCIENCES,
PSYCHOLOGY.

The possibility of quantitative estimates of Sensory Events.—Dr. A. Ferguson
Chairman), Dr. C. S. Myers, C.B.E., F.R.S. (Vice-Chaiyvman), Mr. R. J.
Bartlett (Secretary), Dr. H. Banister, Prof. F. C. Bartlett, F.R.S., Dr. Wm.
Brown, Dr. N. R. Campbell, Dr. S. Dawson, Prof. J. Drever, Mr. J. Guild,
Dr. R. A. Houstoun, Dr. J. O. Irwin, Dr. G. W. C. Kaye, Dr. 5S. J. F. Philpott,
Dr. L. F. Richardson, F.R.S., Dr. J. H. Shaxby, Mr. T. Smith, F.R.S.,
Dr. R. H. Thouless, Dr. W. S. Tucker, O.B.E.

SECTION C.—GEOLOGY.

To excavate Critical Sections in the Paleozoic Rocks of England and Wales.—
Prof. W. W. Watts, F.R.S. (Chaiyman), Prof. W. G. Fearnsides, F.R.S.
(Secretary), Mr. W. S. Bisat, Dr. H. Bolton, Prof. W. S. Boulton, Dr. E. S.

RESEARCH COMMITTEES, ETC. XXXIX

Cobbold, Prof. A. H. Cox, Mr. E. E. L. Dixon, Dr. Gertrude Elles, M.B.E.,
Prof. E. J. Garwood, F.R.S., Prof. H. L. Hawkins, Prof. G. Hickling,
Prof. V. C. Illing, Prof. O. T. Jones, F.R.S., Prof. J. E. Marr, F.R.S.,
Dr. F. J. North, Dr. J. Pringle, Dr. T. F. Sibly, Dr. W. K. Spencer, F.R.S.,
Prof. A. E. Trueman, Dr. F.S. Wallis. £20 (Caird Fund, contingent grant).

The Collection, Preservation, and Systematic Registration of Photographs of
Geological Interest.—Prof. E. J. Garwood, F.R.S. (Chaivman), Prof. S. H.
Reynolds (Secretary), Mr. C. V. Crook, Mr. J. F. Jackson, Mr. J. Ranson, Prof.
W. W. Watts, F.R.S., Mr. R. J. Welch.

To investigate Critical Sections in the Tertiary and Cretaceous Rocks of the
London Area. To tabulate and preserve records of new excavations in that
area.—Prof. W. T. Gordon (Chaiyman), Dr. S. W. Wooldridge (Secretary),
Mr. H. C. Berdinner, Prof. P. G. H. Boswell, O.B.E., F.R.S., Miss M. C.
Crosfield, Mr. F. Gosling, Prof. H. L. Hawkins, Prof. G. Hickling. £15.

The Stratigraphy and Structure of the Paleozoic Sedimentary Rocks of West
Cornwall.—Mr. H. Dewey (Chairman), Mr. E. H. Davison (Secretary),
Mr. H.G. Dines, Miss E. M. Lind Hendriks, Mr. S. Hall, Dr. S. W. Wooldridge.

To consider and report upon Petrographic Classification and Nomenclature.—
Dr. H. H. Thomas, F.R.S. (Chairman), Dr. A. K. Wells (Secretary), Prof.
E. B. Bailey, F.R.S., Prof. P. G. H. Boswell, O.B.E., F.R.S., Prof. A.
Brammall, Dr. R. Campbell, Prof. A. Holmes, Prof. A. Johannsen, Dr. W. Q.
Kennedy, Dr. A. G. MacGregor, Prof. P. Niggli, Prof. H. H. Read, Prof.
S. J. Shand, Mr. W. Campbell Smith, Prof. C. E. Tilley, Dr. G. W. Tyrrell,
Dr F. Walker. £5.

To prove the character of the Paleozoic Rocks underlying the Carboniferous of
the Craven area.—Prof. W. G. Fearnsides, F.R.S. (Chairman), Dr. R. G. S.
Hudson (Secretary), Prof. O. T. Jones, F.R.S., Prof. W. B. R. King, O.B.E.,
Mr. W. H. Wilcockson. £80 (Bernard Hobson Fund grant).

SECTIONS C, E.—GEOLOGY, GEOGRAPHY.

To administer a grant in support of a topographical and geological survey of
the Lake Rudolph area in E. Africa,—Sir Albert E. Kitson, C.M.G., C.B.E.
(Chaiyman), Dr. A. K. Wells (Secretary), Mr. S. J. K. Baker, Prof. F.
Debenham, Dr. V. Fuchs, Prof. W. T. Gordon, Brig. H. S. L. Winterbotham,
C.M.G.,D.S.0. £385.

SECTION D.—ZOOLOGY.

oy cor Bibliography and Publication.—Prof. E. B. Poulton, F.R.S. (Chairman),
r. F. A. Bather, F.R.S. (Secretary), Mr. E. Heron-Allen, F.R.S., Dr. W. T
aia F.R.S., Sir P. Chalmers Mitchell, C.B.E., F.R.S., Mr. W. L. Saisie.

To nominate competent Naturalists to perform definite pieces of work at the
Marine Laboratory, Plymouth.—Prof. J. H. Ashworth, F.R.S. (Chairman
and Secretary), Prof. H. Graham Cannon, Prof. H. Munro Fox, Prof. J.
Stanley Gardiner, F.R.S. £50 (Caird Fund grant).

To co-operate with other Sections interested, and with the Zoological Society,
for the purpose of obtaining support for the Zoological Record.—Sir Sidney
Harmer, K.B.E., F.R.S. (Chairman), Dr. W. T. Calman, F.R.S. (Secretary),
Prof. E. S. Goodrich, F.R.S., Prof. D. M. S. Watson, F.R.S. $50 (Caird
Fund grant).

To consider the position of Animal Biology in the School Curriculum and matters
Telating thereto.—Prof. R. D. Laurie (Chairman and Secretary), Mr. H. W.
Ballance, Prof. E. W. MacBride, F.R.S., Miss M. McNicol, Miss A. J.
Prothero, Prof. W. M. Tattersall, Dr. E. N. Miles Thomas.

To determine the behaviour ofa limited and uniform plankton population observed
under natural conditions.—Dr. G. P. Bidder (Chairman), Mr. A. C. Gardiner
(Secretary), Dr. J. Gray, F.R.S., Mr. J. T. Saunders. £3 10s. 6d. (Un-
expended balance).

xl RESEARCH COMMITTEES, ETC.

The biology of a tropical river in British Guiana and of the neighbouring districts.
—Prof. J. S. Gardiner, F.R.S. (Chaiyman), Dr. G..S. Carter and Mr. J. T.
Saunders (Secretaries), Dr: W. T. Calman, F.R.S., Prof: J. Graham Kerr,
F.R.S., Dr. C. Tate Regan, F.R.S.

SECTIONS D, I, K—ZOOLOGY, PHYSIOLOGY, BOTANY.

To aid competent investigators selected by the Committee to carry on definite
pieces of work at the Zoological Station at Naples.—Prof. J. H. Ashworth,
F.R.S. (Chaiyman and Secretary), Prof. J. Barcroft, C.B.E., F.R.S., Prof.
E. W. MacBride, F.R.S., Dr. Margery Knight. £50 (Caird Fund grant).

SECTIONS D, K.—ZOOLOGY, BOTANY.

To aid competent investigators selected by the Committee to carry out definite
pieces of work at the Freshwater Biological Station, Wray Castle, Winder-
mere.—Prof. F, E. Fritsch, F.R.S. (Chaiyman), Mr. J. T. Saunders (Secretary),
Miss P. M. Jenkin, Dr. C. H. O’Donoghue (from Section D); Dr. W. H.
Pearsall (from Section K). £75 (£40 Caird Fund grant).

SECTION E.—GEOGRAPHY.

To co-operate with the Ordnance Survey in the production of a Population
Density Map (or Maps) of Great Britain and to endeavour ito get this pub-
lished as soon as the 1931 Census is available ; and, further, to examine the
possibility of making similar Maps of the Empire, utilising the International
Map (1 : 1,000,000) as the base.—Brig. H.S. L. Winterbotham, C.M.G., D.S.O.
(Chairyman), Capt. J. G. Withycombe (Secretary), Mr. J. Bartholomew,
Lt.-Col. A. B. Clough, Prof. F. Debenham, Prof. C. B. Fawcett, Prof. H. J.
Fleure, Mr. H. King, Mr. R. H. Kinvig, Prof. A. G. Ogilvie, O.B.E., Prof.
O. H. T. Rishbeth, Prof. P. M. Roxby, Mr. A. Stevens.

To inquire into the present state of knowledge of the Human Geography of
Tropical Africa, and to make recommendations for furtherance and develop-
ment.—Prof. P. M. Roxby (Chairman), Prof. A. G. Ogilvie, O.B.E. (Secretary),
Dr. A. Geddes (Assistant Secretary), Mr. S. J. K. Baker, Prof. C: B. Fawcett,
Prof. H. J. Fleure, Mr. E. B. Haddon, Mr. R. H. Kinvig, Mr. J. McFarlane,
Col. M. N. MacLeod, D.S.O., Prof. J. L. Myres, O.B.E., F.B.A., Mr. R. A.
Pelham, Mr. R. U. Sayce, Rev. E. W. Smith, Brig. H. S. L. Winterbotham,
C.M.G., D.S.O. 5.

To investigate the mapping of historical data for medieval England ‘and to take
steps to advance such work.—Mr. J. N. L. Baker (Chairman), Dr. H. C.
Darby, Mr. E. W. Gilbert, Mr. F. G. Morris, Dr. S. W.- Wooldridge.

SECTIONS E, K.—GEOGRAPHY, BOTANY.

To complete two maps of England on the 1/M: scale showing (i) the distribution
of woodland (based on physical evidence) after the establishment of climatic
conditions approximating to the present, and (ii) the distribution of wood-
land on the basis of ‘evidence derived from early topographical writings
and maps.—Sir John Russell, O.B.E., F.R.S. (Chairman), Prof. P. M.
Roxby (Secretary) ; Prof. H. J. Fleure, Mr. R. H. Kinvig, Prof. A. G. Ogilvie,
O.B.E., Brig. H. S. L. Winterbotham, C.M.G., D.S.O., Capt. J. G. Withy-
combe (from Section E); Prof. E. J. Salisbury, Dr. T. W. Woodhead (from
Section K). $25.

SECTIONS E, L—GEOGRAPHY, EDUCATION.

To report on the present position of Geographical Teaching in Schools, and of
Geography in the training of teachers; to formulate suggestions for a
syllabus for the teaching of geography both to Matriculation Standard and

RESEARCH COMMITTEES, ETC. xli

in Advanced Courses and to report, as occasion arises, to Council through
the Organising Committee of Section E upon the practical working of
Regulations issued by the Board of Education (including the Scottish
Education Department) affecting the position of Geography in Schools and
Training Colleges.—Prof. Sir T. P. Nunn (Chairman), Mr. L. Brooks (Secre-
tary), Mr. A. B. Archer, Mr. J. N. L. Baker, Mr. C..G, Carter, Prof, El. Jn
Fleure, Dr. O. J. R. Howarth, O.B.E., Mr. H. E.M, Icely, Mr. J. McFarlane,
Rt. Hon. Sir Halford J. Mackinder, P.C., Prof. J. L. Myres, O.B.E., F.B.A.,
Dr. Marion Newbigin, Prof: A. G. Ogilvie, O.B.E., Mr. A. Stevens, Prof.
C. B. Fawcett (from. Section E); Mr. J. L. Holland, Sir R. Gregory,
Bt., F.R.S., Mr. E, R: Thomas, Miss O. Wright, Prof. Godfrey, Thomson
(from Section L).

SECTION F.—ECONOMIC SCIENCE AND STATISTICS,

Chronology of the World Crisis from 1929 onwards.—Prof. J. H. Jones (Chaiyman),
Dr. P. Ford (Convener), Mr. G. N. Clark, Prof. H. M. Hallsworth, C.B.E.,
Mr. R. F: Harrod, Mr. A. Radford, Prof. J..G. Smith.

SECTIONS F, G, I, J, L—-ECONOMIC SCIENCE AND, STATISTICS,
ENGINEERING, PHYSIOLOGY, PSYCHOLOGY, EDUCATION.

Industrial Co-operation’: to report on the provisions for co-ordinating and
stimulating scientific work bearing on business practice; and to make
recommendations.—Dr. J. A. Bowie (Chairman), Mr. R. J. Mackay (Secre-
tary), Prof. J. G. Smith, Major L. Urwick (from Section F) ;: Prof. W.
Cramp (from Section G); Mr. G. P. Crowden ( from Section I); Dr. C. S.
Myers, C.B.E., F.R.S. (from Section J); Sir Richard Gregory, Bt., F.R.S.
(from Section L).

SECTION G.—ENGINEERING,

Earth Pressures.—Mr. F. E. Wentworth-Sheilds, O.B.E. (Chaivman), Dr. J. S.
. Owens (Secretary), Prof. G. Cook, Mr. T. E. N. Fargher, Prof: A. R.Fulton,
Prof. F. C. Lea, Prof. R.V. Southwell, F.R.S., Dr. R. E. Stradling, Dr. W. N.
Thomas, Mr. E. G. Walker, Mr. J. S. Wilson. £9 5s. 8d. (Unexpended
balance).

Electrical Terms and Definitions.—Prof. Sir J. B. Henderson (Chairman), Prof.
F. G. Baily and Prof. G. W. O. Howe (Secretaries), Prof. W. Cramp, Prof.
W. H. Eccles, F.R.S., Prof. C. L. Fortescue, Sir R. Glazebrook, K.C.B.,
F.R.S., Prof. A. E. Kennelly, Prof. E. W. Marchant, Sir Frank Smith,
K.C.B., C.B.E., Sec. R.S., Prof. L. R. Wilberforce.

Stresses in Overstrained Materials—Sir Henry Fowler, K:B.E. (Chaiyman),
Dr. J..G. Docherty (Secretary), Prof. G,. Cook, Prof. B. P. Haigh, Mr, J. S.
Wilson. £10 (Unexpended balance).

To review the knowledge at present available for the reduction of noise, and
the nuisances to the abatement of which this knowledge could best be
applied.—Sir Henry Fowler, K.B.E. (Chairman), Prof. T. R. Cave-Brown-
Cave, C.B.E. (Secretary), Mr. R. S. Capon, Prof. G. W. O. Howe, £10.

SECTION H.—ANTHROPOLOGY.

To report on the Distribution of Bronze Age Implements.—Prof. J. L. Myres,
O.B.E., F.B.A. (Chairman), Mr. H. J. E. Peake (Secretary), Mr. A. Leslie
Armstrong, Mr. H. Balfour, F.R.S., Mr. L. H. Dudley Buxton, Prof. V.
Gordon Childe, Mr. O. G. S. Crawford, Prof. H. J. Fleure, Dr. Cyril Fox.

To report on the Classification and Distribution of Rude Stone Monuments in
the British Isles——-Mr. H. J. E. Peake (Chairman), Dr. Margaret A. Murray
(Secretary), Mr. A. L. Armstrong, Mr. H. Balfour, F.R.S., Prof. V. Gordon
Childe, Dr. Cyril Fox, Mr. T. D. Kendrick.

xlii RESEARCH COMMITTEES, ETC.

To report on the probable sources of the supply of Copper used by the Sumerians,
—Mr. H. J. E. Peake (Chairman), Dr. C. H. Desch, F.R.S. (Secretary),
Mr. H. Balfour, F.R.S., Mr. L. H. Dudley Buxton, Prof. V. Gordon Childe,
Mr. O. Davies, Prof. H. J. Fleure, Sir Flinders Petrie, F.R.S., Dr. R. H.
Rastall.

To conduct Archeological and Ethnological Researches in Crete.—Prof. J. L.
Myres, O.B.E., F.B.A. (Chairman), Mr. L, Dudley Buxton (Secretary), Dr.
W. L. H. Duckworth, Sir A. Evans, F.R.S., Dr. F. C. Shrubsall.

To co-operate with the Torquay Antiquarian Society in investigating Kent’s
Cavern.—Sir A. Keith, F.R.S. (Chairman),Prof. J. L. Myres, O.B.E., F.B.A.
(Secretary), Mr. M. C. Burkitt, Dr. R. V. Favell, Miss D. A. E. Garrod,
Mr. A. D. Lacaille. £5,

To co-operate with a Committee of the Royal Anthropological Institute in the
exploration of Caves in the Derbyshire district.—Mr. M. C. Burkitt (Chair-
man), Dr. R. V. Favell (Secretary), Mr. A. Leslie Armstrong, Prof. H. J.
Fleure, Miss D. A. E. Garrod, Dr. J. Wilfrid Jackson, Prof. L. S. Palmer,
Mr. H. J. E. Peake. £25 (Caird Fund grant).

To co-operate with Miss Caton-Thompson in her researches in prehistoric sites in
the Western Desert of Egypt.—Prof. J. L. Myres, O.B.E., F.B.A. (Chair-
man), Mr. H. J. E. Peake (Secretary), Mr. H. Balfour, F.R.S.

To report to the Sectional Committee on the question of re-editing ‘ Notes and
Queries in’ Anthropology.’—Dr. H. S. Harrison (Chairman), Mr. L. Dudley
Buxton (Secretary), Miss R. M. Fleming, Prof. C. Daryll Forde, Dr. A. C.
Haddon, F.R.S., Capt. T. A. Joyce, O.B.E., Prof. C. G. Seligman, F.R.S.,
Mrs. Seligman, Miss C. Wedgwood.

To carry out the excavation of Paleolith cave deposits on Mt. Carmel, Palestine.
—Prof. J. L. Myres, O.B.E., F.B.A. (Chaivman), Mr. M. C. Burkitt (Secretary),
Miss G. Caton-Thompson, Miss D. A. E. Garrod, £80.

To carry out research among the Ainu of Japan.—Prof. C. G. Seligman, F.R.S.
(Chairman), Mrs. C. G. Seligman (Secretary), Dr. H. S. Harrison, Capt.
T. A. Joyce, O.B.E., Rt. Hon. Lord Raglan. £50.

To co-operate with the local committee in the excavation of Pen Dinas hill fort,
Cardiganshire.—Dr. Cyril Fox (Chairman), Mr. V. E. Nash-Williams (Secre-
tary), Prof. V. Gordon Childe, Prof. C. Daryll Forde, Rt. Hon. Lord Raglan,
Dr. R. E. M. Wheeler. £25.

To excavate a prehistoric and Roman mining site in Rio Tinto, Spain.—Mr.
M. C. Burkitt (Chaiyman), Dr. C. H. Desch, F.R.S. (Secretary), Prof. V.
Gordon Childe, Dr. Margaret A. Murray, Prof. J. L. Myres, O.B.E., F.B.A.
£15 (Caird Fund, contingent grant).

To investigate blood groups among the Tibetans.—Prof. H. J. Fleure (Chairman),
Prof. R. Ruggles Gates, F.R.S. (Secretary), Dr. J. H. Hutton, C.1.E., Mr.
R. U. Sayce.

SECTION I.—PHYSIOLOGY.

The supply of Oxygen at high altitudes—Prof. J. Barcroft, C.B., F.R.S. (Chair-
man), Dr. Raymond Greene (Acting Secretary), Mr. G. S. Adair, Mr. E. N.
Odell, Major J. A. Sadd. £5.

To deal with the use of a Stereotactic Instrument.—Prof. J. Mellanby, F.R.S.
(Chairman and Secretary).

SECTIONS I, J.—PHYSIOLOGY, PSYCHOLOGY.

The conditions of vertigo and its relation to disorientation.—
(Chairman), (Secretary), Prof. J. H. Burn, Dr. R.
S. Creed, Squadron-Leader E. D. Dickson, Prof. J. Drever, Dr. J. T.
MacCurdy. £20.

RESEARCH COMMITTEES, ETC. xiii

SECTION J.—PSYCHOLOGY.

To develop tests of the routine manual factor in mechanical ability —Dr. C. S.
Myers, C.B.E., F.R.S. (Chairman), Dr. G. H. Miles (Secretary), Prof. C.
Burt, Dr. F. M. Earle, Dr. Ll. Wynn Jones, Prof. T. H. Pear. £20 (Caird
Fund, contingent grant).

The nature of perseveration and its testing—Prof. F. Aveling (Chairman),
Mr. E. Farmer (Secretary), Prof. F. C. Bartlett, F.R.S., Dr. Mary Collins,
Dr. W. Stephenson.

SECTION K.—BOTANY.

Transplant Experiments.—Sir Arthur Hill, K.C.M.G., F.R.S. (Chairman), Dr.
W. B. Turrill (Secretary), Prof. F. W, Oliver, F.R.S., Prof. E. J. Salisbury,
Prof. A. G. Tansley, F.R.S.

Fossil Plants at Fort Gray, near East London.—Dr. A. W. Rogers, F.R.S. (Chair-
man), Prof. R. S. Adamson (Secretary), Prof. A. C. Seward, F.R.S.

The anatomy of timber-producing trees——Prof. H. S. Holden (Chairman), Dr.
Helen Bancroft (Secretary), Prof. J. H. Priestley, D.S.O. $10,

SECTION L.—EDUCATIONAL SCIENCE.

To consider the position of science teaching in Adult Education classes, and to
suggest possible means of promoting through them closer contact between
scientific achievement and social development.—Prof. J. L. Myres, O.B.E.,
F.B.A. (Chaiyman), Mr. C. E. Browne (Secretary), Major A. G. Church,
D.S.O., Dr. Lilian J. Clarke, Miss E. R. Conway, C.B.E., Prof. C. H. Desch,
F.R.S., Mr. A. Clow Ford, Sir Richard Gregory, Bt., F.R.S., Mr. S. R.
Humby, Dr. C. W. Kimmins, Miss H. Masters, Mr. E.R. Thomas. $10.

To consider and report on the possibility of the Section undertaking more definite
work in promoting educational research.—Dr. W. W. Vaughan (Chairman),
(Secretary), Miss H. Masters, Mr. E. R. B. Reynolds,

Mr. N. F. Sheppard. £5. ,

SECTIONS M, E.-AGRICULTURE, GEOGRAPHY,

To co-operate with the staff of the Imperial Soil Bureau to examine the soil
resources of the Empire——Sir John Russell, O.B.E., F.R.S. (Chairman),
Mr. G. V. Jacks (Secretary), Dr. E. M. Crowther, Dr. W. G. Ogg, Prof. G. W.
Robinson (from Section M); Prof. C. B. Fawcett, Mr. H. King, Dr. L. D.
Stamp, Mr. A. Stevens, Dr. S. W. Wooldridge (from Section E).

CORRESPONDING SOCIETIES.

Corresponding Societies Committee.—The President of the Association (Chairman
ex-officio), Mr. T. Sheppard (Vice-Chairman), Dr. C. Tierney (Secretary),
the General Secretaries, the General Treasurer, Mr. C. O. Bartrum, Dr. F. A.
Bather, F.R.S., Sir Richard Gregory, Bt., F.R.S., Mr. J. V. Pearman, Sir
David Prain, C.LE., C.M.G., F.R.S., Sir John Russell, O.B.E., F.R.S.,
Prof. W. M. Tattersall.

xliv RESOLUTIONS: AND RECOMMENDATIONS

RESOLUTIONS & RECOMMENDATIONS.

The following resolutions and recommendations were referred to the
Council by the General Committee at the Leicester Meeting for con-
sideration and, if desirable, for action :—

From the General Officers.

That it be a recommendation to the General Committee to request the
Council to consider by what means the Association, within the framework
of its constitution, may assist towards a better adjustment between the
advance of Science and social progress, with a view to further discussion
at the Aberdeen Meeting. :

From Section D (Zoology).

That the Committee of Section D (Zoology) of the British Association
regards with grave apprehension the continuing spread of the Musk Rat
in the British Isles. . It has learned with satisfaction that steps are now
being taken by the Ministry of Agriculture and Fisheries to deal with the
pest, and it earnestly hopes that no effort will be spared to exterminate
the species completely in this country.

From Section E (Geography).

(1) That the Council be asked to urge upon the proper authorities the
desirability of including population maps in the Census returns.

(2) That the Council be asked to draw the attention of His Majesty’s
Government to the backward state of geodetic surveys in the British
Colonies and Dependencies, and to point out to the Government that the
lack of reliable surveys and maps greatly delays scientific and material
progress.

(3) That the Council be asked to approach His Majesty’s Government
with a view to accelerating the revision of the large scale maps of the
Ordnance Survey.

From Section K (Botany).

That in view of the value of the cricket-bat willow as a subsidiary farm
crop, which can be grown satisfactorily by the small farmer as well as by
the estate owner, the Government be asked to facilitate investigations of
the diseases or pests causing ‘speck,’ ‘stain,’ and ‘ water-mark.’

From Section L (Educational Science).

That 1,000 copies of each of the reports on Science in Adult Education
and on General Science with special reference to Biology be reprinted
and placed on sale at the price of sixpence per copy, and that free copies
be distributed to the Press and to a selection of local education authorities
and schools.

The following recommendation was approved for immediate action :—

From Section E (Geography).

That copies of the printed report on the Position of Geography in
Dominion Universities be circulated to the universities in the Dominions.

BRITISH ASSOCIATION FOR THE ADVANCEMENT OF SCIENCE.
LEICESTER, 1933.

THE PRESIDENTIAL ADDRESS

SOME CHEMICAL ASPECTS OF LIFE

BY
SIR FREDERICK GOWLAND HOPKINS, PRES.R.S.,
PRESIDENT OF THE ASSOCIATION.

Tt

Tue British Association returns to Leicester with assurance of
a welcome as warm as that received twenty-six years ago, and of
hospitality as generous. The renewed invitation and the ready
acceptance speak of mutual appreciation born of the earlier experi-
ence. Hosts and guests have to-day reasons for mutual congratu-
lations. ‘The Association on its second visit finds Leicester altered
in important ways. It comes now to a city duly chartered and the
seat of a bishopric. It finds there a centre of learning, many fine
buildings which did not exist on the occasion of the first visit, and
many other evidences of civic enterprise. The citizens of Leicester
on the other hand will know that since they last entertained it the
Association has celebrated its centenary, has four times visited
distant parts of the Empire, and has maintained unabated through
the years its useful and important activities.

In 1907 the occupant of the Presidential Chair was, as you know,
Sir David Gill, the eminent astonomer who, unhappily, like many
who listened to his address, is with us no more. Sir David dealt
in that address with aspects of science characterised by the use of
very exact measurement. The exactitude which he prized and
praised has since been developed by modern physics and is now so
great that its methods have real esthetic beauty. In contrast I
have to deal with a branch of experimental science which, because
it is concerned with living organisms, is in respect of measurement
on a different plane. Of the very essence of biological systems is
an ineludable complexity, and exact measurement calls for condi-

tions here unattainable. Many may think, indeed, though I am
B

2 THE PRESIDENTIAL ADDRESS

not claiming it here, that in studying Life we soon meet with aspects
which are non-metrical. I would have you believe, however, that
the data of modern Biochemistry which will be the subject of my
remarks were won by quantitative methods fully adequate to justify
the claims based upon them.

Though speculations concerning the origin of Life have given
intellectual pleasure to many, all that we yet know about it is that
we know nothing. Sir James Jeans once suggested, though not
with conviction, that it might be a disease of matter—a disease of
its old age! Most biologists, I think, having agreed that Life’s
advent was at once the most improbable and the most significant
event in the history of the Universe, are content for the present to
leave the matter there.

We must recognise, however, that Life has one attribute that is
fundamental. Whenever and wherever it appears the steady
increase of entropy displayed by all the rest of the Universe is then
and there arrested. There is no good evidence that in any of its
manifestations life evades the second law of thermodynamics, but
in the downward course of the energy-flow it interposes a barrier
and dams up a reservoir which provides potential for its own re-
markable activities. The arrest of energy degradation in living
Nature is indeed a primary biological concept. Related to it, and
of equal importance is the concept of Organisation.

It is almost impossible to avoid thinking and talking of life in this
abstract way, but we perceive it, of course, only as manifested in
organised material systems, and it is in them we must seek the
mechanisms which arrest the fall of energy. Evolution has estab-
lished division of labour here. From far back the wonderfully
efficient functioning of structures containing chlorophyll has, as
everyone knows, provided the trap which arrests and transforms
radiant energy—fated otherwise to degrade—and so provides power
for nearly the whole living world. It is impossible to believe,
however, that such a complex mechanism was associated with life’s
earliest stages. Existing organisms illustrate what was perhaps an
earlier method. ‘The so-called autotrophic bacteria obtain energy
for growth by the catalysed oxidation of materials belonging wholly
to the inorganic world; such as sulphur, iron or ammonia, and
even free hydrogen. These organisms dispense with solar energy,
but they have lost in the evolutionary race because their method
lacks economy. Other existing organisms, certain purple bacteria,
seem to have taken a step towards greater economy, without reaching
that of the green cell. ‘They dispense with free oxygen and yet
obtain energy from the inorganic world. They control a process in
which carbon dioxideis reduced and hydrogen sulphide simultaneously
oxidised. ‘The molecules of the former are activated by solar energy

THE PRESIDENTIAL ADDRESS 3

which their pigmentary equipment enables these organisms to
arrest.

Are we to believe that life still exists in association with systems
that are much more simply organised than any bacterial cell? The
very minute filter-passing viruses which, owing to their causal
relations with disease, are now the subject of intense study, awaken
deep curiosity with respect to this question. We cannot yet claim
to know whether or not they are living organisms. In some sense
they grow and multiply, but, so far as we yet know with certainty,
only when inhabitants of living cells. If they are nevertheless
living, this would suggest that they have no independent power of
obtaining energy and so cannot represent for us the earliest forms
in which life appeared. At present, however, judgment on their
biological significance must be suspended. ‘The fullest under-
standing of all the methods by which energy may be acquired for
life’s processes is much to be desired.

In any case every living unit is a transformer of energy however
acquired, and the Science of Biochemistry is deeply concerned with
these transformations. It is with aspects of that science that I am
to deal and if to them I devote much of my address my excuse is
that since it became a major branch of inquiry Biochemistry has
had no exponent in the Chair I am fortunate enough to occupy.

As a progressive scientific discipline it belongs to the present
century. From the experimental physiologists of the last century
it obtained a charter, and, from a few pioneers of its own, a promise
of success ; but for the furtherance of its essential aim that century
left it but a small inheritance of facts and methods. By its essential
or ultimate aim I myself mean an adequate and acceptable de-
scription of molecular dynamics in living cells and tissues.

pt.

When this Association began its history in 1831 the first arti-
ficial synthesis of a biological product was, as you will remember,
but three years old. Primitive faith in a boundary between the
organic and the inorganic which could never be crossed, was only
just then realising that its foundations were gone. Since then,
during the century of its existence, the Association has seen the
pendulum swing back and forth between frank physico-chemical
conceptions of life and various modifications of vitalism. It is
characteristic of the present position and spirit of science that
sounds of the long conflict between mechanists and vitalists are just
now seldom heard. It would almost seem, indeed, that tired of
fighting in a misty atmosphere each has retired to his tent to
await with wisdom the light of further knowledge. Perhaps, how-
ever, they are returning to the fight disguised as Determinist and

4 THE PRESIDENTIAL ADDRESS

Indeterminist respectively. If so the outcome will be of great
interest. In any case I feel fortunate in a belief that what I have to
say will not, if rightly appraised, raise the old issues. To claim, as
I am to claim, that a description of its active chemical aspects must
contribute to any adequate description of life is not to imply that
a living organism is no more than a physico-chemical system. It
implies that at a definite and recognisable level of its dynamic
organisation an organism can be logically described in physico-
chemical terms alone. At such a level indeed we may hope ulti-
mately to arrive at a description which is complete in itself, just as
descriptions at the morphological level of organisation may be
complete in themselves. There may be yet higher levels calling
for discussion in quite different terms.

I wish, however, to remind you of a mode of thought concerning
the material basis of life, which though it prevailed when physico-
chemical interpretations were fashionable, was yet almost as in-
hibitory to productive chemical thought and study as any of the
claims of vitalism. ‘This was the conception of that material basis
as a single entity, as a definite though highly complex chemical
compound. Up to the end of the last century and even later the
term ‘protoplasm’ suggested such an entity to many minds. In his
brilliant Presidential Address at the Association’s meeting at Dundee
twenty-two years ago, Sir Edward Sharpey-Schafer, after remarking
that the elements composing living substances are few in number,
went on to say: ‘ The combination of these elements into a colloid
compound represents the physical basis of life, and when the chemist
succeeds in building up this compound it will, without doubt, be
found to exhibit the phenomena which we are in the habit of asso-
ciating with the term “life” ’ Such a compound would seem
to correspond with the ‘ protoplasm’ of many biologists, though
treated perhaps with too little respect. The Presidential claim
might have seemed to encourage the biochemist, but the goal
suggested would have proved elusive, and the path of endeavour has
followed other lines.

So long as the term ‘ protoplasm ’ retains a morphological signi-
ficance as in classical cytology, it may be even now convenient
enough, though always denoting an abstraction. In so far, how-
ever, as the progress of metabolism with all the vital activities which
it supports was ascribed in concrete thought to hypothetical qualities
emergent from a protoplasmic complex in its integrity or when
substances were held to suffer change only because in each living
cell they are first built up, with loss of their own molecular structure
and identity, ino this complex, which is itself the inscrutable seat
of cyclic change, then serious obscurantism was involved.

Had such assumptions been justified the old taunt that when the

THE PRESIDENTIAL ADDRESS 5

chemist touches living matter it immediately becomes dead matter
would also have been justified. A very distinguished organic
chemist, long since dead, said to me in the late eighties: ‘ The
chemistry of the living? That is the chemistry of protoplasm ;
that is superchemistry ; seek, my young friend, for other ambitions.’

Research, however, during the present century, much of which has
been done since the Association last met in Leicester, has yielded
knowledge to justify the optimism of the few who started to work in
those days. Were there time, I might illustrate this by abundant
examples ; but I think a single illustration will suffice to demon-
strate how progress during recent years has changed the outlook for
biochemistry. I will ask you to note the language used thirty
years ago to describe the chemical events in active muscle and
compare it with that used now. In 1895 Michael Foster, a physio-
logist of deep vision, dealing with the respiration of tissues, and in
particular with the degree to which the activity of muscle depends
on its contemporary oxygen supply, expounded the current view
which may be thus briefly summarised. ‘The oxygen which enters
the muscle from the blood is not involved in immediate oxidations,
but is built up into the substance of the muscle. It disappears into
some protoplasmic complex on which its presence confers instability.
This complex, which like all living substance, is to be regarded as
incessantly undergoing changes of a double kind, those of building
up and those of breaking down. With activity the latter predomi-
nates, and in the case of muscle the complex in question explodes,
as it were, to yield the energy for contraction. ‘ We cannot yet
trace,’ Foster comments, ‘ the steps taken by the oxygen from the
moment it slips from the blood into the muscle substance to the
moment when it issues united with carbon as carbonic acid. The
whole mystery of life lies hidden in that process, and for the present
we must be content with simply knowing the beginning and the
end.’ What we feel entitled to say to-day concerning the respira-
tion of muscle and of the events associated with its activity requires,
as I have suggested, a different language, and for those not interested
in technical chemical aspects the very change of language may yet
be significant. The conception of continuous building up and
continuous breakdown of the muscle substance as a whole, has but
a small element of truth. The colloidal muscle structure is, so to
speak, an apparatus, relatively stable even as a whole when meta-
bolism is normal, and in essential parts very stable. ‘The chemical
reactions which occur in that apparatus have been followed with a
completeness which is, I think, striking. It is carbohydrate stores
distinct from the apparatus (and in certain circumstances also fat
stores) which undergo steady oxidation and are the ultimate sources
of energy for muscular work. Essential among successive stages in

6 THE PRESIDENTIAL ADDRESS

the chemical breakdown of carbohydrate which necessarily precede
oxidation is the intermediate combination of a sugar (a hexose) with
phosphoric acid to form an ester. This happening is indispensable for
the progress of the next stage, namely the production of lactic acid from
the sugar, which is an anaerobic process. The precise happenings
to the hexose sugar while in combination with phosphoric acid are
from a chemical standpoint remarkable. Very briefly stated they are
these. One half of the sugar molecule is converted into a molecule
of glycerin and the other half into one of pyruvic acid. Now with
loss of two hydrogen atoms glycerin yields lactic acid, and, with a
gain of the same pyruvic acid also yields lactic acid. The actual
happening then is that hydrogen is transferred from the glycerin
molecule while still combined with phosphoric acid to the pyruvic
acid molecule with the result that two molecules of lactic acid
are formed.1_ The lactic acid is then, during a cycle of change which
I must not stop to discuss, oxidised to yield the energy required by
the muscle.

But the energy from this oxidation is byno means directly available
for the mechanical act of contraction. The oxidation occurs indeed
after and not before or during a contraction. The energy it
liberates secures however the endothermic resynthesis of a sub-
stance, creatin phosphate, of which the breakdown at an earlier
stage in the sequence of events is the more immediate source of
energy for contraction. Even more complicated are these chemical
relations, for it would seem that in the transference of energy from
its source in the oxidation of carbohydrate to the system which
synthesises creatin phosphate, yet another reaction intervenes,
namely, the alternating breakdown and resynthesis of the substance
adenyl pyrophosphate. The sequence of these chemical reactions
in muscle has been followed and their relation in time to the phases
of contraction and relaxation is established. ‘The means by which
energy is transferred from one reacting system to another has till
lately been obscure, but current work is throwing light upon this
interesting question, and it is just beginning (though only beginning)
to show how at the final stage the energy of the reactions is con-
verted into the mechanical response. In parenthesis it may be noted
as an illustration of the unity of life that the processes which occur in
the living yeast cell in its dealings with sugars are closely similar to
those which proceed in living muscle. In the earlier stages they are
identical and we now know where they part company. You will, I
think, be astonished at the complexity of the events which underlie
the activity of a muscle, but you must remember that it is a highly
specialised machine. A more direct burning of the fuel could not
fit into its complex organisation. Iam more particularly concerned

1 Lecture by Otto Meyerhof: in the Press (see Nature).

THE PRESIDENTIAL ADDRESS 7

to feel that my brief summary of the facts will make you realise how
much more definite, how much more truly chemical, is our present
knowledge than that available when Michael Foster wrote. Ability
to recognise the progress of such definite ordered chemical reactions
in relation to various aspects of living activity characterises the
current position in biochemistry. I have chosen the case of muscle,
and it must serve as my only example, but many such related and
ordered reactions have been studied in other cells and tissues, from
bacteria to the brain. Some prove general, some more special.
Although we are far indeed from possessing a complete picture in
any one case we are beginning in thought to fit not a few pieces
together. We are on a line safe for progress.

I must perforce limit the field of my discussion, and in what
follows my special theme will be the importance of molecular
structure in determining the properties of living systems. I wish
you to believe that molecules display in such systems the properties
inherent in their structure even as they do in the laboratory of the
organic chemist. The theme is no new one, but its development
illustrates as well as any other, and to my own mind perhaps better
than any other, the progress of biochemistry. Not long ago a
prominent biologist, believing in protoplasm as an entity, wrote :
‘But it seems certain that living protoplasm is not an ordinary
chemical compound, and therefore can have no molecular structure
in the chemical sense of the word.’ Such a belief was common.
One may remark, moreover, that when the development of colloid
chemistry first brought its indispensable aid towards an under-
standing of the biochemical field, there was a tendency to discuss
its bearing in terms of the less specific properties of colloid systems,
phase-surfaces, membranes, and the like, without sufficient reference
to the specificity which the influence of molecular structure, where-
ever displayed, impresses on chemical relations and events. In
emphasising its importance I shall leave no time for dealings with
the nature of the colloid structures of cells and tissues, all important
as they are. I shall continue to deal, though not again in detail,
with chemical reactions as they occur within those structures. Only
this much must be said. If the colloid structures did not display
highly specialised molecular structure at their surface, no reactions
would occur; for here catalysis occurs. Were it not equipped
with catalysts every living unit would be a static system.

With the phenomena of catalysis I will assume you have general
acquaintance. You know that a catalyst is an agent which plays
only a temporary part in chemical events which it nevertheless
determines and controls. It reappears unaltered when the events
are completed. ‘The phenomena of catalysis, though first recognised
early in the last century, entered but little into chemical thought

8 THE PRESIDENTIAL ADDRESS

or enterprise, till only a few years ago they were shown to have
great importance for industry. Yet catalysis is one of the most
significant devices of nature, since it has endowed living systems
with their fundamental character as transformers of energy, and
all evidence suggests that it must have played an indispensable
part in the living universe from the earliest stages of evolution.

The catalysts of a living cell are the enzymic structures which
display their influences at the surface of colloidal particles or at other
surfaces within the cell. Current research continues to add to the
great number of these enzymes which can be separated from, or
recognised in, living cells and tissues, and to increase our knowledge
of their individual functions.

A molecule within the system of the cell may remain in an inactive
state and enter into no reactions until at one such surface it comes
in contact with an enzymic structure which displays certain adjust-
ments to its own structure. While in such association the inactive
molecule becomes (to use a current term) ‘ activated,’ and then enters
on some definite path of change. The one aspect of enzymic
catalysis which for the sake of my theme I wish to emphasise is its
high specificity. An enzyme is in general adjusted to come into
effective relations with one kind of molecule only, or at most with
molecules closely related in their structure. Evidence based on
kinetics justifies the belief that some sort of chemical combination
between enzyme and related molecule precedes the activation of
the latter, and for such combinations there must be close correlation
in structure. Many will remember that long ago Emil Fischer
recognised that enzymic action distinguishes even between two
optical isomers and spoke of the necessary relation being as close
as that of key and lock.

There is an important consequence of this high specificity in
biological catalysis to which I will direct your special attention.
A living cell is the seat of a multitude of reactions, and in order
that it should retain in a given environment its individual identity
as an organism, these reactions must be highly organised. They
must be of determined nature and proceed mutually adjusted with
respect to velocity, sequence, and in all other relations. ‘They must
be in dynamic equilibrium as a whole and must return to it after
disturbance. Now if of any group of catalysts, such as are found
in the equipment of a cell, each one exerts limited and highly-
specific influence, this very specificity must be a potent factor in
making for organisation.

Consider the case of any individual cell in due relations with
its environment, whether an internal environment as in the case of
the tissue cells of higher animals, or an external environment as
in the case of unicellular organisms. Materials for maintenance of

THE PRESIDENTIAL ADDRESS 9

the cell enter it from the environment. Discrimination among
such materials is primarily determined by permeability relations,
but of deeper significance in that selection is the specificity of the
cell catalysts. It has often been said that the living cell differs
from all non-living systems in its power of selecting from a hetero-
geneous environment the right material for the maintenance of its
structure and activities. It is, however, no vital act but the nature
of its specific catalysts which determines what it effectively ‘ selects.’
If a molecule gains entry into the cell and meets no catalytic influence
capable of activating it, nothing further happens save for certain
ionic and osmotic adjustments. Any molecule which does meet
an adjusted enzyme cannot fail to suffer change and become
directed into some one of the paths of metabolism. It must here
be remembered, moreover, that enzymes as specific catalysts not
only promote reactions, but determine their direction. The glucose
molecule, for example, though its inherent chemical potentialities
are, of course, always the same, is converted into lactic acid by an
enzyme system in muscle but into alcohol and carbon dioxide by
another in the yeast cell. It is important to realise that diverse
enzymes may act in succession and that specific catalysis has directive
as well as selective powers. If it be syntheses in the cell which are
most difficult to picture on such lines, we may remember that
biological syntheses can be, and are, promoted by enzymes, and
there are sufficient facts to justify the belief that a chain of specific
enzymes can direct a complex synthesis along lines predetermined
by the nature of the enzymes themselves. I should like to develop
this aspect of the subject even further, but to do so might tax your
patience. I should add that enzyme-control, though so important,
is not the sole determinant of chemical organisation in a cell. Other
aspects of its colloidal structure play their part.

III.

It is surely at that level of organisation, which is based on the
exact co-ordination of a multitude of chemical events within it,
that a living cell displays its peculiar sensitiveness to the influence
of molecules of special nature when these enter it from without.
The nature of very many organic molecules is such that they may
enter a cell and exert noeffect. Those proper to metabolism follow,
of course, the normal paths of change. Some few, on the other
hand, influence the cell in very special ways. When such influence
is highly specific in kind it means that some element of structure
in the entrant molecule is adjusted to meet an aspect of molecular
structure somewhere in the cell itself. We can easily understand
that in a system so minute the intrusion even of a few such molecules

B2

10 THE PRESIDENTIAL ADDRESS

may so modify existing equilibria as to affect profoundly the observed
behaviour of the cell.

Such relations, though by no means confined to them, reach their
greatest significance in the higher organisms, in which individual
tissues, chemically diverse, differentiated in function and separated
in space, so react upon one another through chemical agencies trans-
mitted through the circulation as to co-ordinate by chemical trans-
port the activities of the body as a whole. Unification by chemical
means must to-day be recognised as a fundamental aspect of all
such organisms. In all of them it is true that the nervous system
has pride of place as the highest seat of organising influence, but
we know to-day that even this influence is often, if not always,
exerted through properties inherent in chemical molecules. It is
indeed most significant for my general theme to realise that when
a nerve impulse reaches a tissue the sudden production of a definite
chemical substance at the nerve ending may be essential to the
response of that tissue to the impulse. It is a familiar circumstance
that when an impulse passes to the heart by way of the vagus nerve
fibres the beat is slowed, or, by a stronger beat, arrested. ‘That is,
of course, part of the normal control of the heart’s action. Now
it has been shown that whenever the heart receives vagus impulses
the substance acetyl cholin is liberated within the organ. To this
fact is added the further fact that, in the absence of the vagus influence,
the artificial injection of minute graded doses of acetyl choline so
acts upon the heart as to reproduce in every detail the effects of graded
stimulation of the nerve. Moreover, evidence is accumulating to
show that in the case of other nerves belonging to the same morpho-
logical group as the vagus, but supplying other tissues, this same
liberation of acetyl choline accompanies activity, and the chemical
action of this substance upon such tissues again produces effects
identical with those observed when the nerves are stimulated.
More may be claimed. The functions of another group of nerves
are opposed to those of the vagus group ; impulses, for instance,
through certain fibres accelerate the heart beat. Again a chemical
substance is liberated at the endings of such nerves, and this substance
has itself the property of accelerating the heart. We find then that
such organs and tissues respond only indirectly to whatever non-
specific physical change may reach the nerve ending. ‘Their direct
response is to the influence of particular molecules with an essential
structure when these intrude into their chemical machinery.

It follows that the effect of a given nerve stimulus may not be
confined to the tissue which it first reaches. "There may be humeral
transmissions of its effect, because the liberated substance enters
the lymph and blood. This again may assist the co-ordination of
events in the tissues.

THE PRESIDENTIAL ADDRESS II

From substances produced temporarily and locally and by
virtue of their chemical properties translating for the tissues the
messages of nerves, we may pass logically to consideration of those
active substances which carry chemical messages from organ to
organ. Such in the animal body are produced continuously in
specialised organs, and each has its special seat or seats of action
where it finds chemical structures adjusted in some sense or other
to its own.

I shall be here on familiar ground, for that such agencies exist,
and bear the name of hormones, is common knowledge. I propose
only to indicate how many and diverse are their fuctions as revealed
by recent research, emphasising the fact that each one is a definite
and relatively simple substance with properties that are primarily
chemical and in a derivate sense physiological. Our clear recognition
of this, based at first on a couple of instances, began with this century,
but our knowledge of their number and nature is still growing rapidly
to-day.

We have long known, of course, how essential and profound is
the influence of the thyroid gland in maintaining harmonious growth
in the body, and in controlling the rate of its metabolism. Three
years ago a brilliant investigation revealed the exact molecular
structure of the substance—thyroxin—which is directly responsible
for these effects. It is a substance of no great complexity. The
constitution of adrenalin has been longer known and likewise its
remarkable influence in maintaining a number of important physio-
logical adjustments. Yet is is again a relatively simple substance.
I will merely remind you of secretin, the first of these substances
to receive the name of hormone, and of insulin, now so familiar
because of its importance in the metabolism of carbohydrates and its
consequent value in the treatment of diabetes. ‘The most recent
growth of knowledge in this field has dealt with hormones which,
in most remarkable relations, co-ordinate the phenomena of sex.

It is the circulation of definite chemical substances produced
locally that determines during the growth of the individual, the
proper development of all the secondary sexual characters. The
properties of other substances secure the due progress of individual
development from the unfertilised ovum to the end of feetal life.
When an ovum ripens and is discharged from the ovary a substance,
now known as estrin, is produced in the ovary itself, and so functions
as to bring about all those changes in the female body which make
secure the fertilisation of the ovum. On the discharge of the ovum
new tissue, constituting the so-called corpus luteum, arises in its
place. This then produces a special hormone which in its turn
evokes all those changes in tissues and organs that secure a right
destiny for the ovum after it has been fertilised. It is clear that

12 THE PRESIDENTIAL ADDRESS

these two hormones do not arise simultaneously, for they must act
in alternation, and it becomes of great interest to know how such
succession is secured. The facts here are among the most striking.
Just as higher nerve centres in the brain control and co-ordinate the
activities of lower centres, so it would seem do hormones, functioning
at, so to speak, a higher level in organisation, co-ordinate the activities
of other hormones. It is a substance produced in the anterior portion
of the pituitary gland situated at the base of the brain, which by
circulating to the ovary controls the succession of its hormonal
activities. "The cases I have mentioned are far from exhausting the
numerous hormonal influences now recognised.

For full appreciation of the extent to which chemical substances
control and co-ordinate events in the animal body by virtue of
their specific molecular structure, it is well not to separate too widely
in thought the functions of hormones from those of vitamins.
Together they form a large group of substances of which every
one exerts upon physiological events its own indispensable chemical
influence.

Hormones are produced in the body itself, while vitamins must be
supplied in the diet. Such a distinction is, in general, justified.
We meet occasionally, however, an animal species able to dispense
with an external supply of this or that vitamin. Evidence shows,
however, that individuals of that species, unlike most animals, can
in the course of their metabolism synthesise for themselves the
vitamin in question. The vitamin then becomes a hormone. In
practice the distinction may be of great importance, but for an
understanding of metabolism the functions of these substances are
of more significance than their origin.

The present activity of research in the field of vitamins is prodigious.
The output of published papers dealing with original investigations
in the field has reached nearly a thousand in a single year. Each
of the vitamins at present known is receiving the attention of
numerous observers in respect both of its chemical and biological
properties, and though many publications deal, of course, with matters
of detail, the accumulation of significant facts is growing fast.

It is clear that I can cover but little ground in any reference to
this wide field of knowledge. Some aspects of its development have
been interesting enough. The familiar circumstance that attention
was drawn to the existence of one vitamin (B, so called) because
populations in the East took to eating milled rice instead of the
whole grain; the gradual growth of evidence which links the
physiological activities of another vitamin (D) with the influence of
solar radiation on the body, and has shown that they are thus
related, because rays of definite wave-length convert an inactive

precurser into the active vitamin, alike when acting on foodstuffs

THE PRESIDENTIAL ADDRESS 13

or on the surface of the living body ; the fact again that the recent
isolation of vitamin C, and the accumulation of evidence for its
nature started from the observation that the cortex of the adrenal
gland displayed strongly reducing properties ; or yet again the proof
that a yellow pigment widely distributed among plants, while not
the vitamin itself, can be converted within the body into vitamin A;
these and other aspects of vitamin studies will stand out as interesting
chapters in the story of scientific investigation.

In this very brief discussion of hormones and vitamins I have so
far referred only to their functions as manifested in the animal body.
Kindred substances, exerting analogous functions, are, however, of
wide and perhaps of quite general biological importance. It is
certain that many micro-organisms require a supply of vitamin-like
substances for the promotion of growth, and recent research of a very
interesting kind has demonstrated in the higher plants the existence
of specific substances produced in special cells which stimulate
growth in other cells, and so in the plant as a whole. These so-
called auxines are essentially hormones. Section B will soon be
listening to an account of their chemical nature.

It is of particular importance to my present theme and a source
of much satisfaction to know that our knowledge of the actual mole-
cular structure of hormones and vitamins is growing fast. We have
already exact knowledge of the kind in respect to not a few. We are
indeed justified in believing that within a few years such knowledge
will be extensive enough to allow a wide view of the correlation
between molecular structure and physiological activity. Such
correlation has long been sought in the case of drugs, and some
generalisations have been demonstrated. It should be remembered,
however, that until quite lately only the structure of the drug could
be considered. With increasing knowledge of the tissue structures
pharmacological actions will become much clearer.

I cannot refrain from mentioning here a set of relations connected
especially with the phenomena of tissue growth which are of par-
ticular interest. It will be convenient to introduce some technical
chemical considerations in describing them, though I think the
relations may be clear without emphasis being placed on such
details. ‘The vitamin, which in current usage is labelled ‘ A,’ is
essential for the general growth of an animal. Recent research has
provided much information as to its chemical nature. Its molecule
is built up of units which possess what is known to chemists as the
isoprene structure. These are condensed in a long carbon chain
which is attached to a ring structure of a specific kind. Such a
constitution relates it to other biological compounds, in particular
to certain vegetable pigments, one of which a carotene, so called, is
the substance which I have mentioned as being convertible into the

14 THE PRESIDENTIAL ADDRESS

vitamin. For the display of an influence upon growth, however,
the exact details of the vitamin’s proper structure must be established.
Now turning to vitamin D, of which the activity is more specialised,
controlling as it does the growth of bone in particular, we have
learnt that the unit elements in its structure are again isoprene
radicals ; but instead of forming a long chain as in vitamin A they
are united into a system of condensed rings. Similar rings form
the basal component of the molecules of sterols, substances which
are normal constituents of nearly every living cell. It is one of
these, inactive itself, which ultra-violet radiation converts into
vitamin D. We know that as stated each of these vitamins stimu-
lates growth in tissue cells. Next consider another case of growth
stimulation, different because pathological in nature. As you are
doubtless aware, it is well known that long contact with tar induces
a cancerous growth of the skin. Very important researches have
recently shown that particular constituents in the tar are alone con-
cerned in producing this effect. It is being further demonstrated
that the power to produce cancer is associated with a special type of
molecular structure in these constituents. ‘This structure, like that
of the sterols, is one of condensed rings, the essential difference
being that (in chemical language) the sterol rings are hydrogenated,
whereas those in the cancer-producing molecules are not. Hydro-
genation indeed destroys the activity of the latter. Recall, however,
the ovarian hormone estrin. Now the molecular structure of cestrin
has the essential ring structure of a sterol, but one of the constituent
rings is not hydrogenated. In a sense therefore the chemical nature
of estrin links vitamin D with that of cancer-producing substances.
Further, it is found that substances with pronounced cancer-pro-
ducing powers may produce effects in the body like those of cestrin.
It is difficult when faced with such relations not to wonder whether
the metabolism of sterols, which when normal can produce a sub-
stance stimulating physiological growth, may in very special circum-
stances be so perverted as to produce within living cells a substance
stimulating pathological growth. Such a suggestion must, however,
with present knowledge, be very cautiously received. It is wholly
without experimental proof. My chief purpose in this reference to
this very interesting set of relations is to emphasise once more the
significance of chemical structure in the field of biological events.

Only the end results of the profound influence which minute
amounts of substances with adjusted structure exert upon living cells
or tissues can be observed in the intact bodies of man or animals.
It is doubtless because of the elaborate and sensitive organisation of
chemical events in every tissue cell that the effects are proportionally
So great.

It is an immediate task of biochemistry to explore the mechanism

THE PRESIDENTIAL ADDRESS 15

of such activities. It must learn to describe in objective chemical
terms precisely how and where such molecules as those of hormones
and vitamins intrude into the chemical events of metabolism. It is
indeed now beginning this task which is by no means outside the
scope of its methods. Efforts of this and of similar kind cannot
fail to be associated with a steady increase in knowledge of the whole
field of chemical organisation in living organisms, and to this increase
we look forward with confidence. The promise is there. Present
methods can still go far, but I am convinced that progress of the kind
is about to gain great impetus from the application of those new
methods of research which chemistry is inheriting from physics:
X-ray analysis; the current studies of unimolecular surface films
and of chemical reactions at surfaces ; modern spectroscopy ; the
quantitative developments of photo-chemistry ; no branch of
inquiry stands to gain more from such advances in technique than
does biochemistry at its present stage. Especially is this true in the
case of the colloidal structure of living systems, of which in this
Address I have said so little.

IV.

As an experimental science, biochemistry, like classical physi-
ology, and much of experimental biology, has obtained, and must
continue to obtain, many of its data from studying parts of the
organism in isolation, but parts in which dynamic events continue.
Though fortunately it has also methods of studying reactions as they
occur in intact living cells, intact tissues, and, of course, in the intact
animal, it is still entitled to claim that its studies of parts are con-
sistently developing its grasp of the Wholes it desires to describe,
however remote that grasp may be from finality. Justification for
any such claim has been challenged in advance from a certain philo-
sophic standpoint. Not from that of General Smuts, though in his
powerful Address which signalised our centenary meeting he, like
many philosophers to-day, emphasised the importance of properties
which emerge from systems in their integrity, bidding us remember
that a part while in the whole is not the same as the part in isolation.
He hastened to admit in a subsequent speech, however, that for
experimental biology, as for any other branch of science, it was
logical and necessary to approach the whole through its parts. Nor
again is the claim challenged from the standpoint of such a teacher
as A. N. Whitehead, though in his philosophy of organic mechanism
there is no real entity of any kind without internal and multiple
relations, and each whole is more than the sum of its parts. I never-
theless find ad hoc statements in his writings which directly encourage
the methods of biochemistry. In the teachings of J. S. Haldane,
however, the value of such methods have long been directly

16 THE PRESIDENTIAL ADDRESS

challenged. Some here will perhaps remember that in his Address
to Section I, twenty-five years ago he described a philosophic stand-
point which he has courageously maintained in many writings since.
Dr. Haldane holds that to the enlightened biologist a living organism
does not present a problem for analysis ; it is, gua organism, axio-
matic. Its essential attributes are axiomatic; heredity, for example,
is for biology not a problem but an axiom. ‘The problem of
Physiology is not to obtain piecemeal physico-explanations of
physiological processes ’ (I quote from the 1885 Address), ‘ but to
discover by observation and experiment the relatedness to one
another of all the details of structure and activity in each organism
as expressions of its nature as one organism.’ I cannot pretend
adequately to discuss these views here. They have often been
discussed by others, not always perhaps with understanding. What
is true in them is subtle, and I doubt if their author has ever found
the right words in which to bring to most others a conviction of
such truth. It is involved in a world outlook. What I think is
scientifically faulty in Haldane’s teaching is the @ priori element
which leads to bias in the face of evidence. The task he sets for
the physiologist seems vague to most people, and he forgets that
with good judgment a study of parts may lead to an intellectual
synthesis of value. In 1885 he wrote: ‘That a meeting-point
between Biology and Physical Science may at some time be found
there is no reason for doubting. But we may confidently predict
that if that meeting-point is found, and one of the two sciences
is swallowed up, that one will not be Biology.’ He now claims
indeed that biology has accomplished the heavy meal because
physics has been compelled to deal no longer with Newtonian
entities but, like the biologist, with organisms such as the atom
proves to be. Is it not then enough for my present purpose to
remark on the significance of the fact that not until certain atoms
were found spontaneously splitting piecemeal into parts, and others
were afterwards so split in the laboratory, did we really know any-
thing about the atom as a whole.

At this point, however, I will ask you not to suspect me of claiming
that all the attributes of living systems or even the more obvious
among them are necessarily based upon chemical organisation alone.
I have already expressed my own belief that this organisation will
account for one striking characteristic of every living cell—its ability,
namely, to maintain a dynamic individuality in diverse environments.
Living cells display other attributes even more characteristic of
themselves ; they grow, multiply, inherit qualities and transmit
them. Although to distinguish levels of organisation in such
systems may be to abstract from reality it is not illogical to believe
that such attributes as these are based upon organisation at a level

THE PRESIDENTIAL ADDRESS 17)

which is in some sense higher than the chemical level. The main
necessity from the standpoint of biochemistry is then to decide
whether nevertheless at its own level, which is certainly definable,
the results of experimental studies are self-contained and consistent.
This is assuredly true of the data which biochemistry is now acquir-
ing. Never during its progress has chemical consistency shown
itself to be disturbed by influences of any ultra-chemical kind.

Moreover, before we assume that there is a level of organisation
at which chemical controlling agencies must necessarily cease to
function, we should respect the intellectual parsimony taught by
Occam and be sure of their limitations before we seek for super-
chemical entities as organisers. ‘There is no orderly succession of
events which would seem less likely to be controlled by the mere
chemical properties of a substance than the cell divisions and _ cell
differentiation which intervene between the fertilised ovum and the
finished embryo. Yet it would seem that a transmitted substance,
a hormone in essence, may play an unmistakable part in that
remarkable drama. It has for some years been known that, at an
early stage of development, a group of cells forming the so-called
* organiser’ of Spemann induces the subsequent stages of differentia-
tion in other cells. The latest researches seem to show that a cell-
free extract of this ‘ organiser’ may function in its place. ‘The sub-
stance concerned is, it would seem, not confined to the ‘ organiser ’
itself, but is widely distributed outside, though not in, the embryo.
It presents, nevertheless, a truly remarkable instance of chemical
influence.

It would be out of place in such a discourse as this to attempt
any discussion of the psycho-physical problem. However much
we may learn about the material systems which, in their integrity,
are associated with consciousness, the nature of that association may
yet remain a problem. The interest of that problem is insistent
and it must be often in our thoughts. Its existence, however,
justifies no pre-judgments as to the value of any knowledge of a
consistent sort which the material systems may yield to experiment.

V.

It has become clear, I think, that chemical modes of thought,
whatever their limitation, are fated profoundly to affect biological
thought. If, however, the biochemist should at any time be inclined
to overrate the value of his contributions to biology, or to under-
rate the magnitude of problems outside his province, he will do well
sometimes to leave the laboratory for the field, or to seek even in the
museum a reminder of that infinity of adaptations of which life is
capable. He willthen not fail to work with a humble mind, however
great his faith in the importance of the methods which are his own.

18 THE PRESIDENTIAL ADDRESS

It is surely right, however, to claim that in passing from its
earlier concern with dead biological products to its present concern
with active processes within living organisms, biochemistry has
become a true branch of progressive biology. It has opened up modes
of thought about the physical basis of life which could scarcely be
employed at all a generation ago. Such data and such modes of
thought as it is now providing are pervasive, and must appear as
aspects in all biological thought. Yet these aspects are, of course,
only partial. Biology in all its aspects is showing rapid progress,
and its bearing on human welfare is more and more evident.

Unfortunately the nature of this new biological progress and its
true significance is known to but a small section of the lay public.
Few will doubt that popular interest in science is extending, but it is
mainly confined to the more romantic aspects of modern astronomy
and physics. That biological advances have made less impression
is probably due to more than one circumstance, of which the chief,
doubtless, is the neglect of biology in our educational system. The
startling data of modern astronomy and physics, though of course
only when presented in their most superficial aspects, find an easier
approach to the uninformed mind than those of the new experimental
biology can hope for. The primary concepts involved are para-
doxically less familiar. Modern physical science, moreover, has been
interpreted to the intelligent public by writers so brilliant that their
books have had a great and stimulating influence.

Lord Russell once ventured on the statement that in passing
from physics to biology one is conscious of a transition from the
cosmic to the parochial, because from a cosmic point of view life
is a very unimportant affair. Those who know that supposed parish
well are convinced that it is rather a metropolis entitled to much
more attention than it sometimes obtains from authors of guide-books
to the universe. It may be small in extent, but is the seat of all the
most significant events. In too many current publications, pur-
porting to summarise scientific progress, biology is left out or receives
but scant reference. Brilliant expositions of all that may be met in
the region where modern science touches philosophy have directed
thought straight from the implications of modern physics to the
nature and structure of the human mind, and even to speculation
concerning the mind of the Deity. Yet there are aspects of bio-
logical truth already known which are certainly germane to such
discussions, and probably necessary for their adequacy.

VI.
It is, however, because of its extreme importance to social pro-
gress that public ignorance of biology is especially to be regretted.
Sir Henry Dale has remarked that ‘it is worth while to consider

THE PRESIDENTIAL ADDRESS 19

to-day whether the imposing achievements of physical science
have not already, in the thought and interests of men at large,
as well as in technical and industrial development, overshadowed
in our educational and public policy those of biology to an ex-
tent which threatens a one-sided development of science itself
and of the civilisation which we hope to see based on science.’
Sir Walter Fletcher, whose death during the past year has deprived
the nation of an enlightened adviser, almost startled the public,
I think, when he said in a national broadcast that ‘ we can find safety
and progress only in proportion as we bring into our methods of
statecraft the guidance of biological truth.’ That statecraft, in its
dignity, should be concerned with biological teaching, was a new
idea to many listeners. A few years ago the Cambridge philosopher,
Dr. C. D. Broad, who is much better acquainted with scientific
data than are many philosophers, remarked upon the misfortune
involved in the unequal development of science ; the high degree
of our control over inorganic nature combined with relative ignorance
of biology and psychology. At the close of a discussion as to the
possibility of continued mental progress in the world, he summed up
by saying that the possibility depends on our getting an adequate
knowledge and control of life and mind before the combination of
ignorance on these subjects with knowledge of physics and cherhistry
wrecks the whole social system. He closed with the somewhat
startling words : ‘ Which of the runners in this very interesting race
will win it is impossible to foretell. But physics and death have a
long start over psychology and life!’ No one surely will wish for,
or expect, a slowing in the pace of the first, but the quickening up
in the latter which the last few decades have seen is a matter for high
satisfaction. But, to repeat, the need for recognising biological
truth as a necessary guide to individual conduct and no less to state-
craft and social policy still needs emphasis to-day. With frank
acceptance of the truth that his own nature is congruent with all
those aspects of nature at large which biology studies, combined with
intelligent understanding of its teaching, man would escape from
innumerable inhibitions due to past history and present ignorance,
and equip himself for higher levels of endeavour and success.

- Inadequate as at first sight it may seem when standing alone in
support of so large a thesis, I must here be content to refer briefly
to a single example of biological studies bearing upon human
welfare. I will choose one which stands near to the general theme
of my address. I mean the current studies of human and animal
nutrition. You are well aware that during the last twenty years—
that is, since it adopted the method of controlled experiment—the
study of nutrition has shown that the needs of the body are much
more complex than was earlier thought, and in particular that

20 THE PRESIDENTIAL ADDRESS

substances consumed in almost infinitesimal amounts may, each in
its way, be as essential as those which form the bulk of any adequate
dietary. This complexity in its demands will, after all, not surprise
those who have in mind the complexity of events in the diverse
living tissues of the body.

My earlier reference to vitamins, which had somewhat different
bearings, was, I am sure, not necessary for a reminder of their nutri-
tional importance. Owing to abundance of all kinds of advertise-
ment vitamins are discussed in the drawing-room as well as in the
dining-room, and also, though not so much, in the nursery, while
at present perhaps not enough in the kitchen. Unfortunately,
among the uninformed their importance in nutrition is not always
viewed with discrimination. Some seem to think nowadays that if
the vitamin supply is secured the rest of the dietary may be left to
chance, while others suppose that they are things so good that we
cannot have too much of them. Needless tosay, neither assumption
is true. With regard to the second indeed it is desirable, now that
vitamin concentrates are on the market and much advertised, to
remember that excess of a vitamin may be harmful. In the case of
that labelled D at least we have definite evidence of this. Neverthe-
less the claim that every known vitamin has highly important
nutritional functions is supported by evidence which continues to
grow. It is probable, but perhaps not yet certain, that the human
body requires all that are known.

The importance of detail is no less in evidence when the demands
of the body for a right mineral supply are considered. A proper
balance among the salts which are consumed in quantity is here of
prime importance, but that certain elements which ordinary foods
contain in minute amounts are indispensable in such amounts is
becoming sure. ‘To take but a single instance: the necessity of a
trace of copper, which exercises somewhere in the body an indis-
pensable catalytic influence on metabolism, is as essential in its way
as much larger supplies of calcium, magnesium, potassium or iron.
Those in close touch with experimental studies continually receive
hints that factors still unknown contribute to normal nutrition, and
those who deal with human dietaries from a scientific standpoint
know that an ideal diet cannot yet be defined. This reference to
nutritional studies is indeed mainly meant to assure you that the
great attention they are receiving is fully justified. No one here,
I think, will be impressed with the argument that because the human
race has survived till now in complete ignorance of all such details
the knowledge being won must have academic interest alone. This
line of argument is very old and never right.

One thing I am sure may be claimed for the growing enlighten-
ment concerning human nutrition and the recent recognition of its

THE PRESIDENTIAL ADDRESS 21

study. It has already produced one line of evidence to show that
Nurture can assist Nature to an extent not freely admitted a few
years ago. That is a subject which I wish I could pursue. I cannot
myself doubt that various lines of evidence, all of which should be
profoundly welcome, are pointing in the same direction.

Allow me just one final reference to another field of nutritional
studies. Their great economic importance in animal husbandry calls
for full recognition. Just now agricultural authorities are becoming
acutely aware of the call for a better control of the diseases of animals.
Together these involve an immense economic loss to the farmers, and
therefore to the country. Although, doubtless, its influence should
not be exaggerated, faulty nutrition plays no small share in accounting
for the incidence of some among these diseases, as researches carried
out at the Rowett Institute in Aberdeen and elsewhere are demon-
strating. There is much more of such work to be done with great
profit.

VII.

In every branch of science the activity of research has greatly
increased during recent years. ‘This all will have realised, but only
those who are able to survey the situation closely can estimate the
extent of that increase. It occurred to me at one time that an
appraisement of research activities in this country, and especially the
organisation of State-aided research, might fittingly form a part of
my address. ‘The desire to illustrate the progress of my own sub-
ject led me away from that project. I gave some time to a survey
however, and came to the conclusion, among others, that from eight
to ten individuals in the world are now engaged upon scientific
investigations for every one so engaged twenty years ago. It must
be remembered, of course, that not only has research endowment
greatly increased in America and Europe, but that Japan, China, and
even India have entered the field and are making contributions to
science of real importance. It is sure that, whatever the conse-
quences, the increase of scientific knowledge is at this time under-
going a positive acceleration.

Apropos, I find difficulty as to-day’s occupant of this important
scientific pulpit in avoiding some reference to impressive words
spoken by my predecessor which are still echoed in thought, talk and
print. In his wise and eloquent address at York Sir Alfred Ewing
reminded us with serious emphasis that the command of Nature has
been put into man’s hand before he knows how to command himself.
Of the dangers involved in that indictment he warned us; and we
should remember that General Smuts also sounded the same note
of warning in London.

Of Science itself it is, of course, noindictment. It may be thought

22 THE PRESIDENTIAL ADDRESS

of rather as a warning signal to be placed on her road: ‘ Dangerous
Hill Ahead,’ perhaps, or ‘ Turn Right’; not, however, ‘ Go Slow,’
for that advice Science cannot follow. The indictment is of man-
kind. Recognition of the truth it contains cannot be absent from the
minds of those whose labours are daily increasing mankind’s com-
mand of Nature; but it is due to them that the truth should be
viewed in proper perspective. It is, after all, war, to which Science
has added terrors, and the fear of war, which alone give it real
urgency ; an urgency which must of course be felt in these days
when some nations at least are showing the spirit of selfish and
dangerous nationalism. I may be wrong but it seems to me that,
war apart, the gifts of science and invention have done little to
increase opportunities for the display of the more serious of man’s
irrational impulses. ‘The worst they do perhaps is to give to clever
and predatory souls that keep within the law, the whole world for
their depredations, instead of a parish or a country as of yore.

But Sir Alfred Ewing told us of ‘ the disillusion with which, now
standing aside, he watches the sweeping pageant of discovery and
invention in which he used to make unbounded delight.’ I wish
that one to whom applied science and this country owe so much
might have been spared such disillusion, for I suspect it gives him
pain. I wonder whether, if he could have added to an ‘ Engineer’s
Outlook’ the outlook of a biologist, the disillusion would still be
there. As one just now advocating the claims of biology I would
much like to know. It is sure, however, that the gifts of the engineer
to humanity at large are immense enough to outweigh the assistance
he may have given to the forces of destruction.

It may be claimed for biological science, in spite of vague references
to bacterial warfare and the like, that it is not of its nature to aid
destruction. What it may do towards making man as a whole more
worthy of his inheritance has yet to be fully recognised. On this
point I have said much. Of its service to his physical betterment
you will have no doubts. I have made but the bare reference in this
address to the support that biological research gives to the art of
medicine. I had thought to say much more of this, but found that
if I said enough I could say nothing else.

There are two other great questions so much to the front just now
that they tempt a final reference. I mean, of course, the paradox
of poverty amidst plenty and the replacement of human labour by
machinery. Applied science should take no blame for the former,
but indeed claim credit unfairly lost. It is not within my capacity
to say anything of value about the paradox and its cure ; but I con-
fess that I see more present danger in the case of ‘ Money versus
Man’ than danger present or future in that of the ‘ Machine versus
Man’!

THE PRESIDENTIAL ADDRESS 23

With regard to the latter it is surely right that those in touch with
science should insist that the replacement of human labour will
continue. Those who doubt this cannot realise the meaning of
that positive acceleration in science, pure and applied, which now
continues. No one can say what kind of equilibrium the distribution
of leisure is fated to reach. In any case an optimistic view as to
the probable effects of its increase may be justified.

It need not involve a revolutionary change if there is real planning
for the future. Lord Melchett was surely right when some time
ago he urged on the upper House that present thought should be
given to that future; but I think few men of affairs seriously
believe what is yet probable, that the replacement we are thinking of
will impose a new structure upon society. This may well differ in
some essentials from any of those alternative social forms of which
the very names now raise antagonisms. I confess that if civilisation
escapes its other perils I should fear little the final reign of the
machine. We should not altogether forget the difference in use
which can be made of real and ample leisure compared with that
possible for very brief leisure associated with fatigue; nor the
difference between compulsory toil and spontaneous work. Wehave
to picture, moreover, the reactions of a community which, save
for a minority, has shown itself during recent years to be educable.
I do not think it fanciful to believe that our highly efficient national
broadcasting service, with the increased opportunities which the
coming of short wave-length transmission may provide, might well
take charge of the systematic education of adolescents after the
personal influence of the schoolmaster has prepared them to profit
by it. It would not be a technical education but an education for
leisure. Listening to organised courses of instruction might at first
befor the few; but ultimately might become habitual in the com-
munity which it would specially benefit.

In parenthesis allow me a brief further reference to ‘ planning.’
The word is much to the front just now, chiefly in relation with
current enterprises. But there may be planning for more funda-
mental developments ; for future adjustment to social reconstructions.
In such planning the trained scientific mind must play its part. Its
vision of the future may be very limited, but in respect of material
progress and its probable consequences Science (I include all
branches of knowledge to which the name applies) has at least
better data for prophecy than other forms of knowledge.

It was long ago written, ‘Wisdom and Knowledge shall be
stability of Thy times.’ Though statesmen may have wisdom ade-
quate for the immediate and urgent problems with which it is their
fate to deal, there should yet be a reservoir of synthesised and
clarified knowledge on which they can draw. The technique which

24 THE PRESIDENTIAL ADDRESS

brings Governments in contact with scientific knowledge in parti-
cular, though greatly improved of late, is still imperfect. In any
case the politician is perforce concerned with the present rather
than the future. I have recently read Bacon’s New Atlantis afresh
and have been thinking about his Solomon’s House. We know
that the rules for the functioning of that House were mistaken
because the philosopher drew them up when in the mood of a
Lord Chancellor ; but in so far as the philosopher visualised therein
an organisation of the best intellects bent on gathering knowledge
for future practical services, his idea was a great one. When civilisa-
tion is in danger and society in transition might there not be a
House recruited from the best intellects in the country with
functions similar (mutatis mutandis) to those of Bacon’s fancy? A
House devoid of politics, concerned rather with synthesising
existing knowledge, with a sustained appraisement of the progress
of knowledge, and continuous concern with its bearing upon social
readjustments. It is not to be pictured as composed of scientific
authorities alone. It would be rather an intellectual exchange
where thought would go ahead of immediate problems. I believe,
perhaps foolishly, that given time I might convince you that the
functions of such a House, in such days as ours, might well be real.
Here I must leave them to your fancy, well aware that in the minds
of many I may by this bare suggestion lose all reputation as a realist !

I will now hasten to my final words. Most of us have had a
tendency in the past to fear the gift of leisure to the majority. To
believe that it may be a great social benefit requires some mental
adjustment, and a belief in the educability of the average man or
woman.

But if the political aspirations of the nations should grow sane,
and the artificial economic problems of the world be solved, the
combined and assured gifts of health, plenty, and leisure may prove
to be the final justification of applied science. In a community
advantaged by these each individual will be free to develop his own
innate powers, and, becoming more of an individual, will be less
moved by those herd instincts which are always the major danger
to the world.

You may feel that throughout this address I have dwelt exclusively
on the material benefits of science to the neglect of its cultural value.
I would like to correct this in a single closing sentence. I believe
that for those who cultivate it in a right and humble spirit, Science
is one of the Humanities ; no less.

SECTION A.—_MATHEMATICAL AND PHYSICAL SCIENCES,

SEASONAL WEATHER AND ITS
PREDICTION

ADDRESS BY
PROF, SIR GILBERT -T. WALKER, C.S.I., FR.S.,
PRESIDENT OF THE SECTION.

I nave chosen the subject of seasonal weather for my address, because
its economic importance is obvious to most men who have lived in the
Tropics, and its scientific problems are full of interest. Unfortunately
there is an additional motive, the need of warning against dangers ahead.
For the difficulties of long-range forecasting are not in general adequately
recognised, so that some of the most progressive countries in the world
are inclined to make predictions on an insecure basis ; their technical
staff does not realise that though the prestige of meteorology may be
raised for a few years by the issue of seasonal forecasts, the harm done
to the science will inevitably outweigh the good if the prophecies are
found unreliable. We only learn from experience that while the fore-
casting efforts of a charlatan are judged by their occasional successes, it
is the occasional failures of a government department which are remem-
bered against it.

In a country where conditions are as changeable from day to day as
they are here, it is natural that we should think in terms of wet or fine
days rather than of wet or dry periods ; but in the greater part of our
empire the different seasons are much more sharply defined, and so
their dominant features stand out more clearly. Also the variability of
their seasons is in general materially greater than here. Thus in the
annual rainfall measurements of the last half-century the smallest rainfall
of Great Britain has been 23 per cent. below normal ; but that of large
areas in South Africa has been in defect by 40 per cent., in north-east
Australia by 50 per cent., and in the Punjab by as much as 58 per cent.,
or two and a half times that of this country.

Now a season that is unusual seems to have some abnormal factor
permanently at work diverting the weather from its ordinary course ;
in India I found, when issuing the daily forecast in a dry winter, that I had
at times to predict no rain, when with identical conditions as shown by
the weather map I should in a wet winter have predicted a widespread
fall. Even in England, in winter, there is an appreciable persistence
in the characteristics: during the last sixty years the fifteen wettest
Januaries were followed by Februaries of more than average rainfall in

26 SECTIONAL ADDRESSES

ten cases; and with dry Januaries also there is a similar two-to-one
chance of a prolongation of the character. It is this persistence, especially
when it is preceded by abnormal features in other regions, that seems
now to hold out most promise of reliability in forecasting. In agricultural
countries in which a failure of the rains involves a national calamity, the
desirability of making preparations in advance has long ago led to efforts
at prediction ; and the demand has been so great that the supply has
been forthcoming before its quality would bear the most cursory
examination. The causes of unusual weather seem hopelessly obscure
to the layman ; and hence primitive ideas, surviving in the depth of our
natures from countless ages of magical practices, still come to the
surface in connection with it. In India I have been officially asked
what is the need of an expensive and difficult scientific inquiry into the
causes of drought when Hindu astrology will indicate what is coming ;
and many a country that claims to be dominated by Western science fails
to recognise that events in weather obey the ordinary laws of physics and
chemistry. The almost universal idea that weather must repeat itself
after a certain number of years finds its origin, I believe, ultimately in
the ancient belief in the control of our affairs by the heavenly bodies
with their definite cycles—a belief which clearly shows itself in the
supposed influence of the moon on the weather. Be that as it may, the
faith in periods is so deep-seated that even in scientific discussions the
ordinary tests for validity are very often ignored : more than once I have
seen in journals of repute the artless remark of an author that if he were
to limit his results to those which would satisfy the criteria of reality
he would obtain few results of interest !

Another regrettable feature of current practice, even in important
memoirs, is that of classing together processes with true periods and
those sometimes called ‘quasi-periodic,’ of which the period varies.
If our ideas are to be applied with success in the present enterprise
their currency must be stabilised, and no good can come of attempting
to pass off a vague surge of a few years as a three-year period.

After these preliminary remarks I propose to make a rapid sketch
of the relationships that have been found between seasonal features in
different parts of the world, then to describe the efforts that have actually
been made to issue long-range forecasts, and finally to consider the
directions from which improvements can be hoped for.

In the collection of World Weather Records, of which the publication
was made possible by American generosity six years ago, there are about
a thousand series of monthly data of pressure, temperature and rainfall ;
and these form but a scanty network. If quarterly values were com-
puted and correlation coefficients between each pair for contemporary
seasons, as well as for seasons one quarter before and after, we should
have about four million coefficients. Co-ordination and generalisation
are imperatively called for, and the development of the subject lies in the
discovery of regions over which the variations are linked together.

After preliminary efforts by Buchan, Hoffmeyer, Blanford, de Bort,
Hann, Meinardus and Pettersson, the far-reaching possibilities were
first visualised by Hildebrandsson, who plotted pressure curves for ten

A—MATHEMATICAL AND PHYSICAL SCIENCES 27

years of sixty-eight stations scattered over the world and drew attention
to the relations between them: among these the opposition between
Sydney in Australia and Buenos Aires was fated to have great influence :
his subsequent studies involved temperature and rainfall also. In 1902
the Lockyers confirmed the existence of the see-saw between pressure
in the Argentine and in India or Australia ; and using graphical methods
produced a world map, dividing areas in it according as their pressures
varied with India or South America. ‘They were followed by Bigelow’s
study of relationships with solar prominences. During recent years
considerable development has followed the introduction of statistical
methods, particularly in the hands of Exner, and of members of the
meteorological services of England and India.

It will be convenient if I may here introduce a technical phrase. If
we have two series of numbers of which the variations are connected,
there will be a certain proportion of the variations of each which are
associated with those of the other, and this proportion is called the
correlation coefficient between the series. If it is nearly unity the numbers
vary closely together ; if it is small there is little relationship between
them ; and if it approaches —1 the relationship is close, but one series
goes up when the other goes down.

Let us now consider some of the results of the analysis of seasonal
features. It has long been known that in the North Atlantic Ocean there
are two types of winter. In one pressure is high near the Azores and
south-west Europe, and low in Iceland, while temperatures are high in
north-west Europe; in the other type all these features are reversed.
(See the three upper graphs in Fig. 1.) Let us suppose that we want
to know the effect of these types on, say, temperature in Labrador.
An obvious plan would be to plot the variations in successive winters,
December to February, of the quantities which increase together, such
as Vienna pressure and Stornoway temperature, and also of the quantities
which decrease when the former increase, such as Iceland pressure,
reversing these so as to secure similarity of the graphs. We could then
draw a graph which is the mean of all these, and could regard it as
expressing the variations of the North Atlantic fluctuation as a whole.
(See the lowest graph of Fig 1.) If now we were to plot Labrador tem-
perature below it we should see that its variations were, like those of
Iceland pressure, strongly opposed: and on reversing Labrador there
would be very strong similarity. So Labrador becomes a good example
of the second group. Now we want to know the effect of the North
Atlantic oscillation on the pressure temperatures and rainfall of a large
number of places ; and if in this way we put a hundred graphs under one
another, some easy to classify and some doubtful in character, it would
be difficult to draw satisfactory conclusions in a manner capable of
convenient and accurate expression. So instead of graphs we use
numbers. Having found by preliminary investigation the stations which
are most representative, we calculate the figures in successive years for
the North Atlantic oscillation as a whole, and then work out the correlation
coefficients of this with the pressures, temperatures and rainfalls of all
the places in which we are interested. These coefficients are plotted

28 SECTIONAL ADDRESSES

in Fig. 2, and in its top chart we see that the rise of pressure with a
positive fluctuation is greater as far east as Vienna and as far west as the
Bermudas than it is at the Azores. ‘There is also to be seen in the second
chart conspicuous warmth in the east of the United States as well as in
north-west Europe, and marked cold to the south-east of the Mediterranean
as well as along the north-east of North America. On rainfall, in the
lowest chart, the influence is less widespread. ‘The small amount of
persistency is shown in Fig. 3. The first of its three graphs shows how

VIENNA PRESS. DEC.~ FEB,

ELANO PRESS. DEC -FEB
REVERSED

5 80 185 go 95 oo} 05 Pbrot rt rita torts 125) 1 1130

Fic. 1.—N. Atlantic Oscillation.

close are the relationships of pressure in December with the figures
expressing the fluctuations of the North Atlantic in that month ; the
second and third, which give the relationships of pressure and temperature
in January with the fluctuations of the oscillation of the December before,
show that little effect of the December conditions survives after a month.

The more critical in my audience may object that if you are sufficiently
astute in choosing your successive numbers for the fluctuation you can
make a certain amount of agreement with any system of pressures and
temperatures ; and to this the reply is that the fit is very much closer
than can be explained in this way. Others may urge that all these
arguments are merely numerical, and quote the jibe that by statistics
you can prove anything. But if you wish to understand phenomena
you must collect the facts, and if they are numerical it is only in the

ad ae CONE ae

et ce bios

HTN bia eS Tp
SHERS SaCSCaReee
Perret ira

Seg UV IEr cause

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eae

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mY

Pans
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Sth
(eS pared a ae MN

Fic. 2.—Relations of N. Atlantic oscillation with area pressure, tem-
perature and rainfall of December to February. Numbers based on series
shorter than 30 years are in brackets ; those for areas are in circles.

SECTIONAL ADDRESSES

[>

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ao

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2, / : .
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Fic. 3.—Relations with the N. Atlantic oscillation of December.

~~

A.—_MATHEMATICAL AND PHYSICAL SCIENCES 31

very simplest of cases that you can see relationships by merely plotting
curves and comparing them. Statistical methods are inevitably forced
on us by common sense when we want accurate and reliable inferences
from series of data, just as a sextant is forced on a sailor when he wants
to determine accurately the altitude of the sun. One who has lost an
important lawsuit, owing to the ingenious argument of the opposing
counsel, may object that by logic you can prove anything ; but that is
an inadequate defence for being illogical on all occasions. As a matter
of fact, when studying relations of cause and effect statistical methods

eee Bete cS Se ee Oo cS gS Se cel) OO Se | Ss
® 8 $ 8 8 &® @ ® © § 8 S$ 8 S$ 8 8 8 8 B &

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i) i) '

Fic. 4.—Illiteracy and unemployment.

show us what quantities vary together, but strictly by themselves they
tell us nothing as to causation. If we compare heights of fathers and
sons, we learn that tall sons have tall fathers ; but in spite of that fact
We are not convinced that the child is literally father to the man.

Let us consider an example from data published in 1906 regarding
‘unemployment and illiteracy as measured by the percentage of persons
who could not sign their name in the marriage register (Fig. 4). Clearly
the correlation coefficient between these two factors might lead to most
undesirable inferences regarding the usefulness of education. But we
could not expect to arrive at the truth if we ignored such an important
fact as the amount of trade, and on admitting the data of this factor we
See at once that faith in the value of our elementary schools need not be
‘uprooted ; for the revival of prosperity produced marriage, especially
among those in a humble position who could not write, as well as a

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eS a
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Fic. 5.—Relations of N. Pacific oscillation with contemporary pressure,
: emperature and rainfall.

A—MATHEMATICAL AND PHYSICAL SCIENCES 33

zat

Fa
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Bos

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Fic. 6.—Relations of Southern Oscillation of December to February with con-
temporary pressure, temperature and rainfall.
Cc

34 SECTIONAL ADDRESSES

}

i ee
| f
| a

NE Eee a ao
aL aA es

(ECTION. (3 SS ee =e

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a Mr hata

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By enees cy CB
eee pa
“peble [ae Tae a

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aS CSE EDSRUEECEE

hee Ag ee at
: eae

ie
La
5)

Fic. 7.—Relations of Southern Oscillation of June to August with contemporary
pressure, temperature and rainfall.

A.—MATHEMATICAL AND PHYSICAL SCIENCES 35

decrease in unemployment ; so that the last two factors varied similarly.
We see, then, that we may be misled if we do not take into account all the
factors that may be operative. In other words, statistical methods like
logarithm tables are invaluable as a tool for giving correct numerical
results with the minimum of mental labour ; but neither tool possesses
imagination or judgment, and neither of them is a substitute for expert
knowledge of the subject to which it is applied.

Let us now turn to the North Pacific Ocean which, in spite of its
limited access to the Arctic seas, is subject to fluctuations very similar
to those of the North Atlantic. A similar treatment yields Fig. 5, in
which increased pressure gradients go with high temperature to the
north-east and south-west, and low temperature to the north-west and
south-east. It will be noted that in both the North Atlantic and Pacific

1880-( 1890- 91 1910-11 1930-31

FOLLOYVING
SUMMER,

THE SOUTHERN OSCILLATION.

Fic. 8.—Forecast of December to February from previous June to August.

Oceans a fluctuation is classed as positive when the pressure gradient
is strong and the wind circulation is active.

The largest known system of related seasonal weather is that called
the ‘ southern oscillation ’ (or ‘ southern fluctuation ’), which has features
in the southern summer of December to February somewhat different
_ from those of the southern winter of June to August. It will be seen

in Figs. 6 and 7 that at both times of the year the fluctuation is called
positive when pressure is high in the southern Pacific and low in the
‘Indian Ocean, and temperature is mostly low in the Tropics ; but. the
economic importance is in connection with rainfall, for the fluctuation
has a correlation coefficient of over 0-8 with the summer rainfall of north-
east Australia, over 0-7 with the monsoon rainfall of India and with the
Nile floods, 0:6 with the rainfall of large areas in South America, and
over 0°5 with that of a region in South Africa.

A surprising fact comes out on comparing the numerical series giving
the characteristics of the summer and winter values of this fluctuation,
the control of the southern winter on the succeeding summer being
expressed by a coefficient of 0-82, the corresponding data being plotted
together in Fig. 8; but the relationship with the previous summer is

Be a
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I }
, |
NaS || a]
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i

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Y

BS

t:\

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AI oy

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oscillation of previous J—A.

A.—_MATHEMATICAL AND PHYSICAL SCIENCES 37

only 0:2. The immediate effect of this is that numerical values of the
winter oscillation give us a means of predicting three months in advance,
at any rate approximately, the summer values of the oscillation and
therefore of the pressure, temperature and rainfall associated with them.
In Fig. 9 are the relationships of the values of the pressure, temperature
and rainfall of December to February, with the numbers indicating the
fluctuation of the previous June to August. These express relationships
which have held for about fifty years, and show that we have arrived,
not at a mathematical figment, but at a physical reality of commercial
value.

These methods of prediction can be improved on by study of the
relationships of individual areas. For example, the coefficient of 0°64
of rainfall of north-east Australia with the oscillation of the previous
winter becomes 0-79, when we base it on previous pressure at Honolulu,

1900 ‘Oo ‘25 ‘30

2 vaca ANN PS

STEN neers oe

ae ee ARE

Fic. 10.—N.E. Australian rainfall, October to April.

Port Darwin and South America ; a comparison of the actual rainfall with
that given by the formula isshownin Fig.10. Similarly, theo-56 of South
Africa becomeso:72. Butacertain amount of the improvement effected in
this way by selecting the biggest factors is bound to be fictitious, even
when there appear to be adequate independent reasons for thinking that
the relationships are real ; and, if this precaution is ignored, the more
promising the formula, as indicated by the closeness of its apparent
relationship, the greater is the likelihood of disappointment.

It must be admitted that a real control of 0-7 by previous conditions
is about as good as is now available for forecasting, and the difference
between the actual and the forecasted amounts will still be considerable ;
so predictions can only be issued with restraint if public confidence is
to be won. The natural consequence is silence, except when the
indications are markedly favourable or unfavourable: in a race with
thirty starters a conspicuously good horse may, without undue risk, be
backed to come in within the foremost six, and we may feel confident
that a thoroughly bad animal will be in the last six; but it would be
unwise to hazard much on the likelihood that a commonplace individual
will finish among the central six. It may at first sight seem a confession

38 SECTIONAL ADDRESSES

of weakness to issue no forecast when conditions appear roughly normal ;
but it is better to admit your limitations, and only speak when you can
do so with some safety, than to issue predictions when they are little
more than guesses.

The objection is sometimes raised that though a foreshadowing
of abundant or scanty rain over a region may be right four times out of
five, owing to local variations the predictions will not be so successful
when applied to a particular farm ; and it must be admitted that this
criticism is valid. But in England, as I learn from Sir John Russell,
there are modifications of treatment and manuring that are appropriate
before wet seasons and others before dry ; in South Africa, in hilly country,
the upper levels are better for cultivation in wet years and the lower
ones in dry years; in India, if the rains fail, cotton and millets will
grow though the ordinary crops may perish. We may hope that,
when our methods have improved, the prediction when applied to a
particular farm will be right at least three times in five years; and if
this is consistently acted upon, it will prove of material value in the
long run.

Of further applications of these methods some are worthy of a passing
notice. For Siam, whose summer rain has a coefficient of 0-7 with the
contemporary southern oscillation, a former Indian colleague has worked
out a foreshadowing formula with a relationship of 0-8. And at length
China, which has suffered terribly from floods as well as droughts, is
receiving attention. A graduate from Shanghai, now working in London,
finds that the Yangtse valley and three areas along the coast have enough
data for a preliminary investigation, and has worked out formule for
prediction with coefficients between 0:6 and 0-7. Mention should also
be made of the researches of Okada in connection with the rice crop
of Japan.

Let us now turn from the academic to the practical, and see how far
these theoretical methods justify themselves in actual experience. I
believe that the earliest regular seasonal forecasts based on meteorological
instead of astrological data were those of the Indian monsoon of June
to September, started half a century ago in India by H. F. Blanford,
and depending mainly for their success on the ill-effect upon the monsoon
of excessive winter or spring snowfall in the Himalayas ; finally, however,
he made the big generalisation that droughts might be associated with
unusually high pressure over a great part of Asia, at Mauritius and in
Australia. Eliot continued the monsoon forecasts from 1887 to 1903,
but data in those days were scanty ; he attempted far too much detail,
his mode of expression was somewhat pontifical, and the newspapers
became sarcastic ; so latterly he obtained immunity from criticism by
printing the forecasts as confidential documents. The gradual intro-
duction of statistical methods in India has undoubtedly led to improve-
ment; but as we have seen it is much easier to predict the rainfall of
December to February than that of June to September, and the length
of the series of Indian data is not yet great enough to give complete
reliability. After careful scrutiny I estimate that of the forecasts issued
before the monsoon periods from 1905 to 1932 two-thirds were correct ;

A.—MATHEMATICAL AND PHYSICAL SCIENCES 39

but I consider that this is not good enough and that we have been too
ambitious. Also while the approximate prediction formula of 1908 has
stood the test of time with credit, the later ones of 1924 for north-west
India and the Peninsula separately, although certainly better in theory,
have not, in the short period of trial, proved so successful. The contrast
between the working of the formule before and after their date of
preparation will be seen in Fig. rr.

Happily in Southern Rhodesia, which in 1922 adopted statistical
methods similar to those of India with only twenty-four years of data to
work upon, the results have been eminently satisfactory. Out of eleven

1924 FORMULAE
eee oOavawa—wmyua=s=—'

a
PENINSULA sune-Serr. ‘Limit’ = -g42Vi-eo = 3-48 \
CALCULATED [|

s* Ny pm Ni ai
JL WSVAVANIEL ATIVAN
AGAR AMITNMTAVU AIA NGHINA

ACTUA
Peis

N.W.INDIA_ sune-Sepr. ‘Limit’= 3h.
PERT

CALCULATED

5: pe | IN | ! e

os ASEAN NECA TAY SAVIN NAL ADS
SNAIL TEDL AVALT TT
ae INV AVI

VV,

1875

Fig. 11.—Calculated and actual Indian rainfall.

years since publication was begun, there have been eight in which a
departure of over 3 in. was given by the formula, and in seven of these
the character was correctly indicated (Fig. 12).

At Batavia the efficient Dutch observatory under Braak started in
1909 to issue forecasts founded on the simple rule that low pressure
from January to June was followed by abundance of rain from July to
December. The rule demanded a more complete presistence of pressure
than actually prevails, and in 1927 Berlage adopted a formula based on
three local conditions, together with data of the rare rains of northern
Peru: this gives, on paper, a relationship of over 0°8.

In Australia calamitous failures in the rains have long demanded
forecasts, and these led to the production of weather cycles, which broke
_ down so frequently that their use was discarded. In spite of this
experience, however, Hunt, the Commonwealth Meteorologist, put

40 SECTIONAL ADDRESSES

forward in 1929 a theory of a four-year period, based on the cooling
effect of the widespread growth of luxuriant vegetation produced by the
rainfall in areas that were parched. I believe that the theory has not
been adopted officially.

When we turn from the tropical and subtropical to the temperate
regions, where the persistence of conditions is in general conspicuously

1922/3 23/4 24/5 25/6 2b/7 27/8 28/9 2/30 30f1 31 32/3

poser

ACTUAL

S. RHODESIA RAINFALL, OCT~APR.

Fic. 12.

smaller, we must expect greater difficulties in making long-range forecasts.
In America the relations of weather and crops have probably been worked
out more scientifically than in any other country, so that the commercial
value of reliable predicting has long been recognised ; and not only by
farmers, but by those interested in water supply, in power schemes,
in transport and in commerce generally. Thus one of the Californian
hydro-electric companies makes its own forecasts, because it may spend
four million dollars more for crude oil in a dry than in a wet year. Ina
country of exuberant vitality it is not surprising that many efforts should

A—MATHEMATICAL AND PHYSICAL SCIENCES 41

have been made to provide for the general demand. In an article in
1927, by C. F. Brooks, we read that in the absence of forecasts ‘ western
farmers have paid a “ rainmaker ” thousands of dollars at a time ’ actually
to produce rain ; that during the previous ten years ‘ well over fifty long-
rangers of greater or lesser repute have been publishing and, in a great
many cases, accepting money for worthless or damaging forecasts.’ As
in Europe, they have predictions based on occurrences on critical days,
such as Candlemas or St. Swithin’s, as well as on the doings of animals
and birds. Thus Brooks quotes from an almanac of 1870: ‘ When
you see 13 geese walking injun file and toeing in you can deliberately
bet yure last surviving dollar on a hard winter, and grate fluktuousness
during the next seazon in the price of cowhide boots.’

Undeterred by the difficulties, G. F. McEwen, of the Scripps Institution

A

NEW F OUN DLAND }CEBERGS. MARCH —-TULY. |,

PUM ALIV TEV UELIVTTETHAQVTU

N

Fic. 13.—Atlantic Icebergs and the previous oscillation.

of Oceanography in California, has for some time been forecasting rainfall
by empirical methods, and at first attained considerable success, largely
on the basis of a short series of ocean temperatures. These, however,
as he has recognised, have not of late made good their early promise ;
and he is driven to using sunspot numbers, a cycle of five or six
years, and a complex method of smoothing in the hope of attaining
reliability.

A less difficult task confronts the International Ice Patrol Service of

the United States in their desire to obtain advance information of the

amount of Arctic ice drifting into the western North Atlantic. I do not
know what progress has been made, but the dependence on the previous
North Atlantic oscillation, with which there is a coefficient of 0:60, would
appear to suggest a useful starting-point (Fig. 13).

In Europe the only seasonal forecasts known to me that have a scientific
foundation, and have been made for anumber of years, are those of Sweden
and Russia. In Sweden Wallén has for eighteen years made predictions
for rainfall and for the height of water. Regarding rainfall, he smoothes
by taking the sums of consecutive twelve months ; and then, assuming

C2

42 SECTIONAL ADDRESSES

that the nature of the fluctuation so disclosed will not change suddenly,
he forecasts that the total rainfall of some definite period, usually six
months or a year, will be greater, or less, than it was in the previous year.
Now a moment’s thought will make it clear that a man will in the long
run be right three times out of four if, when last year’s rain was in defect,
he predicts an increase, or if it was in excess he forecasts a diminution.
So I think it is not unfair to say that success under the Swedish condi-
tions begins at 75 percent. The success actually attained is 82 per cent.,
which is encouraging; and the success in dealing with water levels
is phenomenally great, being slightly over go per cent.

The seasonal conditions of Russia, which are not very closely related
with those of the North Atlantic, have been carefully examined by W. Wiese.
In 1923 the Hydrometeorological Office of Leningrad started publishing
forecasts of ice in the Barents Sea, and out of seventeen monthly fore-
casts of which I have information fifteen were approximately correct.
Predictions of the rainfall of April and May in central and east Russia
were initiated at the same time, and all the first four years they were
approximately correct: the biggest difference between the actual and fore-
casted amounts was only 20 per cent.

No account of European activity in this department could ignore the
enterprise of Prussia four years ago in creating at Frankfurt a.M. a post
for research into long-period forecasting. Dr. Franz Baur has for the
present wisely limited his activity to the issue of a forecast of ten days ;
it would be impossible to expect results under these conditions
which are as accurate as those of daily weather work, but I am in-
formed that their standard fully demonstrates the trustworthiness of
the principles employed. It is only by experiments of this kind that
satisfactory methods of prediction can be developed.

We may now pass to the consideration of improvements in our methods,
and the fundamental question at once arises—what is the physical cause
of seasonal fluctuations ? We should naturally look for it in variations in
the energy received from the sun, and it is surprising that an increase
in solar activity as measured by sunspots produces a slight decrease in the
circulations in the North Atlantic and the North Pacific. In the southern
fluctuation the tendency of numerous spots is to produce positive values,
but even there the biggest seasonal correlation coefficient is only 0-26,
which is much too small to provide the explanation that we seek.
Moreover, it probably arises because a positive fluctuation is associated
with low temperatures between latitudes 40° N. and 40° S.; and these
are linked with an increase in sunspots.

In order to verify that the daily pressures are not produced by short-
lived emanations from the sun tabulations of the relationships between
daily and weekly, as well as the monthly and seasonal, values at distant
places have been made ; for if the daily values over the earth are controlled
from outside there will be close parallelism between these daily and
weekly pressures. It was found that between 31 daily contemporary
pressures at Honolulu and Batavia the coefficient was — 0-12, which is
negligible ; between 39 weekly ones it was +-0-10, between 47 monthly
June pressures it was — 0-12, and between the pressures of 47 three-

A.—MATHEMATICAL AND PHYSICAL SCIENCES 43

monthly seasons of June to August it was —0-46. Between Samoa and
Batavia December pressures the coefficient was —o0-38, and for the
season December to February it was —o-60. ‘Thus it is between the
characteristics that persist over months, not over days or weeks, that
relationships exist.

Being forced off short-lived phenomena we search for an explanation
in terms of slowly changing features, such as ocean temperatures ; and
the big variations from year to year in the amount of pack ice in the
antarctic seas forces itself on our attention. But here the reports of
twelve years from the South Orkneys yield a relationship of only 0-32
with the southern fluctuation, instead of about 0-9, as we should want in
a prime cause ; and the variations at the South Orkneys come after rather
than before those of the southern oscillation. The biggest ocean region
is the Pacific, and as an index of its seasonal water temperature we
may use the corresponding air temperature of Samoa, which shows a
greater persistence than any factor in the world as yet examined ; the
relationship between its summer and autumn values is as large as 0-94.
But unluckily the correlation coefficients show clearly that it is mainly
the southern fluctuation in winter that controls the Samoa temperature.
Thus a short-cut to the explanation of our fundamental problems seems
as far away as ever. Our three big fluctuations each form a system of

_ changes which are apparently held together by meteorological links :
and there is, in my opinion, as yet no satisfactory proof of any free periods
associated with them.

Let us now consider in what direction new developments seem likely.
A moment’s reflection will convince us that in view of the variations of
rainfall over large areas, such as Brazil and Central Africa, which are
scarcely affected by the three big fluctuations, there must be others,
some of which are probably on a big scale. For example we should, on
the analogy of the northern oceans, expect a fluctuation of pressure

_ between the antarctic low pressure belt and the high pressure belt of
—30°S. Weare at once reminded of the marked opposition which Simpson
_ found during the short period of four years for which data were available
_ between pressure at McMurdo Sound and that in a belt round the earth
_ extending from about 25° S. to about 50°S. All students of this subject
have found it natural to regard the fluctuations in the amount of pack
_ ice in the antarctic seas as likely to control sea and therefore air tempera-
tures over large regions, and the most southern station from which as
_ Many as twenty-five years of data are forthcoming is the South Orkneys.
_ Its winter pressure does show the opposition that we should expect with
that of Australia, but not with the high-pressure region of South America
, gh-p §
or Mauritius ; so that it gives little support to the view that there is a
general pressure oscillation between the low and the high pressure belts
of the southern hemisphere. On the other hand, the air temperature at
the South Orkneys may be regarded as an index of the sea temperature :
and as the ocean current through the Drake Passage would take about a
year to reach South Africa, we are not astonished at the relationship of
0°56 between the South Orkneys air temperature in winter and that of the
next winter at Cape Town. ‘This is not, however, as close as the corre-

44 SECTIONAL ADDRESSES

sponding relationship of 0-84 shown in Fig. 14 between the winter tem-
perature at New Year Island at the extreme south-east of South America,
and that at Cape Town a year later. The far greater influence of New
Year Island is interesting, since between Cape Horn and the South
Orkneys there runs E.N.E.a line which the recent Discovery expedition
calls the Antarctic Convergence ; here the cold antarctic water meets the
northern warmer water and dives under it. So while the current flowing
past New Year Island can after a year approach South Africa that from
the South Orkneys is cut off by a barrier.

If I may summarise these remarks, I would say that although seasonal
foreshadowing is still very imperfect it has come to stay ; for situations
will arise from time to time, as they did in India in 1905, in which it

1900 1905 1910 1915 1920 1925

+PC

“PC

Fic. 14.—Departures from normal of Ano Nuevo temperature, June to August,
and of Cape Town temperature, June to August, of following year.

can be foreseen with practical certainty that rains will fail and a warning
will then be of great value. But those who prepare formule by the
selection, based merely on the closeness of their apparent relationship,
of a few out of many factors must remember that they cannot expect the
value of all these factors to be maintained; and if they have a fore-
casting formula which on paper works out with a coefficient of, say, 0°75,
they must realise that this is in reality probably not more than 0-6, or
in some cases even 0-4. And I would plead for a much severer standard
in handling questions of periodicity. If these views are right, no
anticipations should be published except on the strongest evidence of
excess or defect until the experience of fifteen or twenty years has justified
a less cautious policy. i

Finally I would express the hope that the subject may, by its potential
value to the race, and by the many-sided nature of its interests, enlist the
services of some of my hearers who are qualified to unravel some of ‘its
intricacies.

SECTION B—CHEMISTRY.

NATURAL COLOURING MATTERS
AND THEIR ANALOGUES

ADDRESS BY
PROF. ROBERT ROBINSON, F.R:S.
PRESIDENT OF THE SECTION.

On taking the Chair of this Section I should like to express my thanks
for the great honour which you and the Council of the British Association
have conferred on me.

Although the subject which I have selected for my address is necessarily
somewhat technical, it occurred to me that the problem of flower colour
is of general interest, and the gist of what I have to say is a contribution
to the answer to the question: why are some flowers blue and others,
containing the same pigment, ved? In the interests, too, of members of
this audience who are not organic chemists I propose to allow the spoken
to diverge from the written word, and I shall venture also to attempt the
performance of a few simple experiments.

In every country and throughout the ages emotions have been stirred
and curiosity aroused by the display of colour in Nature, but it is perhaps
not generally realised that the ready availability of artificial colouring
matters suitable for every kind of tinctorial purpose, from boot polish
to finger nails, is a comparatively recent development. We read of the
ancient Tyrian purple, the purple of kings, and of the red cosmetic pig-
ments of natives of the Orinoco, so rare that they were used as the basis
of exchange ; in contrast, at the present time dyes of all shades may be
indulged in to an extent controlled certainly by individual courage, taste and
discretion, but hardly at all by limitations of purse or social status. It may
be that this ‘ freedom of the hues ’ has been enjoyed for so brief a period
that a state of equilibrium has not yet been reached and we are not using our
privileges in this matter either as fully as possible or as wisely as possible.

It is not, however, for an organic chemist to discuss such problems as
that of masculine sartorial conservatism on the one hand, or to attempt an
estimate of the esthetic value of the film-fan magazine cover on the other.

The chemist has been attracted to the investigation of natural and
artificial colouring matters for a variety of reasons, including not only
colour-pleasure, the incentive of the knowledge that chlorophyll and
hemoglobin perform some of the most important functions in vital pro-
cesses, and the industrial importance of dyestuffs and pigments, but also
on account of the fact that visible colour more than any other property
facilitates the experimental study of organic substances whether by
analysis or synthesis. It furnishes a standard of homogeneity or a measure
of concentration, it is an invaluable guide in the search for methods of

46 SECTIONAL ADDRESSES

separation and purification, and it at once indicates, by its appearance or
disappearance, the occurrence of a chemical reaction. Small wonder
that the successful outcome of the investigation of many colourless sub-
stances has awaited the discovery of some characteristic colour-reaction ;
a noteworthy example being Vitamin A. Odour is a more specific
property than colour as judged by the eye, and in a more limited field it
has proved equally useful to chemists who prefer to follow their noses.
However, we cannot yet resolve odours in a spectrum.

Thus the pursuit of a fascinating object has been along a path of
relatively low resistance and the pioneers have been richly rewarded.

Like a list of best books, a catalogue of outstanding achievements
invites destructive criticism. I do not fear this, however, in recalling
the researches of Laurent, Kekulé, Baeyer and Heumann on indigo ; of
Sir William Perkin, Hofmann, Otto and Emil Fischer, Meldola and many
others on the basic dyes ; of Griess and his host of followers on the azo-
compounds ; of Arthur Perkin and of Kostanecki on the flavones and
flavonols ; of Willstatter on the respiratory pigments and the antho-
cyanins ; and, not least, of Hans Fischer on the synthesis of the prosthetic
group of the blood pigment.

No attempt can be made to cover this vast field, but the mere mention
of these topics serves to prove the immense theoretical and practical value
of a study of organic colouring matters. ‘The work proceeds and a long
chapter on the natural carotinoid pigments is even now being written by
Karrer, Kuhn and others ; it is of great chemical and biological interest.

Before dealing with the special group of the anthocyanins, some aspects
of which have recently been studied at Oxford, attention may be directed
to the analogies in constitution existing between natural colouring matters
and artificial dyestuffs.

As the result of the researches of Baeyer, indigotin is generally regarded
as having the formula I, but a technical digression may be made to the
effect that the formula II has not yet been completely disproved.

vA JNEY_/CO
Ges: & ae va | :
7 Rg icin. C
~ me \Y/ Ng aaa
(I) (11)

The oxidation of indoxyl to indigotin appears to favour I, but then
Gabriel has shown that the oxidation of diketohydrindene (III) by means
of alkaline persulphate furnishes dihydroxynaphthacenequinone (IV).

OH

JV SO O Sere

2 CH: a
(III) (IV)

B.—CHEMISTRY 47

All the indigotin syntheses can give II just as well as I, and II can yield
isatin on oxidation. ‘The recent researches of E. Hope prove that some
of the products of the action of benzoyl chloride on indigotin possess the
skeleton of II, but of course this may arise from an intramolecular
rearrangement. The chief argument against II is derived from a con-
sideration of the numerous classes of indigoid dyestuffs which are easily
formulated on the model of I.

The industrial analogues of indigo are its substituted derivatives, the
thioindigos (e.g. V) and similar indigoid dyes, and indanthrone (VI).
The first-mentioned classes were made in imitation of the indigotin

(V) (VI)

structure, but in the case of indanthrone flattery was unconscious.
Both indigotin, and indanthrone contain the chromophoric quinone
group —CO—C = C—CO— and closely situated auxochromic —NH—
groups.

Graebe and Liebermann’s recognition of the constitution of alizarin
(madder) (VII) led, as in the case of indigo, to the industrial synthesis of
the colouring matter itself and of numerous derivatives and analogues.

ave OH Ai pa ?
ON “
Bm pon Ole
CO
(VI) (VHT)

At the present time we recognise in retrospect that the most important
outcome of the work on madder was the attention focussed on the study:
of anthraquinone and its derivatives. It may seem a far cry from the
adjective natural dyestuff to the modern vat dyestuff Caledon Jade
Green (VIII), but the descent is in the direct line—alizarin, Alizarin
Blue, benzanthrone, dibenzanthrone, Jade Green. Technical analogues
of the anthocyanidins are to be found in the phthaleins, pyronines and
rhodamines, and some more or less close dyestuff analogy can be found to
correspond with most of the series of natural colouring matters.

48 SECTIONAL ADDRESSES

The most recent, and certainly one of the most interesting, examples of
this kind is found in the phthalocyanines which contain a porphyrazine
structure, that is the porphin skeleton of the natural porphyrins in
which some —CH= groups are replaced by —N=. Dr. Linstead will
shortly give an account of his investigations of these substances and of
their remarkable properties.

It was primarily with cognisance of Dr. Linstead’s work that I ventured
to direct your attention to analogues of natural colouring matters ; this is
at the technical end of the scale, and in contrast Professor Kuhn has kindly
consented to describe some novel natural colouring matters of high
biochemical interest.

The following sections of this address deal with developments of the
chemistry of the red, blue and violet colouring matters of flowers and
blossoms.

STRUCTURE AND SYNTHESIS OF THE ANTHOCYANINS.

A brief description of the chemistry of the anthocyanins is necessary at
this stage. ‘The brilliant and pioneering researches of Richard Willstatter
and his co-workers (1914— __) established the main features of the chemistry
of the anthocyanins which were recognised as saccharides, occasionally
acylated, of the anthocyanidins. They exhibit amphoteric character,
forming salts with both acids and bases. Thus the violet pigment cyanin,
which can be isolated from blue cornflowers, red roses, deep red dahlias
and other flowers, forms a blue sodium salt and a red hydrochloride.
The hydrolysis of the latter by means of hot aqueous hydrochloric acid
into cyanidin chloride and glucose is represented by the equation :

Co7H 51046 Cl + 2H,0 = C,5Hy,06Cl + 2C,H,,0,
cyanin chloride cyanidin glucose
chloride

The constitution of cyanidin chloride (X) has been established by analysis
and numerous syntheses ; the first of these (Willstatter and Mallison)
utilised the reduction of quercetin (IX) by means of magnesium in
aqueous methyl alcoholic hydrochloric acid solution (demonstration).

Cl
4 On\ OH HO Oo. OH
HO
C OH C OH
eT) ee
= (&
Pan NOH H,+HCl 7 NOH +H,0
WARNES 2 6 SCH +H,
(IX) | (X)

In this process a widely distributed anthoxanthin yields a widely
distributed anthocyanidin, and the temptation to assume that similar
reactions occur in the plant laboratory is very great. There is, however,
very little justification for this view and the experimental support brought”
forward in its favour will not survive careful scrutiny. The alleged

B.—CHEMISTRY 49

crystalline anthocyans prepared by the reduction of natural flavones or
plant extracts containing them are nothing but the said flavones with
a small proportion of adsorbed colouring matter of anthocyanidin type.
It seems much more probable that the flavones and anthocyanins are
independently synthesised, although perhaps from a common starting
point. The existence of genetic factors which control the occurrence of
anthoxanthins independent of that of anthocyanins is strong evidence in
favour of this view.

The anthocyanidins which have been isolated are the following :
pelargonidin (XI), cyanidin (XII), peonidin (XIII), delphinidin (XIV),
petunidin (XV), malvidin (XVI) and hirsutidin (XVII), represented as
chlorides. All have been synthesised by unambiguous methods and the
synthetic specimens have been carefully compared and identified with the

Cl Cl OH
a ——s

OH NEO
HO

HO
(XI) (XID)
ice OMe Saran OH
HO tt apa OH HO On < ou
OH OH OH
HO HO
(XIII) (XIV)
om OMe oF, OMe
HO O a Nou HO? 20 —< You
OH | ‘OMe
OH \ 40H
HO HO
(XV) (XVI)
OMe 3
/OH OMe ae: 5
HO 5
(XVII) Numbering Scheme.

_ hatural products. It will be observed that pelargonidin, cyanidin and
_ delphinidin are the fundamental types, peonidin being a methyl ether of
_ cyanidin and petunidin, malvidin and hirsutidin being, respectively, the
_ mono-, di-, and trimethyl ethers of delphinidin.

50 SECTIONAL ADDRESSES

The greater number of the anthocyanins fall into a comparatively
restricted number of categories, including :

(a) the 3-monoglucosides and 3-monogalactosides,

(6) the 3-rhamnoglucosides and other 3-pentoseglycosides,
(c) the 3-biosides,

(d) the 3 : 5-diglucosides, and

(e) the acylated anthocyanins.

It is unnecessary to recount the steps taken in reaching these conclusions,
but they have been finally justified by synthesis in many instances.

In group (a) we find callistephin (XVIII), the monoglucoside of pelar-
gonidin occurring as one of the pigments of the aster and as the main
pigment of scarlet carnations and many other flowers; the related
galactoside, fragarin, is the colouring matter of the strawberry.

In the cyanidin series the corresponding pair is chrysanthemin and
idwin (XIX), the former of wide distribution and the latter occurring
in the skins of cranberries and in the leaves of the copper beech.

Peonidin 3-monoglucoside (XX), termed oxycoccicyanin, is found in
the skins of the larger American cranberries and cenin or malvidin
3-monoglucoside (XXI) is the colouring matter of the skins of purple-
black grapes, as well as of certain cyclamen and primule. The delphi-
nidin representative undoubtedly occurs in bilberries in admixture with
other pigments, and it has not yet been fully examined ; the petunidin
and hirsutidin representatives have not been isolated from natural sources,
although there is reason to believe that the former occurs in the berries
of the Darwin barberry and the latter has been synthesised.

Cl Cl OH

HO 6 | pon coer e

O0-C,H,05 CA /0-CeliniOs
HO

(XVIII) (XIX)
ee OMe — OMe
HOY On. < Son HO on < You
as
OMe
WZ O-C,H,,0; /O-C.H1105
HO HO
(XX) (XXI)

In groups (b) and (c) we find large classes of anthocyanins of which
only a few representatives have been closely studied. These include
keracyanin (cyanidin 3-rhamnoglucoside), probably identical with antir-
rhinin (isolated by Miss R. Scott-Moncrieff), and mecocyanin (XXII),

B.—CHEMISTRY 51

a pigment of red poppies which is now recognised by synthesis as
cyanidin 3-gentiobioside. There is very little doubt that pelargonidin

Beligcric LORE
sGeee
a Aiak geal er Cs ena a
O

O
(XXII)

3-rhamnoglucoside colours the scarlet gloxinia and that pelargonidin
3-biosides are of widespread occurrence, for example, in the ordinary
orange-red nasturtium and in the flowers of the scarlet runner bean.

The anthocyanins of groups (a), (6) and (c), when derived from the same
anthocyanidin, exhibit similar behaviour as indicators. ‘Thus chry-
santhemin, keracyanin and mecocyanin all give a violet solution in aqueous
soda and this becomes blue on the addition of caustic alkali. On partial
hydrolysis mecocyanin and antirrhinin actually yield chrysanthemin.

The anthocyanins of class (d) are the most widely distributed and best-
known members of this series of natural pigments ; they include pelar-
gonin (XXIII), the colouring matter of the scarlet pelargonium and
possibly the first anthocyanin to be obtained in a crystalline condition
(Molisch’s experiment), also cyanin (XXIV), the isolation of which from
the blue cornflower by Willstatter and Everest in 1914 was the first of
an impressive series of investigations.

Cl
——
HO“ AN _ on HONS _< on

| hey oa
O-C,H,,0; ee O-C,H,,0;

C,H,,0,:0 C,H,,0,;°0
(XXIII) (XXIV)

Peonin from the deep red peony and malvin (XXV) from the wild
mallow or from certain primulz, are the peonidin and malvidin repre-
sentatives in this group, which is completed by petunin and hirsutin.
Quite recently the delphinidin member has been isolated from Salvia
patens.

The anthocyanins of group (d) differ from those of groups (a), (6) and
(c) in their alkali-colour-reactions and in their marked instability to
aqueous sodium hydroxide. ‘Thus cyanin, which compares with meco-
cyanin in group (c), gives a pure blue solution in aqueous soda and the
dilute solution becomes very quickly yellow on the addition of sodium
hydroxide (demonstration).

Pelargonin, cyanin, peonin, malvin and hirsutin have been synthesised

52 SECTIONAL ADDRESSES

and an example of the methods adopted may be schematically indicated
in the case of malvin.

MeO MeO

Acog’ coc! CHAN: Aco co-cHN, HCO.H
MeO MeO
MeO FtOH MeO

AcO CO: CHEO-CHO Mn... es Aco¢ CO-CH,OH
MeO MeO

Hy
Bromoacetoglucose,
Ag,CO,
Bromoacetoglucose

HO /\.0H
OM
CHO KOH in MeCN wae
for

HO
HO/\OH A |
HCl in CH,
CHO EtAc mis
(AcO),:C,H,O-O O-C,H,O(OAc),4
.-_s. —__~

rg Cl

pee
IE O OMe
. va HO 1s < oH
acetylated hydrolysis Ba(OH), | OMe
malvin SE EnEEEEEEEEEEEEEEEEE O-C,H,,0;°

chloride HsO, tcl C,8:{0;-0
(XXV)

The anthocyanins can be characterised and qualitatively distinguished
by their distribution between immiscible solvents, and in the case of
disaccharides the use of n-butyl alcohol is convenient (demonstration).

Acylated anthocyanins occur in all the anthocyanidin series ; thus, on
hydrolysis, delphinin, the pigment of species of delphinium, furnishes
p-hydroxybenzoic acid as well as glucose and delphinidin.

Many other delphinidin derivatives are acylated by means of p-hydroxy-
cinnamic acid, probably attached to the sugar hydroxyls, and pelargonin
and cyanin also occur in acylated forms. ‘These so-called complex antho-
cyanins are characterised by high distribution numbers ; they are usually
acylated 3 : 5-dimonosides, but in the delphinidin series, gentianin and
violanin appear to be p-hydroxycinnamates of delphinidin monoglucoside
and rhamnoglucoside respectively (Karrer). There is also some evidence
of another type of depside anthocyanin in which the acyl group is directly
attached to the anthocyanidin molecule and the glucoside group is borne
by the hydroxyl of the acid residue.

e
OAc
CO OMe

B.—CHEMISTRY 53

ANTHOCYANINS AS INDICATORS AND THE CAUSES OF VARIATIONS OF
: CoLours OF FLOWERS

(With Mrs. G. M. Rosinson).

The amphoteric character of the anthocyanins accounts for the exhibi-
tion of a wide variety of colours in a range of solutions of graded pH, and
this method (demonstration), using buffered solutions, can be employed
for the characterisation of anthocyanidins and anthocyanins. Under the
specified conditions the results are fully reproducible and the pH values
have been controlled by electrical methods as well as by the use of indi-
cators. Thus, if the pH of an acid cyanin solution is increased until the
violet tone matches that of an alkaline cyanin solution, the pH of which
is decreased in order to reach the same condition, then the pH of the violet
solution will be found to be 7:0-9-0, depending on the shade of violet
produced. Cyanin is red in solutions of pH 3-0 or less, violet at pH 8°5
and blue at pH 11-0. The red, violet and blue forms are the oxonium salt
(XXIV), the colour-base (XXVI) and the salt of the colour-base (X XVII).

HOA Ov, at HOO yy io La PBe
c=¢7)=0 e=¢ =0
| tal ee |
C-0-C,H,,0; C-0-C,H,0;

/ ay
C.H,,0,0 & C,H,,0;"0

H

(XXVI) (XXVII)

(There is no evidence in regard to the assumed position of the quinonoid
group and the acidic hydroxyl.)

Now cyanin was isolated by Willstatter and his colleagues from the
blue cornflower and from the red rose, and it seemed quite a simple step
to assume that the cell-sap in the cornflower was alkaline and that in the
rose acid, particularly in view of the fact that the absorption spectra of the
coloured aqueous extracts correspond with these conditions.

It has indeed been generally assumed that the indicator colour of the
anthocyanin will give a measure of the pH of the cell-sap, but unfortunately
this method cannot be relied upon for several reasons. In the first place
there is a glaring anomaly in the fact that direct measurement by electrical
methods (glass electrode as arranged by Mrs. Kerridge) shows that the
cell-saps are all well on the acid side of the neutral point. Thus the
conventional view for red flowers may well be correct, but some special
circumstances must be invoked in the case of blue flowers.

Turning at once to the blue cornflower (the cultivated annual kind),
a blue filtered extract made with distilled water was found to be sufficiently
acid to turn blue litmus red. Using 3 g. of petals in 14 c.c. of distilled
water (pH 6-3 owing to dissolved CO,), the pH was 4:9. (These
quantities were used throughout the experiments and the use of larger
relative quantities of the petals did not alter the pH appreciably.) Addi-
tion of a buffered solution of pH 4-4 did not affect the colour, but the
colour changed to violet when the B.D.H. Universal Buffer, pH 9:0,
was added. It was at once apparent that the only simple explanation is

54 SECTIONAL ADDRESSES

that the cyanin anion is present in a complex form, giving a stable aggre-
gate with a negative charge ; in some way the strength of cyanin colour-
base as an acid must be vastly increased.

Some form of colloidal solution was considered most likely to fulfil the
necessary conditions, and Dr. Conmar Robinson, of the Chemistry
Department, University College, London, kindly examined a filtered,
distilled-water extract of blue cornflowers and reported as follows :

‘'The solution contains ultramicrons easily visible in the slit ultra-
microscope, but small enough to be in fairly rapid Brownian movement.
Microcataphoresis showed them to be negatively charged. Without
more quantitative work it is impossible to say if these particles can repre-
sent the bulk of the material present, but this seems probable if the
solution is very dilute ; the possibility of observing a colloidal impurity
is always a trap. he visibility of the ultramicrons suggests a lyo-
phobic colloid. It is, however, not precipitated even by 2N NaCl,
which indicates that a protective colloid is also present.’

Our next step was to attempt the production of blue cyanin sols stable
in neutral or weakly acid solution, and some measure of success was
achieved, although the solutions are by no means so stable as those from
the blue cornflower.

If a little crystalline cyanin chloride is added to boiling tap-water
(pH 8-0) then the usual violet solution results (see above), the colour
being what we consider ‘ normal.’ If, however, the cyanin is triturated
in the cold for a minute with the water and gradually heated to boiling
with shaking, then a beautiful blue solution results. The fact that the
same materials can be used to produce two entirely different results shows
that it can only be the state of aggregation of the cyanin which can have
stabilised the anionic charge and hence produced a blue colour under
the conditions that normally produce a violet solution. If very small
quantities of cyanin chloride are employed, this phenomenon can be repro-
duced using distilled water. Willstatter and Everest found that their corn-
flower extracts contained xylan and other polysaccharides, and we have
attempted to produce blue acid cyanin solutions in the presence of various
polysaccharides. The addition of dispersed xylan and various kinds of
starch, also Agar-Agar, makes the preparation of blue solutions of pH about
7:5 a very simple matter (demonstration), but we have not yet found a way
of imitating the cornflower solution in respect to its stability at pH 5-0.

Probably these colloid associations are much more readily formed at
values of pH between 5-5 and 6-5, and on the whole the blue flowers have
less acid cell-saps than the red flowers. The petals of the rose in contrast
with the cornflower constitute an exception (pH 5-6), and the following
further provisional results may be quoted although no great accuracy
can be claimed for a method which involves the destruction of the petals.
The pigment of the orange-red polyantha rose ‘ Gloria Mundi’ is found
to be pelargonin and the pH was 5-5. On the same plant some flowers
had reverted to the cyanin type. The red-flowered hydrangea had petal
PH 3°75, whilst the blue flowers gave pH 4:9; similarly the red-flowered
linum (anthocyanin based on delphinidin) gave petal pH 4-6, and the’
blue variety pH 5-9. Blue anchusa, 6:2; Meconopsis Baileyi, 5-3
(Miss R. Scott-Moncrieff found that blue and violet flowers had the

B.—CHEMISTRY 55

same petal pH); sweet-peas, all about 5-3; delphiniums, 5-6 (most
violet shade), 5-8 (most blue shade) ; clematis (blue), 5:4; viola, 6-2
(blue violet), 6-0 (reddish violet) ; lobelia (blue), 5-7.

It must be emphasised that these variations of pH are quite insufficient
in themselves to account for the colour changes and it is evident that the
most important single factor for flower colour, given the nature of the
anthocyanin, is the question of the condition of the pigment in solution,
and it would appear that all blue flowers are coloured by colloidal solutions
of their respective pigments.

Methods for the determination of the pH of the cell-sap of flowers
depending on the use of the flower colours as indicators may be sound,
but only if it can be guaranteed that the colloidal condition of the pigment
solution is not altered by the extraction with the buffered solutions which
are employed. In any case, the results bear no relation to the colours
observed in vitro using isolated anthocyanins and they cannot be trans-
ferred from flower to flower ; the colour series depends almost as much
on the other conditions in the cell-sap as on the pH and on the nature of
the anthocyanin. Another aspect of pH of the cell-saps is that the higher
values appear to be associated with the formation of delphinidin deriva-
tives. The remarkable distribution in the tropeolum—Empress of India
—is as follows: leaf, delphinidin diglycoside (pH 5-6); calyx, cyanidin
3-bioside (pH 5:0); flower, pelargonidin 3-bioside (pH 4-5). On the
other hand three scabious with anthocyanins based respectively on
pelargonidin, cyanidin and delphinidin had all the same petal pH 5:0.

We have already discussed elsewhere the influence of certain substances
termed co-pigments on the colour of anthocyanin solutions ; these effects
are to be detected in strongly acid solution and the presence or absence
of these substances is undoubtedly a factor to be taken into consideration.
The extent to which the co-pigment effect is bound up with colloid
phenomenon is a matter for future experiment and discussion, but it is
convenient to maintain the term co-pigment for the present.

Dr. E. A. H. Roberts has observed the shift of the absorption bands
of chrysanthemin and cenin chlorides on the addition of papaverine
(strongly blueing effect) and narcotine (weak effect), and correlated this
with a corresponding change (lowering) of the distribution number of the
anthocyanin using amyl alcohol (demonstration).

It seems clear that papaverine salts and cenin salts combine in solution.
The relation between the distribution number of cenin chloride and the
concentration of the pigment seems to require the assumption that the
molecules of the anthocyanin are associated (2 mols.) in aqueous solution
and free in amyl alcohol. Chrysanthemin and idzin behave similarly,
also malvidin 3-galactoside. ‘This phenomenon appears to be related to
that of co-pigmentation.

The naturally occurring co-pigments include the anthoxanthins (flavone
and flavonol saccharides, etc.) and tannins and some efficient substances
not yet identified.

The justification for assuming the operation of this factor can best be
indicated by an example. Certain herbaceous phlox contain pelargonin,
but have a much bluer-red colour than other flowers coloured by this
anthocyanin. But the same observation applies to the extract in I per

56 SECTIONAL ADDRESSES

cent. hydrochloric acid, and moreover the presence of much anthoxanthin
is noted. Hence, all the circumstances point to co-pigmentation of the
pelargonin salt in the flower petal.

Finally, we do not know whether or no traces of iron and other inorganic
substances may affect flower colour. In this connection the case of the
blue hydrangea is always quoted, and we have observed that when the
stalks of red hydrangea flowers are immersed in very dilute aqueous
ferric chloride, the flowers slowly become blue. .The ashes of many
flowers contain 1-2 per cent. Fe,O,, and the anthocyanin test for iron is
one of the most delicate known.

Summarising, the main factors affecting flower colours are :

(1) The nature and concentration of the anthocyanins and other
coloured substances present.

(2) The state of aggregation of the anthocyanin in solution—the pH
of the cell-sap is one of the subsidiary factors affecting this, and naturally
the presence or absence of protective colloids is another.

(3) The presence or absence of co-pigments and, problematically, the
effect of traces of iron and other complex forming metals.

Time does not permit me to deal with other anthocyanin types such as ges-
nerin, the leuco-anthocyanins, the yellow anthocyanin of Papaver nudicaule,
or the nitrogenous beet-pigment and its analogues ; I will close, appro-
priately I hope, on an experimental note by attempting a demonstration of
some of the tests which we employ for the recognition of anthocyanidins.

(1) The oxidation test—addition of 10 per cent. aqueous sodium
hydroxide to a dilute solution shaken with air—petunidin and delphinidin
are at once destroyed, the other anthocyanidins are relatively stable.

(2) Extraction with amyl alcohol, addition of sodium acetate and then
of a trace of ferric chloride. Characteristic colour reactions are observed,
and in particular if cyanidin is present the violet amyl alcoholic solution
changes to pure blue in the last stage. Pelargonidin, peonidin and
malvidin give no ferric reaction.

(3) Distribution between 1 per cent. aqueous hydrochloric acid and
a mixture of anisole (5 vols.) and ethyl zsoamyl ether (1 vol.) containing
5 g. of picric acid in 100 c.c. Delphinidin is not extracted by the organic
layer, petunidin is taken up to a slight extent, cyanidin to a considerable
extent, and malvidin, peonidin and pelargonidin are completely extracted
if the solution is sufficiently dilute.

(4) Distribution between 1 per cent. hydrochloric acid and a mixture of
cyclohexanol (1 vol.) and toluene (5 vols.). Delphinidin and petunidin
are not extracted at all; malvidin gives the organic layer a faint lilac
tint ; cyanidin a pale rose tint ; peonidin, and still more pelargonidin, are
extracted by the organic layer to a considerable extent.

The deductions are confirmed by a study of the colour reactions of the
anthocyanins.

In conclusion I must express my very deep indebtedness to all co-
workers in these fields, and especially to Dr. D. D. Pratt, Prof. A. Robert-
son, Dr. W. Bradley and Dr. A. R. Todd on the synthetic aspects of the
work, and to my wife, without whose co-operation a survey of natural
anthocyanins could not have been attempted.

SECTION C.—GEOLOGY.

A CORRELATION OF STRUCTURES IN
THE COALFIELDS OF THE MIDLAND
PROVINCE

ADDRESS BY
PROF. WILLIAM GEORGE FEARNSIDES, F.RS.,
PRESIDENT OF THE SECTION.

Tue effort called for in following rock outcrops over hilly country compels
the field geologist to think in three dimensions, and, in mountain ground,
whatever his first interest, he comes early to a stage when structure gets
the lion’s share of his attention. The rougher the country, the more
trouble is taken to interpret the implications of its surface geometry, until,
having achieved a partial solution, the researcher can project his imagin-
ings in depth and predict the locus of the outcrop in another place. In
this lies the fascination of our science, and each hill district of Britain is a
shrine to some enthusiast who would interpret the anatomy of our ancient
alps.

Lowland and coalfield country is less attractive, and it is because he
must that the mining geologist and the official surveyor there collects his
information. Without some knowledge of its solid geometry no geologist
can evaluate a coalfield property, nor should the engineer advise how the
development of mineral may proceed. The whole geometry of a coal
seam is never known until its wealth is spent, but, pending complete
solution, it is possible by stages to project from the fully known to the
unknown ; and in the older coalfields, where mining records have been
kept, there is such accumulation of local three-dimensional information
as can never be made available in the best exposed of mountain ground.

Mine plans are made on a scale so large that, for quick appreciation
and interpretation as contributions to regional geology, their records must
be reduced to the dimensions of a map. ‘Treated thus over great indus-
trial districts, where hundreds of square miles of several coal seams have
been wrought, they afford exact and documented evidence as well of
lateral variation of original sedimentation as of the size and form of
impressed structures. In detail such information is the stock-in-trade
of mineral agents, but in bulk it is rarely considered except by consulting
engineers and the maker of the plans.

Coalfields are extensive, their folding broad, and only where relief is
exceptional and the rocks diverse does regional structure leap tomeet theeye.
Coal Measure rocks other than sandstone are soft and weather deeply,
so that only where artificial excavations expose fresh material, or where,

58 SECTIONAL ADDRESSES

by feature mapping of the harder bands, the position of others can be
interpolated, can a coalfield map be made from surface evidence. Under
such conditions, in country which is marred and scarred by man, it is no
wonder that the local amateur is content to collect fossils from spoil-banks
or from brick-pits, and accepts from the professional what he is told about
the stratigraphy and structure.

Fortunately the officers of the Geological Survey now have full access
to mining information, and, as they compile the evidence they are recording
it upon the revised edition of the official 6-in. geological maps. As the
map sheets are issued their economic usefulness is recognised by the
mining profession, but, because of their fullness of detail and because
established prejudice regards all coalfield information as uninteresting
and dull, the subject matter has not received from other geologists the
attention it deserves.

As one whose business it is to teach geology at a university closely
associated with industry in the East Pennine Coalfield, I find the call for
local application of our science more often concerned with underground
geometry than with the composition of the rocks. Therefore, in training
men to lead in mineral exploitation, I have insisted that structural geology
is a science of measurement, and that the real geology of an area is not
fully known until it can be represented by a model true to scale.

From accumulated mining information, or from the modern geological
6-in. maps, it is not difficult to exemplify the shape and size of individual
structures, but in presenting a completed picture of a coalfield—even of a
district so far exploited as that of Yorkshire—the gaps in present know-
ledge are so wide that, lacking a working hypothesis to summarise the
shapes and distribution of the folds and faults, one must exterpolate, and
continually correct approximations as new information comes along.
During my years at Sheffield I have enjoyed the sport of correlating
nearby coalfield structures on dead-reckoning not less than similar pursuits
among the mountains, and it is in the hope that, from a review of obvious
trend-lines over a wider area an ordered plan of regional structure may
emerge, I have chosen the subject for this address. I am confident
that the study of coalfield structures is an open field for the advancement
of science, and as mining development proceeds in Coal Measures con-
cealed beneath the newer rocks, successful projection of the buried
structures promises no inconsiderable industrial reward.

Where Coal Measures rest conformably on Millstone Grit, the major
folds and faults disturbed both formations together, and the unit of struc-
ture is therefore greater than the coalfield. Recent investigations, in
establishing Upper Carboniferous zonal correlations, have made it certain
that a Pennine basin filled with Millstone Grit and Coal Measures
extended to the Midlands. The limestone massif of the Peak lines up
with Charnwood Forest, the downfold of Cheshire continues into Shrop-
shire ; so for a manageable unit of structure it is logical to take the area
within the nearmost outcrop ring of pre-Carboniferous rock. This is
the Midland Coalfield Province. It lies all within a circle of sixty miles
radius round Buxton. Its bounds are set towards the north by the scarp

C.—GEOLOGY 59

of the rigid block of Craven; in the west by the compacted ridges of
Denbighshire and the Berwyns ; and on the south by the ragged ribs of
ancient rock which fringe the Midland barrier of St. George’s Land.
Towards the east its unknown boundary lies buried beneath thick Permian,
Trias and Jurassic rocks, where no man has seen or touched the rocks
below the Carboniferous. This Midland Coalfield Province includes the
great coalfields of Yorkshire, Derbyshire and Nottinghamshire; of
Lancashire and Cheshire, and North Staffordshire ; and the lesser fields
of North Wales, Shropshire, South Staffordshire and Worcestershire,
Warwickshire, South Derbyshire and Leicestershire : and also the proved
and probable extensions of these coalfields underneath the Trias. Within
this Coalfield Province are nearly a thousand working mines, five hundred
of them each employing more than a hundred men in the winning and
working of some 120,000,000 tons of coal per year, or more than half the
total mineral wrought underground in Britain.

Study of regional structure must begin with notice of the mode of
accumulation of the local rocks and of the crustal movements which allowed
their accommodation, but in dealing with so wide an area in an address,
one cannot do more than mention the distribution and the varying thick-
ness of the sedimentary groups exposed. For details of their constitution
and stratigraphy a reference to the Geological Survey Sheet and District
Memoirs, and for a brief discussion and bibliography the chapters by
Garwood, Wright and Kendall in the 1929 Handbook of the Geology
of Great Britain, must suffice. The only further references noted are
to certain recent contributions not included in that extensive bibliography.

THE MIpLAND CARBONIFEROUS GEOSYNCLINE.

At all exposures round the edges of the Midland Province, older beds
of the Visean overlap with discordant unconformity against a land topo-
graphy of moderate relief. ‘Tournasian rocks are only recognised in the
deep trough south of the Craven Fault, where, in Pendle and the Craven
Lowlands, downward movement began early in the Carboniferous, and

1 The Geological Survey Publications drawn upon for information herein
summarised, include those descriptive of 1-in. maps, New Series, Sheets numbered :

76 Rochdale . ? 1927 126 Nottingham and

77 Huddersfield . 1928 Newark 1908
85 Manchester . 1930 137. Oswestry . 3 1928
86 Glossop . : 1933 138 Wem < : 1924
96 Liverpool . 3 1923 139 Stafford . 1927

too Sheffield . : IQI4 141 Derby and Bu rton-
ro8 Flint é F 1924 on-Trent ‘ 1905
110. Macclesfield r 1906 142 Melton Mowbray 1909
112 Chesterfield é 1929 152 Shrewsbury ; 1933
113 Ollerton . : IgII 153 Wolverhampton. 1929
121 Wrexham . SIESIG27 154 Lichfield . : 1926
123 Stoke-on-Trent . 1924 155 Atherstone , I9IO
125 Derby and Wirks- 156 Leicester . = 1903
worth . ¢ 1908 158 Birmingham . 1924
169 Coventry . - 1926

together with those relating to the parts of 1-in. maps, Old Series, Sheets
numbered : 53, 60, 61, 72, 73, 80, 81, 82, 87, 88, 89 and 90, which have not
been recently revised.

60 SECTIONAL ADDRESSES

was progressive until 10,000 ft. of pre-Coal Measure sediment was accom-
modated. Three thousand five hundred feet of alternating Visean shales
and reef knolls in this mid-Pennine trough contrast sharply with the
equivalent 400 ft. of Great Scar Limestone and overlying shale deposits
on the adjoining Ingleborough block.

Across North Wales and the southern Pennine district, Visean sedi-
ments are mainly bands and banks of shallow-water limestone, 1,800 ft.
thick at the head of the Vale of Clwyd, and a little more in the open section
along the Wye Valley in Derbyshire. Locally in the High Peak district,
and to a much greater extent where pierced by borings in search of oil
beneath the Derbyshire and Staffordshire Coalfields, these limestones are
interstratified with submarine eruptive products. ‘Towards the Midlands
the amplitude of Visean movements was less, and as the marginal beds of
limestone lap against St. George’s Land, though all the subdivisions are
represented, their total thickness has diminished to about 1,000 ft. on the
northern flanks of Charnwood, and to less than 300 ft. east of the Wrekin
towards the Severn Valley.

Visean deposits of the Midland Province end with shallow-water lime-
stones containing the D3 facies fauna, which may or may not belong to
one horizon. At some places cherty beds pass up to earthy ‘ black beds ’
and bituminous shales. Elsewhere the last of the grey limestones are
impersistent shell banks and limestone breccias, and there is striking
evidence of an interformational non-sequence. With application of
modern zonal methods to the faunas of the shales which overlie the lime-
stones, it has been recognised that in Pendle, between the topmost Visean
limestone and the beds with faunas identical with the lowest Edale shales
of Derbyshire, at least 3,000 ft. of land waste was accommodated. Lower
Lancastrian shales and grit bands are 2,000 ft. thick in Staffordshire,? but
have not been recognised in the Derwent Valley, so in Peakland the non-
sequence may become an unconformity. Transgression near the same
horizon has been followed along the edges of the Craven-Ingleborough
block, and the relation of the Holywell shales to the underlying cherts and
Cefn-y-fedw series in North Wales requires a similar explanation. ‘These
evidences of structural disturbance are not regular, and whether we regard
them as marking areas of local uplift, or attribute the non-sequence to
cessation of downward movement, we must recognise that they coincide
with arch folds which now dominate the local structure.

Most important of the early Lancastrian upfolds, from the point of
view of coalfield distribution, is the limestone plateau outcrop, the “ massif ’
of the High Peak of Derbyshire.2 Its margins have steep dips, but
though its place is the north-west extension of the Charnwood Pre-
Cambrian platform, there is underground evidence that its topmost lime-
stones extend widely in all directions beneath the overlying shales,* and
it cannot be accepted either as reef mass or as a pre-Lancastrian horst.

2S. W. Hester, ‘The Millstone Grit Succession in North Staffordshire,’
H.M.G.S. Summary of Progress for 1931, Pt. II, p. 34 (1932).

3 W. G. Fearnsides and others, ‘ The Geology of the Eastern part of the Peak
District,’ Proc. Geol. Assoc., vol. 43, p. 152 (1932).

4 T. Sington, ‘The Search for Petroleum in Derbyshire now in progress,’
Trans. Inst. Min. Eng., vol. 57, p- 25 (1919). TIF

C.—GEOLOGY 61

Moreover, its monoclinal edges are plicated by pitching cross-folds, on
whose arches are the reef knolls and beds of limestone breccia, and in
whose troughs there is the appearance of conformity from cherty limestone
to Lancastrian shales older than those which are continuous over inter-
vening arches. These cross-folds have persisted as belts of instability
throughout and beyond the period of the Carboniferous. ‘Their extended
axial lines are marked by rapid pinching out of sandstones of the Millstone
Grit deposits, and they line up with the steep-sided anticlines and synclines
of the Derbyshire and Midland Coalfields. The most northerly of these
curving cross-folds terminates and contains the High Peak limestone area,
and beyond it there is no evidence of pre-Lancastrian uplift of any central
Pennine fold.

During the later Lancastrian or Millstone Grit period, and on throughout
the Coal Measures, negative movement, though progressive, was punctu-
ated by frequent delays. Sediment was delivered to Yorkshire in such
quantity that it could not be accommodated until regional settlement had
made its place. During the waiting periods therefore it drifted on
towards Cheshire and built its lenses on the front of the growing delta.
As sinking proceeded there was agitation in the shallows, and coarse
material was entrapped in deepening troughs. Coarseness of sediment
in such measures, though it must always be an index of the velocity of the
inwash current, can in no wise be accepted as a criterion of proximity
to a shelving shore.

Lancastrian sediments are thickest north of the Lancashire Coalfield,
where more than 5,000 ft. of shales and grits were accommodated. ‘The
Millstone Grit divisions lose thickness southward round about the Peak
district, but in Staffordshire the bore-hole at Rownall Hall, started below
the Middle Grits, had not reached limestone at a depth of 2,700 ft.°
Against the encircling fold which ends the limestone outcrop of the High
Peak at Castleton, lenses of sandstone, which are exceptionally strong in
the ‘edges’ of Kinderscout, lose half their thickness. We have no proof
that P. or lower E. beds were ever deposited over the High Peak district,
but mineral constitution seems to show that the coarsest Middle Grits
were persistent from the Derbyshire Edges east of the Derwent to the
Roaches of Staffordshire. Within the East Pennine Coalfield, deep
borings indicate a wedging out of the whole series south-eastwards, from
1,500 ft. thick at Renishaw to less than 300 ft. at Kelham. ‘The available
records are all from trial oil wells in anticlinal areas, and there is evidence
of grits and shales outcropping north-west of Charnwood, and Lower
Lancastrian Ez shales persist beyond the Hathern boring.’ South-
westwards across Lancashire the advancing Millstone Grit delta did not
reach North Wales, and in 400 ft. of Holywell shales all the Lancastrian
zones are represented.

Despite pulsatory and progressive subsidence, the whole South Pennine
area was filled and levelled to a plain before the period of the Millstone
Grit was ended, and the latest G. marine band spread over and drowned

5 H. P. W. Giffard, ‘ The Recent Search for Oil in Great Britain,’ Tvans. Inst.

Min. Eng., vol. 65, p. 221 (1923).
6 ‘ Wells and Springs of Leicestershire,’ p. 99. H.M.G.S. Mem. (1931).

62 SECTIONAL ADDRESSES

a coal seam which extended across the Midland Province. This is the
famous Alton, Halifax Hard, Bullion, Upper Foot, or Crabtree Coal Marine
Band. Near the top of the Productive Measures the Mansfield, Sharlstone,
Dukinfield, or Speedwell Marine Band is similarly continuous in all Pennine
coalfields, and the thickness of measures between the two affords a trust-
worthy indication of the aggregate amplitude of negative movement in the
various districts during the Coal Measure period. By measurement of
this distance we recognise in South-east Lancashire, where the intervening
thickness exceeds 4,000 ft., the regional centre of the Coal Measure collect-
ing dish. About that centre in all directions the thickness of sedi-
ment accommodated diminishes to 2,000 ft. in less than 50 miles. By
plottings of isohypses of sediment between successive coal seams, we can,
with labour and persistence, prove the local variations in the amplitude
of depression to any degree of accuracy we choose. Each coal seam grew
at water-level during a waiting period, but individual coals are not
sufficiently persistent, and only exceptional groups of coals have a coalfield-
wide distribution. For comparative studies of variations of the rate and
amount of movement as between one coalfield and another, we therefore
depend upon the modern method of identification and correlation of Coal
Measure horizons by interstratified non-marine lamellibranch zones.”

Consideration of the lowest group, the Halifax Coal Measures, shows
them thickest in North or Central Lancashire, where also the Millstone
Grits are thickest. There more than 1,000 ft. of Coal Measures underlie
the Arley Mine. Equivalent measures § at outcrops in Yorkshire, Derby-
shire and North Staffordshire are less than half that thickness. The
Ovalis zone, 600 to 1,000 ft. thick in Yorkshire, is more than 1,500 ft.
thick in Central Lancashire. It thins eastwards across Yorkshire, and
to the south-east across Derbyshire to: Nottingham. ‘The Modiolaris
zone, the main coal-bearing belt, maintains through Yorkshire and
Derbyshire a wonderfully constant thickness, about 1,000 ft., along the
strip of country where Park Gate and Barnsley coals are wrought. ‘This
zone is fully 1,200 ft. thick about Oldham, but thins southwards through
Cheshire into North Staffordshire, and more rapidly westwards across
Lancashire.

Variation of thickness in the Similis-Pulchra zone is much more rapid.
This zone attains its maximum thickness in the Pennines south-east of
Manchester. East of the Pennines a plotting of isohypses for the sedi-
ments between the Barnsley Coal and the Mansfield Marine Band proves
a thinning from over 1,000 ft. at outcrop to less than 500 ft. in the most
easterly of working pits, which rate of thinning, if continued, would give
the Barnsley Bed the Mansfield Marine Band for its roof within a very
few miles east of the Trent. Beds between the Mansfield and the Shafton

7 D. A. Wray and A. E. Trueman, ‘ The Non-marine Lamellibranchs of the
Upper Carboniferous of Yorkshire and their zonal sequence,’ H.M.G.S. Summary
of Progress for 1930, Pt. III, p. 70 (1931).

7 A. E. Trueman, ‘A suggested correlation of the Coal Measures of England
and Wales,’ Proc. South Wales Inst. Eng., vol. 49, p. 63 (1933).

8 D. A. Wray, L. Slater and G. E. Eddy, ‘ The Correlation of the Arley Mine
of Lancahsire with the Better Bed Coal of Yorkshire,’ H.M.G.S, Summary of
Progress for 1930, Pt. II, p. 1 (1931).

C.—GEOLOGY 63

Marine Bands in Yorkshire and Nottinghamshire similarly wedge out
rapidly towards the east and south. Across Lancashire the westward
diminution of thickness is continuous. About Oldham the Dukinfield
Marine Band is 1,250 ft. above the Furnace Coal, whereas at Tyldesley
its place is less than 800 ft. above the Rams. In the trough of North
Staffordshire near Tunstall the Speedwell Marine Band is 1,400 ft.
above the Ten Foot Coal, but there is rapid wedging out of measures
both towards the western anticline and towards the south.

The Pottery Marl and Blackband Ironstone series of the A. Phillipsii
zone in North Staffordshire may be 1,200 ft. thick. They pass up into
an equal or greater thickness of red and mottled Etruria Marls. In
South-east Lancashire 1,800 ft. of grey measures, including the Bradford
group of coals, overlie the Worsley Four Foot (which may be the Shafton
Coal of Yorkshire), and underlie the variegated marls and limestones of
the Ardwick series. East of the Pennines Etruria Marls are preserved
only in the centres of the synclines. Beneath them in South Yorkshire,
above the Shafton Marine Band, grey beds, mostly sandstones, are
1,200 ft. thick, but between Mansfield and Nottingham equivalent
measures thin south-eastwards to less than 300 ft.

Because of cumulative displacement by negative pulsations, and
because the supply of sediment was never-failing, Coal Measures in the
great coalfields which flank the southern Pennines are an expanded series.
Southwards along the margins of the Province less accommodation was
provided, and Productive Measures taper out against the Midland barrier
of St. George’s Land. Zonal correlation by non-marine lamellibranchs is
not yet available for the Thick Coal district of South Staffordshire and
Warwick, and the best suggestion for correlation of horizons is by the tracing
of coal seams in relation to occasional marine bands. Away from the
Pennines, the G. or Alton Marine Band has not been proved beyond South
Derbyshire, where it lies about 1,000 ft. below the Main Coal, and has
below it Millstone Grit. A more persistent marine band overlies the
Main Coal in Leicestershire and the Seven Foot Coal in Warwickshire,
and this may be the White Stone Band below the Heathen Coal of the
Black Country and the Pennystone of Coalbrookdale. If one may guess
that it is also the Speedwell Band of Staffordshire, its position within
_ 200 or even 100 ft. above the pre-Carboniferous bed-rock of the Thick
Coal districts is evidence that these shores of the Midland barrier did not
come within the belt of sedimentation until a late stage of the infilling of
the Coal Measure basin. If it represents the marine band above the
Seven Foot Banbury, at the base of the Modiolaris zone, it must indicate
that the creeping transgression which brought these beds across the
upraised edges of Midland Visean and Lancastrian deposits was in-
ordinately slow. The thickness of the Productive Coal Measure sedi-
ments accommodated in the Midland coalfields is from one-tenth to one-
fifth of that disposed in the Central Pennine area of North Staffordshire.
Conditions must have been strangely static for a very long period when
the Thick Coals were growing, but within that series there are no more
appearances of stratigraphical discordance than where equivalent sedi-
ments are thick.

64 SECTIONAL ADDRESSES

Increase of the thickness zone by zone towards the centre in the southern
Pennine area may be accepted as evidence of progressive geosynclinal
development and its differential deepening. ‘There is compounded with
this regional settlement increase of thickness in troughs and thinnings
towards the crests of local folds. Probably the best-known coalfield
example of such local variability is the Potteries syncline and the adjoining
Western or Rearers anticline of North Staffordshire. ‘There from crest
to trough the total thickness of Productive Measures underneath the Red
Beds varies within two miles from 2,500 to 3,500 ft. Individual coal
seams continue across the whole coalfield ; marine bands and shales with
non-marine lamellibranchs are similarly persistent, and the variable
component in the measures is the coarse land waste which accumulated
in thicker and more numerous sandstone lenses towards the centre of the
trough. There is no evidence that the crest of this fold was so uplifted
that some beds might have been denuded ; and it follows that the develop-
ment of the anticline was by differential sinking of the lateral troughs.
As with the regional tilting towards the centre of the geosyncline, so in
this local folding the rate of change of thickness was slow until the more
important coals had grown (Ovalis and Modiolaris zones), but becomes
increasingly differential through and towards the later part of the Similis-
Pulchra zone.

The Horseshoe anticline in the North Wales Coalfield has a slightly
different history. It too was sinking more slowly than neighbouring
areas when measures containing the Lower Coal series were deposited
across it. Thereafter, though it continued to receive a share of sediment,
it maintained a line of shoals which acted as a barrier and diverted the
flow of sediment, so that there is striking dissimilarity between the
Bulkeley Fireclay series formed in the troughs of Flint, and the Upper
Coal and Cefn Rock series deposited contemporaneously in Denbighshire.
At its northern end along the Dee estuary, before the deposition of red
Upper Coal Measures over it, some hundreds of feet of measures were
denuded from its broken and upraised crest. Series of wash-outs in
coal seams under sandstones in the Flintshire syncline are interpreted
as erosion features produced by stream-courses directed longitudinally by
the folding of the trough.

In Coalbrookdale, Productive Measures, including some hundreds of
feet of measures newer than the Pennystone, were sharply folded and
faulted by posthumous disturbances of pre-Carboniferous post-Silurian
folds. 'These movements were mainly completed and the anticlinal crests
denuded before the overstep of Upper Coal Measures, which is the
unconformity of the Symon ‘ Fault.’

Statistical studies of colliery records within the open folds of Yorkshire
are bringing evidence that above the Barnsley Coal, and especially towards
the top of the Similis-Pulchra and through the lower parts of the Phillipsii
zones, the total thickness and the proportion of sandstone in the sedi-
mentary column increases progressively to a maximum over the deepest
parts of the Frickley and Maltby troughs.® ‘There is no suggestion of

® “Sections of Strata of the Yorkshire Coalfield,’ Midland Inst. of Min. Eng.
(1927).

C.—GEOLOGY 65

any emergence of the Don Valley fold before the Red Beds were deposited
over it, but both in Yorkshire and in Derbyshire, where the folds are
steeper and narrower, it is probable that by the time the latest coal streaks
of the A. Phillipsii zone had accumulated, the workable coals lay many
hundreds of feet deeper in the synclines than over the anticlines between.

The latest grey beds of the Phillipsii zone pass up by alternations into
the Red and Mottled series which for convenience is taken as the lowest
division of the Upper Coal Measures. ‘These variegated and ill-stratified
Brick and Tile Marls (Etruria Marls) are over 1,250 ft. thick in the
trough of the Potteries Coalfield, and as the Ruabon Marl group in
Denbighshire their thickness is hardly less. Of the equivalent Ardwick
group of the Manchester syncline, over 1,000 ft. remains below the
Collyhurst Sandstone. At Farnsfield in Nottinghamshire, some 600 ft.
of variegated beds are preserved beneath the Permian in the deepest part
of the East Pennine basin. In South Staffordshire, the thickness of the
Marl group is very variable, from 800 to 150 ft. within two miles, and
there is evidence that with redisturbance of local folds across the Black
Country, trough-like areas were developed in which deposition kept pace
with the sinking of the floor. In Warwickshire and in Shropshire, and
in the south of South Staffordshire, the Marl group overlaps the Productive
Coal Measures against the shores of islands, whose waste provided the
fragments which compose the Espley Rocks.

The Newcastle-under-Lyme group of the Potteries is 600 ft. thick.
Its variegated grey and green beds mark a temporary late return to normal
Coal Measure conditions in the south-west Midland area. As the
Halesowen Sandstone group of South Staffordshire and Warwickshire,
and the Coalport group of Shropshire, its component members thin as
they overstep towards the south, and it rests with slight unconformity on
the Old Hill Marls or older rocks below.

Over the eastern part of the Midland Coalfield Province, the strati-
graphical record of the early development of structures ends with the
deposits of the A. Phillipsii zone. In the south-west, red and purple
marls, sandstones and conglomerates, deposited in reasonably strict
conformity upon the latest coal-bearing series, carry on the history of
settlement and contemporaneous filling of a land-locked basin to a later
stage.

In North Staffordshire some 700 ft. of red, purple and grey marls and
sandstones form the Keele group. Over the Warwickshire Coalfield and
all round the South Staffordshire Coalfield this group maintains its
thickness, but in Shropshire it tapers out south-westwards as it overlaps
beyond the coalfields against the edges of older land. Upwards it passes
into the calcareous Enville group of Staffordshire or the Corley group of
Warwickshire, with interstratified lenses of conglomerate, and in the
higher parts has great wedges of breccia, scree or torrent-borne products
derived from neighbouring Lower Carboniferous, Silurian, Cambrian
or Pre-Cambrian outcrops upraised towards the south. In southern
Warwickshire,!° the thickness of the extended Corley group is not less
_ 10 F, W. Shotton, ‘On the Geology of the Country around Kenilworth,’

Q.J.G.S., vol. 85, p. 170 (1929).
D

66 SECTIONAL ADDRESSES

than 3,500 ft., and along the Severn Valley the Clent Breccias are also
thick. Northwards and westwards, as the breccia beds tail out, the group
becomes difficult to separate from calcareous Keele beds with which they
are included in the 2,000-3,000 ft. thick Erbistock series of Denbighshire.

The accommodation of such thickness of Upper Coal Measures over
the Western Midlands necessitated the shifting the Pennine geosynclinal
centre towards the south. ‘To what extent the uprising of the Derbyshire
High Peak area was contemporaneous, is not known, but pebbles in
Midland conglomerates have not been traced to any Pennine source. In
the Ingleton Coalfield the highest Red Beds with bands of Spirorbis lime-
stone are associated with brockram scree deposits, and by this stage uplift
to the north and denudation of the escarpment of the Craven Faults had
there exposed the Lower Carboniferous,

In the Concealed Coalfield of Yorkshire and Nottinghamshire basal
Permian transgresses 5,000 ft. of folded Coal Measures. The simple
geometry of the floor on which the Permian rests shows that, following
the storm of crustal movements, the cycle of denudation was completed.
The regular eastward slope of that buried peneplain from Tynemouth to
Nottingham is proof that that side of the Pennines was already con-
solidated as a structural unit, which, rippled by gentle swelling of the
underlying cross-folds, and cracked a little by rejuvenated coalfield faults,
has since been tilted as a whole. Such later displacements as, east of
Leeds and about Nottingham, have also cut the Trias, are of amplitude
insufficient to distort the structural pattern, which, born before the end
of the Visean, developed during the Lancastrian and Productive Coal
Measure period, attained maturity when the Red Beds of the Midlands
were being deposited, and was dissected and planated before tilting and
regional settlement depressed it to receive the sediments of the Magnesian
Limestone sea.

West of the Pennines, the Collyhurst Sandstone rests with sharp dis-
cordance upon the tilted Ardwick group, and westwards transgresses
3,800 ft. of underlying Productive Coal Measures. Its thickness alters
abruptly, sometimes by hundreds of feet, at the crossings of important
faults, and its disposition suggests accumulation in the fault scarp hollows
at the foot of the upraised and faulted Pennine and Rossendale anticlinal
ridges. The Manchester Marls above it are displaced, but not otherwise
affected by faulting which also cuts the Trias. They contain a fauna
correlated with the Lower Magnesian Limestone, and pass up by transition
into the Bunter Sandstone of the Cheshire Basin.

South of the Pennines the evidence of post-Carboniferous chronology
is mainly buried under Trias, which banks against a land surface composed
of every kind of older rock. Each exposed Midland coalfield is a dish or
dimple in an upraised horst, bounded by faulted folds of variable pitch,
which are axially convergent on the Coal Measure geosynclinal centre west
of the Peak near Manchester. In middle limbs outside the lateral crests
are powerful but discontinuous boundary faults, flanking the Trias-filled
deep depressions which contain concealed coalfields. ‘These boundary
faults are late Carboniferous structures which displace alike all members
of the Productive and Upper Coal Measures, to and including the Keele

C.—GEOLOGY 67

group, and much of the Corley and Lower Enville beds. Several of them
line up with older breaks in the pre-Carboniferous platform, and many
are known to have continued their displacement during and after the
deposition of the Trias. Marl conglomerates towards the top of the
Upper Coal Measures suggest contemporaneous movement of neighbouring
faults, but pebble and breccia beds are torrent-borne from southern lands,
and the main displacement of both folds and faults is later than the Upper
Coal Measures deposits. Possibly the latest Enville, Corley and Erbistock
beds are contemporaneous with some Magnesian Limestone, but proof is
lacking, and the steady structure demonstrated in the basal Permian
peneplain is not yet recognised west of Derbyshire.

There being no fossils in the Trias of the Midland Province, the age of
movements affecting it cannot be checked by zoning. Wedges of Bunter _
Sands and Keuper Marls in Nottingham overlap the wedge of Magnesian
Limestone to rest on Coal Measures and older rocks in Derbyshire and
Leicestershire. ‘Tilting continued with sedimentation, and east of the
Pennines the sloping surface of concealed Coal Measures is buried under
a thousand yards of Permian and Trias within a few miles east of the
Trent. The great basin of Cheshire with its salt beds, and Shropshire
with its patch of Lias, downfolded as it filled. Its depth and what lies
under it are matters for conjecture, but the Plumley borehole pierced
2,500 ft. of Keuper, and Bunter Beds at Heswall have been proved
2,200 ft. thick. The turn-up of Trias to the western anticline of
Staffordshire, and the Red Rock Fault of Cheshire, is evidence of further
substantial settlement, since the deposition of the down-tilted beds.

The Trias basin of Staffordshire sagged as a duplex trough on either
side of the faulted saddle of the Black Country. ‘The western downfold,
like the Shropshire basin, is edged about with latest Carboniferous Red
Beds, and within it conformable passage between the two formations is
not impossible. In the depression to the east of Stafford, the Chartley
boring passed through 2,000 ft. of Trias, and outliers of Rhztic lie further
to the east. From the north part of this basin fingers of Bunter extend
along steep-sided valleys scored in the southern ending of the Pennines.
The edges of the Leicestershire platform are also ragged ; and against and
over them Bunter is overlapped by Keuper, which completes the transgres-
sion of ‘Trias across the coalfield synclines of Warwickshire and Leicester-
shire, and overtops the sharp, upstanding peaks of Charnwood Forest.
That core of Pre-Cambrian in Charnwood, along with the western portion
of the Pennine block, must have been elevated as the Nottinghamshire,
Staffordshire and Cheshire Trias basins were being filled. Eventually
all elevations, cluttered up in their own debris, were buried under the
great bulk of material washed to the Midlands by torrents or wind-swept
from the foothills of the great Hercynian Chain. By the time the desert
deposits of the Keuper were covered by the Rhztic Sea, the whole Midland
Province had been upgraded to a plain.

Wherever there is exposure of bare rock, and diversity of rock character

_ to show it, there is evidence that the even lie of Trias and post-'Triassic

_ rocks has been disturbed by later movements, but in the Midland Coalfield

Province, except for certain arcuate groups of east-west faults which cross

68 . SECTIONAL ADDRESSES

the Pennines, and a few north-west fractures occupied by Tertiary dykes,
- the disposition of those faults agrees so closely with the trend of older
structures that all may be interpreted as posthumous adjustments of the
underlying floor. The later structural history of the Midland Coalfield
Province is not documented by its own deposits, and we may leave the
stratigraphical study of its development at this stage.

Fotp DISTRIBUTION.

A striking feature of the small-scale geological map of England is the
alignment of the coalfields in east-west rows. The coalfield of South
Wales is an east-west downfold in the forefield of the Hercynian mountain
chain, and it has been assumed that, beyond the upfold of the Midland or
Mercian Highland barrier, the Midland group of coalfields occupies the
following trough. The history of coalfield evolution outlined above tells
us that the Midland barrier was already a structural unit when Carbon-
iferous rocks were laid against it. There is no suggestion of natural
separation of the southern Midland coalfield district from the greater
coalfields around the southern Pennines. The filled Carboniferous
geosynclinal basin, subsequently everted, must for structural purposes
be considered as a whole. The wide pre-Permian break between its
Yorkshire-Lancashire edge and the downfold containing the Durham-
Cumberland alignment also may be a Hercynian master-upfold, but
pending analysis of its structures, it were well to suspend judgment.

With the idea that east-west downfolds across the Midlands are
Hercynian, goes the notion that the Pennine ‘ backbone of England ’ is
a complementary north-south cross-fold; but there is divergence of
strikes within it, and as we know that the limestone district of Derbyshire
was upstanding at the time of the pre-Lancastrian unconformity, it is
difficult to accept it as other than a rejuvenated and accentuated group of
older structures.

Having looked for and failed to recognise the leading lines of the
supposed Hercynian chessboard in the arrangement of coalfields within
the Midland Province, I long since suggested that the upstanding High
Peak massif of limestone of Derbyshire is founded upon an extension of
the pre-Cambrian platform of Charnwood Forest, and I would now
maintain that contention by a demonstration of the distribution of its
supporting folds. To this end I have had compiled, first by pantographic
reduction from the 1-in. geological maps to the }-in. scale, and then by
photography and retracing, the diagram (Fig. 1), on which are plotted in
correct relationship all fold-lines which the officers of the Geological Survey
have located and indicated on the published maps.” ‘The result is striking,
both in confirming the alignment of the High Peak plateau with Charnwood
Forest, and in its emphasis of the persistence of other ridge lines from the

11 W. G. Fearnsides, ‘ Some Effects of Earth Movement on the Coal Measures
of the Sheffield District,’ Pt. II., Tvans. Inst. Min. Eng., vol. 51, pp. 445-450
(1916).

12 The laborious work of this reduction was undertaken by William Pulfrey,
M.Sc., Ph.D., research worker in the Department of Geology at Sheffield
University, to whom I return grateful thanks.

wa
:
|

7

On tur

:
2
g
=

Sak et

= SEs

- An ae a -

FOLD AXES

IN THE Ls
LAND COALFIELDS

Ey

D
rT

|

Fig. 1.

C.—GEOLOGY 69

scattered outcrops of Lower Palzozoic formations around the Midlands in
later foldings of the Carboniferous rocks. ‘There is no chessboard or other
interlacing of the folds. ‘The folds are congruent, curving, clustered or
‘divergent ; acute and often steeply pitching where there is great change
of stratigraphical level, but ill-defined and widely separated where the
troughs are broad. It is difficult to perceive how, in yielding under
unilateral stress, sheets of new-made Coal Measures could have wrinkled
in such forms. It seems more likely that, like blankets on the bed of
-arestless sleeper, they have heaved and buckled in accommodating them-
selves to the movements down below. It is recognised that in the con-
temporaneous filling of each deepening syncline, as old folds tightened
differences of rigidity between adjoining areas must have been perpetuated,
and thus, whatever crustal thrust has later disturbed the underlying Lower
Palzozoic platform, could not do other than exaggerate existing strains.
Established lines of yielding have been from age to age rejuvenated, but
the plotting of fold-lines has discovered no local bending structures in
the Midland Coalfield Province, which can be determined as begun by
late Carboniferous movements, or as having adopted a novel impressed
Armorican or Hercynian trend.

To the coalminer the unit of structure is the coalfield—a group of
several down-folds forming a distorted trough or synclinorium. For the
geologist arches are more conveniently described as individual structures,
The complex ridge of Charnwood pitches down north-westward under
the Trent Valley, beyond which, by Ashbourne, folds rise to culminate
near Buxton. Northwards the Pennine anticlinal crest droops down
some 2,000 ft. under Kinderscout. ‘Thence it continues almost on level
course along the mid-Pennine ridge of Millstone Grit, and curves a little
towards the east to Keighley. At intervals of a few miles the High Peak
ridge throws off, most noticeably towards the east, trailing transverse
folds, which spread fanwise across the Derbyshire Coalfield. ‘These trans-
verse folds are sinuous in plan, and variable both in amplitude and pitch.
Locally intensified, they bring up the limestone inliers of Crich and
Ashover, and the cracked domes which were pricked for oil, successfully
at Hardstoft, but unsuccessfully at Brimington, Renishaw, Ridgeway and
Ironville. Never straight, their direction swings round in reversed ‘S’
bends almost through a quadrant. 'To the north in the moorland country
the transverse undulations are less acute, their crest-lines swing first
northwards, and then eastwards and a little southwards, as they lose
themselves in the broad trough of the Yorkshire Coalfield.

On the west side of the Pennine-Peak-Charnwood ridge-line the change
of geological level is rapid. In Leicestershire the Thringston Fault puts
Coal Measures against Pre-Cambrian, and with the two or three sharp
infolds of minor coalfields west of Buxton, the High Peak adjoins the
Cheshire Plain. This last great downfold, however, is not a simple
structure. To it, as to a neck, the extensions of the folds between
Charnwood and the Longmynd come to meet and join. The triangular
form of the North Staffordshire Coalfield demonstrates the gape of the
virgation within whose southward opening rise the ribs which are the
Productive Coalfield of the Midland district. The plotting shows that

70 SECTIONAL ADDRESSES

each major fold axis in the Midlands, if extended northwards, would come
to Manchester. Within the convergence the pitch of folds is somewhat
variable, but there is no evidence of interweaving, or rise and fall by cross-
folding, which can be interpreted as compounding with broad east-west
Hercynian folds. North and west of Buxton folds in the Millstone
Grit country swing southwards round the High Peak ridge, and there
is rude symmetry of fold distribution in Staffordshire and Derbyshire
about the north-west line of the extended Charnian axis.

Across the Manchester Coalfield the broad trough is cut to ribbons by
north-west faults, which break the measures, as, bending, they dive
towards the Cheshire Plain. Minor folds alongside major faults have
axes which diverge westwards from the Pennine fold. The east-west
Rossendale anticline of mid-Lancashire is so broad a swell that, as with
its neighbour the even broader Cheshire basin, the location of its merging
in the Pennine fold is ill-defined. ‘The sharp monocline which makes the
Pennine crest near Todmorden bends round to the east towards Keighley,
and the triangular trough of the Burnley Coalfield is evidence that the
Charnian midrib of the South Pennine structure, which is more or less
continuous from Leicestershire, has here ended.

Beyond the North Lancashire Coalfield the trend of sharp folds in the
Craven lowlands is north-easterly. They swing to the eastwards through
Skipton as far as Leeds, to follow and define the northern edge of the
Yorkshire Coalfield. From their divergence to the westwards it is evident
that the Craven lowlands and North-west Lancashire is a structural unit
quite distinct from the North Lancashire Coalfield, and there is similarity
of structure between this Pendle-Bowland area adjacent to the Craven
Faults and the fold virgation in North Staffordshire.

The structure of the North Wales coalfield country north-west from
Shropshire has lately been discussed by officers of the Geological Survey,
and folds affecting Carboniferous rocks are interpreted as due to tightening
and adjustment of structures already developed in the Lower Palzozoic
rocks.13 Whether or not the upstanding mass of the Longmynd has
protected from Hercynian fold invasion the plains of Southern Cheshire,
resultant movement in Flint and Denbighshire has produced the horse-
shoe anticlines whose range is more or less parallel to the Lower Palzozoic
outcrop, and in groups separated by great tear faults they bulge eastwards
upon the Cheshire Plain.

FAULT-PATTERN.

Following the consideration of fold axes, a similar plotting and reduction
has been made " of the distribution and alignment of recorded faults, and
the intricate patterning of Fig. 2 results. From comparisons of super-
posed diagrams, as first reduced to the }-in. scale, it is clear that the
dominant families of faults follow the limbs of folds, but that they sweep
in curves of radius larger than the axial curvature of folds. No fault

13 C, B. Wedd, ‘ The Principles of Paleozoic and later Tectonic Structure
between the Longmynd and the Berwyns,’ H.M.G.S. Summary of Progress for
$93T,/ Pt. TE pt i(r932):

14 Also by Dr. Pulfrey.

FAULT STRUCTURE
IN THE
MIDLAND COALFIELDS

10
Tin =

o

C.—GEOLOGY 71

outcrop is really straight or continuous for many miles, but major fault-
lines curve witha radius which is often greater than ten or even twenty miles.
Leading faults, changing direction, give off tangential branch faults or
receive tributaries which trail in at angles less than 45°. Transverse
faults are usual across the troughs of pitching synclines. Where trans-
verse and longitudinal faults cut the country into more or less quadrangular
blocks, faults which are ending bend to meet the curve of the persistent
fault.

Large faults are generally associated with change of dip or change of
strike of strata, and are therefore inconstant in their throw. Large
faults frequently occur en echelon in the middle limbs or sides of troughs,
where their direction makes a small angle with both the strike of the
measures and the pitch axis of the fold. Mostly faults tend to converge
towards a rise of pitch. ‘Transverse faults sometimes displace the crests
of anticlines, but are of greater importance as they reduce the effect of
pitch along the synclines. Most transverse faults bend and lose their
throw as they approach the steeper middle limbs of folds, and change the
curvature of their direction as they pass from anticline to syncline.

Certain groups of complex or paired trough fractures sweep in
discontinuous arcuate curves across the Midland Coalfield Province on
a radius as great as fifty or sixty miles. These are not obviously related
either to the trend of noticed folds or to the longitudinal or transverse fault
breaks, with some of which they join. Of them the most extensive system
follows a rude semicircle through the North Lancashire and East Pennine
Coalfields from Accrington, by Todmorden to Huddersfield and Sheffield,
and across Derbyshire to the Dukeries. If it is continuous with the fault
belt which from Blackburn extends to Wigan and St. Helens, it may
encircle the Cheshire Basin.

Other fault groups which bend round the High Peak of Derbyshire
also cross the Pennines. These carry on through the Derbyshire and
Nottinghamshire Coalfield, and may encircle the platform of Charnwood
Forest. The most northerly of this group traverses the Pennines from
Rochdale to the Calder Valley, and intercrosses with the Todmorden-
Sheffield disturbance in the Rishworth Moors. A more southerly group
close to the limestone boundary at Castleton passing by Holmesfield and
Chesterfield to the south of Mansfield, crosses and recrosses the reversed

*$° bend of the Brimington anticlinal axis.

In Flint and Denbighshire also, arcuate groups of fractures likewise
slice across the horseshoe fold axes. These are circumferential to the
Silurian buttress of Snowdonia. Where, in the Trent Valley, Trias is
banked against the southern ending of the Pennines, broadly arcuate
east-west fractures cut directly across the Pennine Carboniferous folds.

Appreciation or description of coalfield fault pattern is difficult except
by diagram, but regional trends change gradually, and within the Midland
Coalfield Province the only apparent discontinuities are gaps or obscurities
due to lack of information. Drift obscures the fault outcrops in the Trias
_ country, and Carboniferous, deep bedded under Trias, reveals its structure
only as the coal is worked.

The criss-cross fault arrangement of the Yorkshire Coalfield has been

72 SECTIONAL ADDRESSES

compared by Professor Kendall }° to the crack lattice produced by twisting
slabs of glass, and the differential lifting of the Pennines was suggested
as the agency of the twist. The analogy is a good one in that it reminds
us that the simplest kind of stress may in a single operation by resolution
produce the diamond fault-block pattern. North of the Don the most
persistent faults are longitudinal in the flanks of the wide West Yorkshire
trough, wherein they converge and anastomose, with rise of pitch north-
westward. In this area transverse faults preserve an almost constant
north-easterly direction. Most of their movement was pre-Permian, but
some have since increased their displacement, and certain east-west faults
which are longitudinal in the flank of the northern boundary anticline
extend into the Trias. There is to the north of the Don anticline, near
Rotherham, one area twenty square miles in extent without a charted
fault. That, however, is exceptional, and triangular or quadrangular
blocks, of a few score acres to three or four square miles, are characteristic
of the Yorkshire Coalfield.

In Derbyshire, and with less certainty in Nottinghamshire, the fault
pattern is recognisable as an extension of that better defined in Yorkshire,
but local folds of variable pitch dominate the Derbyshire structure.
Faults following the general north-west elongation of the coalfield basin
join with the arcuate groups, and bend eastward to cut across the limestone
area of the High Peak. In Derbyshire there is no strong development of
north-east fractures, and the few faults which break the Permian outcrop
south of Sheffield are either north-westers, or in the south, near Notting-
ham, where they become important, members of the east-west arcuate
system of the southern ending of the Pennines.

In Lancashire transverse faults have cut the coalfield into boat-shaped
strips which taper sharply where neighbouring members of the same fault
series join. About Manchester the master fractures traverse steep
measures in the trough of the wide syncline as it pitches to the Cheshire
Basin, and are effective in reducing the average rate of dip. The 45°
hade of these fractures is exceptional, and must have come by tilting as
displacement continued during and after the deposition of the Permian
and Trias. South of Manchester the fractures bend southwards as they
tail off in the sharp rise of measures in the Cheshire margins of the Peak.
Towards the north the leading fault lines take a double bend, and swing
round first westwards and then northwards to cross the Rossendale
anticline. In North Lancashire, and all the way from Wigan to Todmorden,
the pattern is broken by the great encircling fault group into which both
from north and south the local strip fractures trail. In South Lancashire
to the west of the great Pendleton-Irwell Valley Fault, the north-west
breaks are less powerful and more widely spaced. There are also strike
faults, possibly an arcuate series, in the edges of the Cheshire Basin, and
about Wigan and St. Helens a diamond block pattern, not unlike that of
Yorkshire, has resulted.

The swarm of faults which in North Wales slices the country into
narrow strips range generally north and south, with some eastward
convexity, and cut across the horseshoe folds obliquely. Northwards

15 P. F. Kendall and H. E. Wroot, Geology of Yorkshire, p. 243 (1924).

C.—GEOLOGY 73

from Wrexham, and along the Dee estuary, they diverge somewhat to the
westward, but east of Hawarden they bend as if to complete beneath the
Trias the encircling fractures of the Cheshire Plain. ‘The continuation
of the Bala or Llanelidan Fault tears across the whole Carboniferous
outcrop, as does the east-west fault through the Vale of Llangollen.
North-south faults trail into or branch from these old deep-seated fractures,
by whose repeated movements the wedge of ground between them may
have been subjected to horizontal torsional stress. The ring of fractures
round the slab of Ruabon Mountain is not matched in any British coalfield.
Further to the south, longitudinal faults bend south-westwards, and the
Denbighshire Coalfield ends at east-west cross-fractures which also cut
the Trias.

Within the Cheshire Basin faulting is recorded only in broken outcrops
of Triassic sandstones. The known pattern follows that in neighbouring
outcrops of Carboniferous rocks. At the Staffordshire border the Red
Rock Fault is at once marginal to the basin and longitudinal in the flank
of the Rearers anticline. Across it both folding and fault movements
have been renewed since the deposition of the Trias.

Between the Red Rock Fault of Cheshire and the plateau of the Peak,

fractures which gather from East Lancashire die in the lower flanks of
the steep upfold. Along the crest of that main Pennine fold in Yorkshire
and Cheshire, longitudinal displacements replace the narrow folds con-
verging to it from the south, and form the Pennine anticlinal fault. Out
of this across the Millstone Grit moors, minor branch fractures, cross-
connected, curve away to the eastward in a wide half-circle, to join the
longitudinal series of the Yorkshire and Derbyshire Coalfield.
_ The triangle of country which lies between the Peak of Derbyshire,
the Longmynd and Charnwood, has longitudinal faults which branch as
they diverge southwards in the middle limbs of folds. As boundary
faults in the edges of the exposed coalfields of the Midlands, some of
these are associated with great change of stratigraphical level. They
range with slight obliquity to the strike of pre-Carboniferous structures,
and are in the flanks of late Carboniferous upfolds, which have completed
perhaps the last third of their movements during or since the deposition
of the Trias. Faults developing in the limb of the western anticline of
Staffordshire turn and cross the Potteries syncline obliquely, their
considerable throw reducing the effect of southward pitch. Numerous
adjustment faults, often in pairs, traverse the crests of anticlines in the
North and the South Staffordshire coalfields, and also the coalfield
synclines of South Derbyshire and Leicestershire. Only east-west faults
of the arcuate group in the northern margin of the Staffordshire-Trent
Valley Basin are recognised as breaking across both anticlines and
synclines, or as having direction unrelated to Carboniferous and older
structures.

In his studies of structure in the country between the Longmynd and

_the Berwyns, Wedd has discussed the development of faults by resolution
of horizontal stress to lateral shear or spiral torsion, where compact rocks
have met obliquely an advancing Hercynian crustal wave. Possibly
Structural disposition along other ribs of reinforcement in the pre-

D2

74 SECTIONAL ADDRESSES

Carboniferous floor of the Midlands has located faults of lateral shift,
but details await attention, and the subject is too large for further
discussion here.

COALFIELD DIMENSIONS.

In the foregoing description and discussion of structural pattern,
reference to size has intentionally been omitted. In coalfield engineering
size is the prime factor controlling development, so, for the better applica-
tion of the principles which have emerged in the qualitative analysis,
I shall conclude with notes on the dimensions of those structures in and
about the several coalfields of the province which have been proved, or are
likely to prove, important in industrial planning and development.

The largest and most productive of British coalfields is that of Yorkshire,
Derbyshire and Nottinghamshire, the East Pennine or East Midland
Coalfield, a continuous complex downfold or synclinorium, more than
seventy miles long between Bradford and Nottingham, and forty miles
wide along the river Don. Half or more than half of its total area to
and beyond the rivers Ouse and Trent is buried under Permian and Trias ;
and there, though folds and fault belts from the exposed area can be pro-
jected, real knowledge of pre-Permian structure has only come with mining
exploration and development. Denudation had taken toll of all the up-
raised anticlines before the Magnesian Limestone was deposited, and so
between Leeds and Nottingham the Basal Permian rests in turn on each
and every member of the Productive Coal Measures series.

The Yorkshire Coalfield north of the Don is a comparatively simple
dish structure, cracked and broken by its faults. Its deepest part is the
Frickley trough between Pontefract and Doncaster, where the floor of
lowest Coal Measures lies 4,500 ft. deep twenty miles in from outcrop.
Towards the south the broad swell of the Don anticline ends in the
1,500 ft. deep descent to the Maltby Basin, whose slope is broken en
echelon by the north-easterly Don Faults. Between Doncaster and
Worksop the central part of this South Yorkshire Basin includes a patch
of Upper Coal Measures, and here, with 5,000 ft. of Productive Coal
Measures, is probably the deepest part of any coalfield east of the Pennines.
Despite truncation at the Permian unconformity, some Productive Coal
Measures extend for several miles beyond the Trent.

Contrasting sharply with Yorkshire, where faults are the main dis-
turbers of continuous mining development, Derbyshire is characterised
by steep-sided folds of variable pitch, which undulate the measures in
troughs and arches, nearly, but not quite, high enough to obscure the
synclinal structure of the coalfield as a whole. From the suburbs of
Sheffield, the Ridgeway-Renishaw anticline, 1,000 ft. high, pitches
south-eastwards and bulges the Silkstone Coal outcrop some six miles
east, and continues by Barlborough and Whitwell underneath the Dukeries.
Four miles to the south, it has for neighbour the curving hogsback of the
Brimington anticline, which for eight miles between Holmesfield and
Duckmanton maintains an even crest level, while the syncline of Dronfield,
Staveley and Bolsover, pitching with undulations, descends 2,000, ft.
alongside the steep east-facing flank which at Brimington rises 1,000 ft.

C.—GEOLOGY 75

within a mile. The back slope to the Chesterfield syncline starts immedi-
ately, and, though not so high, is similarly steep. By sudden change of
pitch and oblique cross-faulting, 600 ft. of crest elevation is lost at Hasland,
and about Heath the hogsback becomes a terrace. Southwards the crest
picks up in the 500 ft. high, mile wide, cracked dome of Hardstoft, beyond
which, broadening as it pitches, it flattens out eastward in the swell which
holds the coals at convenient depths across the Sherwood Forest area
east of Mansfield. The Chesterfield-Clay Cross-Tibshelf syncline, two
to four miles wide, 500-1,000 ft. deep, broadens and opens out to the
Oxton-Thurgarton Basin of Nottinghamshire. It is bordered on the
west by the uneven crest which brings limestone to surface at Ashover, and
by the broken dome of Ironville, three miles long and two miles wide, in
which the measures rise 600 ft. ‘This towards the south-east is paralleled
by the wider anticlines of Cossal and the Erewash Valley. Further to the
westward are the local basins of Swanwick, Ripley, and Heanor—this
last two miles wide and 500 ft. deep—which form dimples in the terrace
in which the margin of the coalfield extends south-westwards towards
Derby.

Concerning the extension of fold structures beneath the Nottingham-
shire Trias, more, and more exact, information is desirable. In Derby-
shire no trough or crest line ever keeps an even course, and though on a
small-scale map we may outline in simple curves the information avail-
able from existing pits and boring records, it is not to be expected that
all pre-Permian folds in Nottinghamshire are broad and open. Levels in
the Top Hard Coal between Welbeck and Ollerton rise to the eastward,
and within two miles there is a further steeper rise to Wellow. Explora-
tions along the line from Mansfield to Kirklington show sharp diversities
of level of quite 1,000 ft., and to the south of this line, borings at Farns-
field, Oxton and Thurgarton have proved 500 ft. of red Upper Coal
Measures infolded underneath the Permian. Despite the presence of
Upper Coal Measures in this central trough of Nottinghamshire, because
of southward thinning of the several subdivisions of the series, it is likely
that the deepest part of the Nottinghamshire basin is shallower by at least
1,000 ft. than that of South Yorkshire.

As the East Midland Coalfield fills the broad synclinorium which flanks
the Peak uplift on the east, so the Lancashire coalfields, and whatever
there may be beneath the plains of Cheshire, occupy the deeper downfold
which abuts upon it from the west. Extended Charnwood, being more
rigid, has been given greater elevation than the prolongation of the
Longmynd, but west of this latter under the great oval area which extends
from Manchester to Shrewsbury (sixty miles), and from Chester to Con-
gleton (thirty miles), Carboniferous rocks are so deeply depressed and
covered with ‘Trias as to have remained unproved. A borehole 2,500 ft.
deep at Plumley near Northwich ended in Keuper, and under the central
500 ft. of Lias proved at Prees the basin is probably deeper still.

The fall-off westward from the Peak within the East Lancashire coal-
field to Manchester, is amazingly steep, 7,000 ft. within the six miles of
mining ground between Oldham and Manchester, 3,500 ft. in an unbroken
two-mile dip-slope under Stockport town ; and the whole thickness of

76 SECTIONAL ADDRESSES

the local Carboniferous from the lowest D1 to the zone of A. tenuis has
been exposed and bevelled off in the sixteen miles between Miller’s
Dale and Stockport.

Steep dips in the Manchester corner of the Icahedshilge Coalfield are
half compensated in the pitch of the broad Cheshire syncline by low-
hading, north-westerly throw-back faults, which die in the limbs of the
anticlines on the north and east. ‘The Irwell Valley-Pendleton Fault,
with a throw of not less than 2,000 ft. under the suburbs of Salford, is
about the last and the greatest of the slasher system faults. Beyond it,
with steepness decreasing from I in 3 to 1 in 6 or less, the Lancashire
outcrop of Productive Measures sweeps westward to Wigan, where,
across more faults, it elbows south by St. Helens and Prescot, and so
beneath the Trias and across to Wales. Decrease of dip in Lancashire
is associated with transgression of Productive Measures by Permian or
by overlap of ‘Trias on to Millstone Grit towards the west.

The northward rise of Coal Measures from under the Cheshire Basin
continues to a height greater than their local thickness, which in the east
exceeds 8,000 ft. Across the ten miles wide plateau of the Rossendale
Anticline which ranges east-west from Bacup to Chorley, the beds of
Millstone Grit are almost flat, and stratigraphically only some 1,000 ft.
lower than in the neighbouring crest of the Pennines, from which this
fold is separated by a mile-wide sloping ridge or neck.

The North Lancashire Coalfield is a triangular downfold only some
1,500 ft. deep, tucked in between the Rossendale plateau and the Pen-
nines, and is cut off towards the north-west by the sharp uprise of Millstone
Grit and Lower Carboniferous, which outcrop in the Forest of Pendle
and the lowlands of Craven and the Ribble. This shallow downfold
contains little more than Lower Coal Measures.

The horseshoe folds of Flintshire lie to the east and alongside the
upstanding mass of limestone and Lower Palzozoic rocks of Denbigh and
Snowdonia, much as the folds in Derbyshire flank the east side of the
limestone massif of the Peak. The most easterly of them through
Hawarden, rising and falling transversely 2,000 ft. in about three miles,
is of similar dimensions to the Brimington anticline. By Caergwrle it
turns into the profound pre-Trias disturbance of the Llanelidan Fault,
a branch of the Bala Fault which crosses Wales. ‘The Denbighshire part
of the coalfield is also traversed by a 1,000 ft. fault through the Vale of
Llangollen, but most of the curving fractures which cut the North Wales
coalfield into longitudinal strips are mainly effective in stepping back
steeply-inclined measures as they dip under the Trias of the Cheshire
Plain. ‘The westerly transgression of the Trias in Lancashire is matched
south of Chester by the sudden incoming of the Midland type of Upper
Coal Measures at the line of the Bala Fault. By Wrexham these red beds
increase in thickness, and, overlapping the Productive Measures against
pre-Carboniferous rocks of Shropshire, are probably continuous to Staf-
fordshire and provide a large part of the filling of the southern half of
the Cheshire Basin.

Although it adjoins the Cheshire Basin, there is no suggestion that
North Staffordshire was ever downfolded with it. ‘The utmost that can

C.—GEOLOGY 77

be claimed is that the marginal strip of coalfield between the crest of the
Rearers Anticline and the Red Rock Fault was dragged down as the basin
deepened. The Rearers Fold or Western Anticline of Staffordshire is
interpreted as an acute upfolding of an extension from the Longmynd.
Within the coalfield, mining has proved that the coal seams rise and fall
transversely across it 1,500 ft. within three miles, and that where the fold
is asymmetrical the slight overturn is towards the west. Where, by
Astbury, the convergence at the Red Rock Fault brings Trias against
D2 limestone, the eastward drop into the Biddulph trough introduces
5,000 ft. of measures within two miles. The divergent Eastern or Endon
anticline is a part of the gentler north-eastward rise out of the Potteries
Coalfield trough towards Derbyshire, and is defined eastward by the
steep-sided shallow syncline of Rudyard and the narrow flat-bottomed
Shaffalong Coalfield. The main trough of Staffordshire pitches a little
to the west of south at about 500 ft. per mile, but powerful north-west
faults make the pitch only partially effective. In fifteen miles the coalfield
widens southward from one to fifteen miles, and within its gape there is,
about Newcastle and Trentham, already 5,000 ft. of Productive Measures
overlain by more than 2,000 ft. of Upper Coal Measures. Within North
Staffordshire, Trias transgresses and is banked against every member of
the Carboniferous series, and is itself quite steeply tilted by secondary
uplift of the Rearers and other anticlines.

The southward pitching of the Potteries downfold is towards Newport
and the East Shropshire Coalfield. Inlying outcrops of red Upper Coal
Measures follow the line of the Rearers fold towards the Longmynd, but
spread also eastwards towards Lilleshall, where a sharp uprise of the
Wrekin ridge brings up Cambrian and Carboniferous Limestone, and the
only suggestion of closure of the Stafford-Shropshire basin includes the
great oval of ‘Trias and Upper Coal Measures which extends forty miles
south to Kidderminster and Bewdley, with Stafford and Wolverhampton
on its eastern side. In this downfold, as in the southern half of the
Cheshire Basin, the Upper Coal Measures are thick, but development
from the deep pits already working out westwards from the Black Country
is evidence that almost all its deep downfolding is subsequent to the
deposition of the Productive Measures.

The South Staffordshire or Black Country Coalfield is essentially a
twenty mile long, four to eight miles wide, flat-topped, north-south ridge
or plateau, tilted slightly towards the south and diversified with minor
ridges and hollows, which are re-awakened pre-Carboniferous structures.
From the trend of its minor folds and bounding faults one may guess that
it lines up with the Eastern (Endon) anticline of North Staffordshire, and
that the pitch which brings up limestone under Trias north of Cannock
is responsible for the ending of the coalfield there.

As the Black Country is a plateau, so the Lichfield-Birmingham Trias
area is a steep-sided downfold several thousands of feet deep, widening
southwards and flanked towards the east by the rise to the Warwickshire
Coalfield. Possibly this is the trough of the Cheadle Coalfield continued
southward under the Rhetic outlier of Abbots Bromley, but a local rise
of pitch allows rocks older than the Trias to appear at surface between

78 SECTIONAL ADDRESSES

Walsall and Tamworth, and so divides an Uttoxeter-Burton-Lichfield
basin from the Birmingham-Stratford syncline to the south.

The Warwickshire Coalfield is an open syncline two to seven miles wide,
which widens as it pitches down toward the south. Between Kenilworth
and Coventry it contains over 4,000 ft. of pre-Trias red beds, the thickest
development of Upper Coal Measures known in Britain. It is elevated
somewhat above the level of the Birmingham syncline, from which the
Productive Measures are separated by the crest of Cambrian rock which
outcrops at Dost Hill. ‘Towards the east the Warwickshire Coal Measures
rise sharply with the Nuneaton ridge of Cambrian and Pre-Cambrian,
over and against whose east-facing side the Leicestershire Trias banks
and overlaps. This spread of Trias is continuous with that of Lichfield
and the Trent Valley, but whereas as far as the western margin of the
Warwickshire and South Derbyshire Coalfields the Lichfield trough
contains a great thickness of Red Upper Coal Measures underneath the
Trias, the Cambrian and older rocks of Leicestershire form a diversified
upraised platform and upon it the Bunter is overlapped by Keuper.

Across the Leicestershire platform, shallow folds of variable pitch strike
in a general north-westerly direction towards Dovedale and the conver-
gence of North Staffordshire, in parallel with the south-west edges of the
Peak. On it, en echelon on either side of the south-east-pitching Ashby
anticline, lie the coalfields of South Derbyshire and Leicestershire, each
six or eight miles long and containing about 1,500 ft. of rich Productive
Measures across which the Trias rests directly. ‘The structural boundary
of the Leicestershire Coalfield towards Charnwood is peculiar. For
miles it is a steep fold, broken by a fault, the fissure being occupied by an
igneous intrusion. But as the fault bends round north-westward it cuts
across the pitch of the folds, and, whereas on the coalfield side with east-
ward dip older rocks appear in order northward from under the Coal
Measures, on the Forest side towards the north the Pre-Cambrian is
succeeded by Carboniferous Limestone; and west of Melbourne, where
Millstone Grit is overlain by Trias, this powerful boundary fault has lost
itsthrow. Movements along this fault were completed before the overstep
of the Trias.

CONCLUSION.

In the assembly of this information I have noted many structural
associations the significance of which has not been elucidated. The
plotting of formational thicknesses of strata by zones has confirmed the
Midland Province as a structural unit of deposition. Examination of
Coal Measure stratigraphy has proved its slow development as a Coal
Measure geosynclinal basin which was everted before Permian time. In
cross-section the folding of the Province is duplex in all directions, and
in general it is now a synclinorium with a central lop-sided crumpled
dome. This bifid, asymmetric elevation, which is the central Pennine
fold, divides the eastern coalfield from a western, more deeply depressed,
Trias-filled syncline, and within the fork of double uplift is Staffordshire
and the fingering coalfields of the Midlands.

The narrow folds which compose the western branch of the Pennines

C.—GEOLOGY 79

have for core in Shropshire the worn plexus of Lower Palzozoic rocks
which had been foothills to the Devonian Caledonian Alps. The Charn-
wood core of the eastern limb in Leicestershire is compressed Pre-Cam-
brian and igneous material. Several, probably all, synclines within the
Carboniferous synclinoria are disposed between ribs of reinforcement in
the pre-Carboniferous foundations, which are aligned with the anticlinals
of their cores. The synclinals deepened intermittently but progressively
as the geosynclinal filled ; and though as a whole the Province may occupy
an early downfold in the foreland of the Hercynian alpine chain, its
leading fold-lines are re-emphasised and rejuvenated structures which
in origin are older.

In the beginnings of my study of fold and fault distribution in the
Pennines, I was content to follow custom, and use established regional
names for trend. The East Pennine Coalfield has obvious north-west-
south-east elongation and is continuous to Charnwood. Its longitudinal
folds and faults, though they bend in flowing curves, do not stray far
from the Charnian direction. The north-east-south-west oval of the
Cheshire Basin may be Caledonian, and though it lies athwart the com-
pressed folds of Wales, it is flanked by folds and faults which are
rejuvenated Caledonian structures. The Pennines as a hill range trend
north and south, but north-south folds are only dominant in them for
some twenty miles along the borders of Derbyshire and Cheshire, where
they are bunched between the Caledonian trough of Cheshire and the
Peakland extension of the Charnwood ridge. Continuing with slight
divergence through North Staffordshire, they point southward as a hand
with outstretched fingers, the thumb along the Caledonian folds of
Shropshire, the long fingers following the coalfields of the Black Country
and Warwickshire, and the little finger the Charnian of Leicestershire—
a Midland fan of congruent folds and faults, Caledonian and Charnian,
but on the average ‘ Pennine’ in direction. Northwards also, but in
curves which are asymmetric, trend-lines from the central Pennines open
out, in Lancashire bending westwards but in Yorkshire eastwards, to
return southwards and unite with Charnian structures in Derbyshire and
Nottinghamshire.

Surely in this continuous variation of fold and fault direction within
the type area from which the Pennine trend was named, we see the appli-
cation of regional trend nomenclature reduced to an absurdity. The
Pennine uplift is not a simple group of parallel pressure ridges ; and,
having traced the loosening of its sheaf of structures through the Midlands,
and seen them almost box the compass in the coalfields on either side,
I have concluded that as a synonym for north-south trend of structure
the name of ‘ Pennine’ must disappear. Forced correlation in use of
nomenclature cannot express tectonic virgation, and for precision in
indicating fold direction in the course of this address, I have gone
back to compass-bearing, and for specifying fault-lines I am content to
mention their alignment and locality.

Charnian, Caledonian, Hercynian, are well-established names for
ancient mountain ranges. With reason they are used to designate
structure impressed when those mountain folds were being compressed.

80 SECTIONAL ADDRESSES

During the filling of the Coal Measure geosyncline, local folds of the
Pennine family were lines of delayed settlement, and it seems unlikely
that the Midland Province area was then being compressed. Moreover,
within this area the flanks and crests and troughs of the folds affecting
Carboniferous rocks are broken by normal faults of extension, whose
‘ wants’ or ‘ barren areas’ go far to compensate the shortening of the
base line required for maintenance of continuous cover for the folds.
From mining records we have indications that certain longitudinal faults
had cracked and suffered adjustment as the Coal Measures were deposited,
but the main displacement of all coalfield faults belongs to the time of
Hercynian uplift, after the accumulation of the Upper Coal Measure
Red Beds, and before the planation which made ready for the deposition
of the Permian.

By pattern and by distribution over all the area studied, Pennine and
older and newer faults and folds are so closely associated that it is
inconceivable that they should have come into existence or developed
separately. Lateral compression does not explain the existence of
normal faults along the middle limbs of folds, nor the characteristic
back-step adjustments in the pitch of troughs ; and by stages Pennine
structures must have been both tensional and compressional. Only by
meticulous measurement of the extent of wants and barren areas in
disrupted sheets of sediment which were once continuous, such as coal
seams, could the relative importance of positive and negative strains be
evaluated. It is in the hope that geologists interested in such problems
will seek out and compute the exact geometrical information available
in coalfield mine plans, that I have stressed their interest in the opening
remarks of this address.

SECTION D—ZOOLOGY.

THE MECHANICAL VIEW OF LIFE

ADDRESS BY
DR: J."GRAY)’F.RIS:,
PRESIDENT OF THE SECTION.

EAcu year it becomes more difficult to review the progress which is being
made in the diverse fields of modern zoology, for as individuals we are
necessarily specialists, and we tend to forget that the greatest contribu-
tion which zoology has ever made to human thought was not the result
of a specialised inquiry. The concept of organic evolution was, on the
contrary, a brilliant process of integration from every branch of the
subject, which spread its effect far beyond the confines of zoology itself.
Although it is impracticable to review, even in the most general terms,
the progress of the science as a whole, it is perhaps possible to take stock
of one particular branch of the subject and to discuss its contributions
towards problems which are of some general scientific and human interest.
To an increasing extent, experimental zoologists are borrowing the
weapons of physical chemistry, and possibly the time has come to consider
the general point of view which underlies this type of attack on zoological
problems. What is our conception of the essential nature of the living
organism? Do we believe that the activity of living matter and its
potentiality for change can be expressed adequately in terms of physical
units? Do we incline to the belief that living animals have been evolved
from inanimate matter ?

The aim of experimental biologists is to express the living organism in
terms of its dynamic activities and to consider its structure as an active
and functional machine. It is not infrequently suggested that this is the
province of the physiologist and the biochemist. I venture to think that
this is not the case. Let us consider one of the fundamental tissues of
an animal’s body from the point of view of the physiologist and from that
of the zoologist. ‘To the physiologist, a muscle is all but invariably an
isolated preparation functioning under conditions which are often remote
from those which exist in the body of the organism. Such preparations
have thrown light on the phenomena of muscular contraction, and on the
process whereby the muscle is induced to contract when it receives a
nervous impulse. On the other hand, how many physiologists know, or
are even interested to know, how a frog jumps? ‘To the zoologist a
frog’s sartorius should represent an essential part of the locomotory
machine ; it must be studied im situ and in a way which will illuminate,
not the nature of a muscular twitch, but the behaviour of the animal in
its own natural habitat. It is idle to suggest that there is not much
common ground between physiology and experimental zoology, but,
from a broad standpoint, the conception of the organism as a single living

82 SECTIONAL ADDRESSES

entity is, or should be, the more peculiar attribute of experimental
zoology. To some extent it is true that we cannot understand the full
potentiality of a frog’s musculature until we have a precise knowledge of
the dynamic properties of a muscle fibre. The fibre is, or appears to be,
a less complicated system than the muscle which is working in situ, and it is
tempting to start with the simpler unit and to pass on to the more compli-
cated systems by a series of apparently logical steps. To a significant
extent this argument has appealed to experimental zoologists. We start by
being interested in the organism as a whole, but soon decide to concentrate
on one specific organ. Eventually the organ gives place to the cell, and
thence it is an easy step to the bottom of the ladder where we gather
together to discuss the structure and the functions of living material in
terms of atoms and molecules. This point of view is of peculiar signifi-
cance, for, by means of a common language, zoologists, physiologists,
chemists and physicists have developed, and are continuing to develop,
a fruitful field of work. It is, however, a field on which it is dangerous
to tread without adequate safeguards. It is all too easy to over-simplify
a problem and to ignore the fundamental properties of living matter ; it
is all too easy to make artificial pearls and cast them before appreciative
swine. It is, nevertheless, in this field that the foundations of all biology
eventually may rest, and perhaps the time has come when we should
review, as impartially as we can, the relationship between the animate
world of animals and the inanimate world of the physical chemist.

The application of physical and chemical methods as instruments of
biological research needs no defence. Its justification is seen in the
results which have been obtained. During the past twenty-five years
our knowledge of the living cell, of the respiratory process, and of the
mechanisms of nerve and muscle fibres has been placed on a high level
of precision by methods which are identical in type with those used for
the study of physico-chemical processes in inanimate systems. In so far
as these results bear on their own peculiar problems, zoologists must
accept them, and they must influence our conception of the organism as
a whole. By using appropriate methods we can define the physical
properties of living matter, but there always remains the possibility that
the living organism may possess properties of another nature which
cannot be defined in physical units.

When, as biologists, we are asked to define our conception of the nature
or origin of living matter, we must confine ourselves to views which are
based on the facts of observation. The more accurate and extensive are
our observational data, the more precise and the more satisfying will be
our conclusions. The material with which the biologist must deal is of
extreme diversity and complexity, and we naturally turn to the physical
world for standards of measurement which will help us to arrange our
material and to place our observations in a reasonable relationship to each
other. As I understand it, the age-long discussion between the mechan-
istic and vitalist schools of thought turns on how far we believe—on the
basis of observation—that the facts of biology can be sorted out into an
harmonious and satisfying series without invoking conceptions which are
found to be unnecessary in dealing with the facts of observation within
the physical world. The centre of gravity of the problem shifts from

D.—ZOOLOGY 83

time to time, but for many years two concepts appear to have influenced
the discussion to a marked extent. Firstly, the synthesis of organic
compounds from inorganic material suggests that there is no fundamental
difference between the type of substances found in or made by living
organisms and those which are found in or formed by purely inorganic
systems. Secondly, the inferences drawn from the theories of organic
and terrestrial evolution suggest that these two processes are funda-
mentally similar and involve the operation of fundamentally comparable
forces. Not a few biologists have in fact maintained that living matter
“ owes its origin to causes similar in character to those which have been
instrumental in producing all other forms of matter in the Universe ’
(Schafer, 1911). This was the view of Ray Lankester, who elaborated a
series of intermediate steps whereby the first type of living organism was
evolved from inanimate matter. I imagine that not a few modern
zoologists would tolerate, if not actually accept, a similar view. From
this it is often, but not always, implied that there is a fundamental
continuity in the properties of all matter and that the only properties
which a living organism can possess are those which can be defined in
physico-chemical terms.

Opposition to such a view has not been wanting. In 1912 Sir Oliver
Lodge replied to the views set forth by Sir Edward Schafer and stressed
the existence in organisms of a principle, not easy to define, which is
absent from the world of physics and chemistry. From time to time the
battle has been renewed, and both biologists and physicists have taken an
active part. It is a curious but pertinent fact that the most far-reaching
mechanistic views have been and are being put forward by biologists, the
more cautious views or the vitalistic views are held by physicists and
chemists. IT. H. Morgan, the author of so much fundamental work in the
realm of pure biology, states in a recent book: ‘ When, if ever, the whole
story can be told, the problem of adaptation of the organism to its
environment, and the co-ordination of its parts, may appear to be a
self-contained progressive elaboration of chemical compounds.’ Even
Dr. Barnes accepts the spontaneous origin of living matter as a natural
phenomenon : ‘ If we could reproduce in the laboratory the conditions
which existed upon the earth when life first appeared we should cause it
to appear again.’ On the other side, we find physiologists (whose experi-
mental contributions to science are of a severely physico-chemical nature)—
J.S. Haldane and A. V. Hill—regarding the purely physical outlook with
distrust. It all seems rather like Alice in Through the Looking-glass.

The exponents of the mechanistic view have been curiously indefinite
in the exposition of their opinions. I confess that a study of the more
popular works on physical science leads me no nearer to an understanding
of those ‘ causes ’ which, according to Sir E. Schifer, ‘ have been instru-
mental in producing all other forms of matter in the Universe’; nor
have such chemists as I have had the good fortune to meet been very
familiar with the concept of ‘ co-ordinated series of self-regulating and
self-propagating chemical reactions,’ such as are described by Prof.
Hogben. According to Prof. Hogben, we may look for a complete
solution to the nature of life within a mechanistic framework, fortified by
the conviction that ‘ The mechanist has a cheerful attitude to knowledge

84 SECTIONAL ADDRESSES

and refuses to capitulate to the fear of the Unknown: the vitalist, a
sadder but not necessarily a wiser type, finds balm in the limitations and
failures of human effort.’ So far as I have been able to observe, it is by
no means obvious to note in the writings of Dr. Haldane, Prof. Hill,
or the Bishop of Birmingham those signs which are usually associated
with a contemplation of the failures of the human intellect.

The mechanistic view of life seems to imply that if, at any instant of
time, we were to know the precise distribution of the matter and energy
which are present in an organism, we would have a complete under-
standing of all its properties. In other words, the behaviour of living
systems can be completely defined in terms of laws which are fundament-
ally similar to those which describe the behaviour of inanimate systems.
It is of interest to consider how far this conception is based on the results
of observation, and how far it rests on a rather indefinite foundation of
intuitive belief.

Let us look for a moment at the theory of the evolution of animate
from inanimate matter. From a biological point of view it seems at
first sight reasonable—it seems to be the natural conclusion to draw from
the process of evolution which characterises the world of living organisms
and the universe as a whole. The theory gives us a comfortable feeling
of continuity of thought. Let us look at the position from a physical
point of view. As a physical phenomenon it is undoubtedly possible for
a living organism to have been evolved spontaneously from inanimate
matter. It is also possible for a stone to leap spontaneously from the
surface of the earth. ‘These things are possible, but are they probable ?
To obtain some estimate of the degree of probability it may be useful to
consider the phenomena of Brownian movement. As biologists we are
very familiar with the spontaneous motion of very small particles lying
in a liquid medium. We believe that each excursion is due to a difference
in the intensity of molecular bombardment along the axis of movement.
The smaller the particle, the greater is the chance that a molecule of water
will hit the particle without a simultaneous encounter from another
water molecule coming in an opposite direction. Water molecules are
moving at random, and the direction of collision is one of chance—the
larger the particle, the greater is the chance of an equal average intensity
of bombardment from all directions at any given moment. Now since all
water molecules are free to move in any direction, the actual number of
molecules moving in a common direction at any given moment will vary
from moment to moment, and the same is true for the molecules of a
pebble on the ground. It is possible for all the particles in a suspension
of Indian ink to move simultaneously in one direction. It is also possible
for all the molecules of a pebble to perform the same feat—but in view of
the very large number of other possibilities, the probability of simultaneous
co-ordinated movement is very, very small unless we are dealing with
very small numbers of molecules. The degree of smallness can be judged
by putting ten black and ten white balls into a box and drawing them
out at random in lots of ten. The probability that we will draw ten
white or ten black balls is five times in one million. If we increase
the numbers and draw one hundred balls, the probability of drawing
balls all of one colour is so small that we say that anybody who

D.—ZOOLOGY 85

expected it to occur must be slightly demented. In the case of the
Brownian particles, the chances of ten contiguous particles moving
simultaneously in the same direction are even smaller, and in practice we
sum all this up by saying that as long as we are dealing with reasonably
large numbers of molecules, the events which we observe are the most
probable events, and we assume that the improbable events do not in
fact occur. On this arbitrary but effective basis rest most, if not all, the
laws of physics and chemistry which we apply to the study of living matter.
We say, in effect, that stones do not leap spontaneously from the earth
because the chances against it are so extremely great ; similarly we state
that the pressure of a gas is always inversely proportional to its volume,
except on a negligible number of occasions. ‘The organisation of the
simplest living organism is clearly more complex than that of a stone or of
a motor car, and it carries out processes which are infinitely more complex
than the sorting out of black from white particles. What, in fact, is the
probability that any chance distribution of molecules should lead spon-
taneously to the dynamically active mechanism of the living organism ?
Would any serious credence be given to the suggestion that a motor car
or even a footprint on the sands came spontaneously into existence without
the intervention of directive forces? Why, then, should we accept the
spontaneous origin of living matter ? It is possible, but it is so improbable
that, if considered as an observable phenomenon, in any other sphere of
human thought it would be discarded as a figment of a deranged brain.
Why should biology accept a standard of probabilities incomparably less
satisfying than that of other branches of knowledge ?

Left to himself, the chemist does not seriously consider the spontaneous
origin of proteins from CO,, water, and simple salts, nor does the physicist
admit the spontaneous origin of organised machines. Biology itself pro-
vides not one shred of observational evidence to support the spontaneous
origin of living matter in the world to-day, and yet not a few biologists
are prepared to postulate the spontaneous origin of intermediate stages
between the living and the inanimate worlds—to my mind, the spontaneous
origins of these stages represent physical events which are so improbable
that we cannot describe them in terms of ‘ laws’ which only apply to
events of an entirely different order of probability: if these inter-
mediate stages actually occurred they must be classified as miracles,
not as ‘ natural’ events. We may be told that in past ages, events which
are now very improbable were in fact of quite frequent occurrence. As
scientists we cannot accept this statement without some assurance as to
what were the nature of the conditions which made the origin of life
inevitable or even probable. The distribution of energy and of matter
in past epochs may have been different ; but if such conditions produced
the living organism, is it not strange that every attempt to reproduce
them in the laboratory have completely failed ?

We can put the facts in another way. Within the physical world all
systems appear to move towards the state of greatest probability, and the
events which take place within a dynamic system are those which tend
to destroy structure and not those which elaborate it. Is there any evi-
dence which suggests that, within the physical world, a dynamic machine
has spontaneously come into existence? ‘That such an event might

86 SECTIONAL ADDRESSES

happen is true, but has it, in point of fact, ever occurred under the observa-
tion of mankind ? Unless a positive answer can be given to this question,
the belief in the spontaneous origin of living matter seems to be a negation
of the principles which underlie scientific thought.

If we decline to accept the spontaneous origin of living from non-living
matter, there is no particular reason why we should hope to express all
the properties of an organism in terms of physical laws ; we might just
as reasonably try to express physical phenomena in terms of biological
conceptions. It seems more logical to accept the existence of matter in
two states (the animate and the inanimate) as an initial assumption.
Some properties are naturally common to matter in either state, and it is
therefore legitimate to study the so-called physical properties of living
matter ; but just as the fundamental concepts of physics are based on
observational facts, so those of biology must conform to the same condi-
tions. The physicist is not concerned with the origin of inanimate
matter ; he is content to investigate it as he finds it. The biologist must
likewise accept the living state as he finds it and not allow his science to
rest on theories, however spectacular or attractive. It is not easy to
define Life, but in practice most people will admit that matter in the living
state possesses characteristics which are fundamentally different from
those of inanimate objects.

The central characteristic of living matter is its state of organised
dynamic structure. This is obvious in all the larger forms of animal life,
but it is equally true in so-called ‘homogeneous’ protoplasm. This
important fact emerges from the study of such cells as the eggs of echino-
derms and molluscs. From a biological point of view, the eggs represent
not only very remarkable chemical laboratories, but also systems which
are capable of transforming themselves spontaneously into highly differen-
tiated organisms. A study of the physical properties of the eggs shows,
conclusively I think, that the cytoplasm consists of a fluid matrix in which
lie the granules which are visible under the microscope. ‘The viscosity
of the fluid matrix has been measured by observing the rate at which
granules or particles move through the cytoplasmic matrix when exposed
to a given intensity of centrifugal force—and the value so obtained is
confirmed by observing the velocity at which such granules redistribute
themselves spontaneously by Brownian movement. We conclude from
such observations that the cytoplasm of the cell with all its complicated
biological properties possesses, in the aggregate, the general properties of
a liquid and not of a solid. Similarly, the immature nucleus of the odcyte
has the general properties of a fluid, and yet it proceeds spontaneously
to form the highly differentiated system seen during meiosis. Within the
fluid system of the cytoplasm or the nucleus, single molecules or aggregates
of molecules will distribute themselves at random (just as do the granules
we can see through the microscope), unless these molecules are subjected
to suitable restraint. When we try to picture the cell or the nucleus as a
complex chemical laboratory, it is by no means easy to visualise the type
of forces which are necessary to hold the various particles or molecules
in their proper position relative to each other. Were the matrix of the
cell of a solid nature, the problem would be much simpler. It may be
suggested that the application of centrifugal force destroys the real struc-

D.—ZOOLOGY 87

ture of the egg, so that under natural conditions the cytoplasm possesses
the properties of a solid rather than those of a liquid. If this be the case,
we are faced with the striking fact that the centrifuged egg develops
normally, so that any structure which is destroyed by centrifugal force is
very rapidly regenerated spontaneously when the force ceases to be
applied—such powers of spontaneous regeneration are unknown in the
physical world. The evidence is, however, against the view that the low
viscosity of cytoplasm is more apparent than real, and the suggestion is
entirely inadmissible in respect to the nucleus for, in this case, the fluid
nature is revealed without the application of any force other than gravity.
If we base our conception of the structure of protoplasm on the facts
revealed by physical methods, we must imagine a system of very great
chemical complexity and of very great potentiality for spontaneous self-
differentiation within a fluid framework. Protoplasm cannot be regarded
as a fluid crystal, for it possesses dynamic properties which are constantly
expressing themselves in a variety of ways. Two general conclusions
seem possible. We may assume that the molecules of protein and of
other substances in the cell are so arranged in respect to each other that
they constitute a highly active chemical system, and that the mechanism
which maintains this molecular orientation is such that individual mole-
cules or groups of molecules are able to move in the way necessary to give
fluid properties to the whole system but not free to distribute themselves
at random. If this be the case, the whole cell must be regarded as a
fundamental unit, whose organisation is such that its structure cannot be
destroyed by centrifugal force. So far such an organisation is not known -
in dynamically comparable systems of an inanimate nature—we must
regard it for the time being as an attribute peculiar to the living state,
and as an attribute which is as fundamental as any of those employed for
the description of inanimate matter. An alternative view is, however,
possible.

We may look on a mass of protoplasm as a very fine emulsion, the funda-
mental units of which are extremely-small. If we assume that the pro-
perties of the system as a whole are essentially those of each individual
unit, then we have no great difficulty in seeing how mass disturbances fail
to affect the properties of the whole system. The displacement of the
particles by diffusion, or other causes, throughout the mass of the system
will not influence the fundamental properties of the cell or nucleus if these
properties are essentially those of the small individual units. The con-
ception of the living cell as an aggregation of a very large number of funda-
mental units is in keeping with the fact that small fragments of egg-cells
retain some at least of the properties of the whole system. It is also in
keeping with the very small dimensions (as in viruses) within which
living phenomena have been observed. ‘There is some evidence to support
the view that single differentiated cells also represent aggregates of very
small living units. For example, a suspension of the spermatozoa of the
sea-urchin Echinus in sea-water, after a period of maximal activity, enters
a phase of declining mechanical and respiratory activity. If we consider
a single spermatozoon during this period of senescence, we find that the
intensity of its mechanical and respiratory activity declines in a way which
is characteristic of a population of units which differ from each other in

88 SECTIONAL ADDRESSES

their viability—the single cell behaves, in fact, as though it represented a
large population of much smaller units of activity.

If we accept the view that the fundamental unit of life is extremely
small, we can see that mechanical disturbances throughout a suspension
of such units may induce no very far-reaching results. The conception
of protoplasm as an emulsion of small vital units suspended in a fluid
system is perhaps the most satisfactory picture we can derive from available
facts ; but it breaks down when we try to think of the mechanism whereby
the cell differentiates itself as a whole—for here we must postulate some
form of co-ordinated relationship between individual units. If, however,
we shelve this difficulty for the moment and accept the general conception
that ‘ vital’ properties are associated with very small units of structure,
a variable number of which are normally aggregated together as a suspen-
sion to form a single cell—it is obvious that we must exercise very great
caution in the application of the statistical laws of physics in describing
the properties of the fundamental units of life. ‘The only legitimate laws
are those applicable to the behaviour of single units of activity. So far
as I can form an opinion, such determinate laws have not yet been forth-
coming. I am inclined to think that the intrinsic properties of living
matter are as mysterious and as fundamental as the intrinsic properties
of the molecule of a radio-active substance : when the physicist can tell
us why one particular molecule explodes and why another goes on existing,
I venture to think that we can begin to consider the possibility of defining
the fundamental properties of living protoplasm in physical terms. At
present, however, the physicist seems more inclined to define physical phe-
nomena in terms of biological conceptions, for, according to M. Poincaré
and others, ‘modern physics is presenting us with apparent examples
of spontaneity and foresight.’ For the moment, however, we must con-
clude that although physical methods have provided important facts con-
cerning the state of living material, they have not as yet thrown much light
on its fundamental properties.

If we now turn to the behaviour of an echinoderm egg-cell after fertili-
sation, it is again possible to define certain physical characteristics. We
can observe changes in the mechanical properties of localised regions of
the cell and of the nucleus, but we have no adequate picture of how these
events are initiated. We are, however, acutely conscious of the high
regulative power of the whole system. If we destroy, by mechanical or
other means, the astral radiations seen in the cell at the anaphase of mitosis,
these structures are regenerated in what we can reasonably call the right
place at the right time. The whole process of nuclear and cell divi-
sion, when regarded impartially as a physical event, represents an orderly
process of formation of structural elements—and has physical attributes
similar to those which characterise the formation of an inanimate machine
from unorganised material. All attempts to define the mechanism
whereby this orderly process of segregation is initiated, in terms of physical
units, are, in my opinion, fanciful. It is more reasonable, at present, to
regard such powers of effecting an orderly distribution of material as an
intrinsic and fundamental property of living matter. The operation of
this power no more involves disobedience of physical or chemical laws
than does the manufacture of a motor car.

D.—ZOOLOGY 89

After cell division has been in progress for a very short period the cells
which are formed by an egg of a sea-urchin begin to show a marked
difference in arrangement from those of a polychet worm. At the end of
the third cleavage cycle, the cleavage pattern of a sea-urchin is seen to be
orthoradial—the cleavage furrows between the upper quartet of cells lie
immediately over the furrows of the lower quartet. In the polychet,
however, the arrangement is spiral, not orthoradial, for the furrows of the
first quartet of smaller cells lie between the furrows of the basal quadrant
cells. By experimental means we can force the sea-urchin egg to
divide in a way characteristic of the worm. ‘This is done by increasing
the centripetal force which tends to press one cell against another, and we
can show that the arrangement in the polychzt worm is that assumed by
a system of spheres so arranged as to pack together within a minimum
volume. The arrangement in the polychet is essentially the same as in
the egg of the mollusc or polyclad turbellarian. What conclusions can
we draw? The classical interpretation associates the similarity in the
cleavage pattern with a common phylogenetic relationship. From an
experimental point of view one is inclined to a totally different view—viz.
that the similarity in form is due to a similarity in the intensity of the
mechanical forces operating on the cells. In the worm, mollusc, or tur-
bellarian the centripetal pressure acting on the cells is sufficient to force
the cells to occupy a form in which a maximum volume is enclosed by a
minimum area of surface. In the sea-urchin this is not the case. The
pattern as such plays no essential réle in determining the fate of the egg.
A spirally cleaving sea-urchin egg develops normally ; it does not develop
into a worm or mollusc. The mechanical view is peculiarly attractive,
but it has one serious objection. When the dividing cells of a molluscan
egg rotate so as to reduce their centripetal pressure to a minimum, a rota-
tion to the left is as effective as a rotation to the right—and on each occasion
one would expect an equal number of rotations to the left as to the right.
In a few cases this seems to occur, but in others the left-handed or right-
handed pattern appears to be due to determinate and not to chance forces—
for at any given stage of cleavage all the eggs show a rotation to the right
or to the left. That this phenomenon is correlated with mechanical
asymmetry is quite probable, and it may be that the nature of this
asymmetry will eventually be observed. In the meantime, however, we
seem to be faced with the fact that a mechanical condition which is satis-
fiable in either one of two ways, is, in fact, only effected in one way.
Does it not look as though a disturbance has occurred in the probability
values of the system ? It is as though we were presented with a bag of
black and white balls—and each time we pick out the black balls and reject
‘the whites. Before we attribute a determinate behaviour to the cleaving
egg-cell we must, of course, make certain that the chance of left- or right-
handed cleavage is mechanically of equal probability. Up to the present
we can only say that no mechanical difference is apparent—and in the
absence of such definite evidence we are free to interpret the facts either as
evidence of a deficiency in our knowledge of the mechanics of the system,
or to the possibility that there exists in the egg a potentiality which makes
certain events more probable than they could be in inanimate systems.
One is tempted to suggest that the cells of a molluscan egg turn one way

go SECTIONAL ADDRESSES

or another for intrinsic reasons: an event starts inside the cells—quite
independent of any external influence—just as in the exploding molecule
of a radio-active substance. In other words, the cell has an individuality
of its own—which is free from the limitations of statistical laws. ‘The
field of cell cleavage is full of possibilities for future inquiry, and would
well repay more intensive study.

We must, however, now turn to certain wider aspects of experimental
embryology, which are best observed in the eggs of the lower vertebrates.
Within this field the progress of the past twenty-five years has been
spectacular. By grafting fragments of the developing embryo of the newt
into positions which they do not normally occupy, it is possible to get
a picture of embryological development which is incomparably more
satisfying than any hitherto available. We know that there exists in the
egg a region or regions which are capable of influencing the fate of the
neighbouring tissues. Each of these so-called ‘ organising centres’
determines in some way the process of tissue differentiation: the raw
material is, as it were, full of potentialities for differentiation, but the
exact line which will be followed is affected by the organisers. Once the
process of differentiation has reached a critical stage, the fate of the tissue
is determined ; before that period, the raw tissue can be built up into
a variety of different structures. Quite recently it has been shown that
such organisers are curiously non-specific—an organising centre from
a chick can induce organ-formation in the undifferentiated tissue of
a mammal ; and, still more remarkable, the organising centre does not
appear to lose its activity after death. These facts are admittedly be-
wildering—but two points seem to emerge quite clearly. Firstly, the
potentiality of the organism to control its fate is established at a very early
stage. If we carry back the facts of experimental embryology to their
beginning, we see that the essential biological difference between the
egg of the sea-urchin and the egg of the mollusc (Dentalium) is a difference
in the relative time at which development becomes independent of
organising centres—in the sea-urchin it is relatively late; in Dentalium
it occurs before the egg begins to cleave. By accepting the concept of
an organising centre the facts of embryology thus appear to arrange
themselves in an orderly manner—and this, after all, is the supreme test
of any scientific hypothesis. The second great inference to be drawn
from these facts is the present inadequacy of expressing the facts in
physico-chemical terms. The only point at which the phenomena
seem to be susceptible to physical analysis is the apparent activity of an
organising centre after death. This would suggest that the action of an
organiser is either mechanical in its nature or is comparable to that of
a trigger which releases specific lines of development from unorganised
tissues of high potentiality. By physical methods we can hope to elucidate
the physical attributes of this trigger action, but I do not think that the
facts, so far as they are known at present, present a very convincing argu-
ment in favour of a mechanistic hypothesis. From a broad standpoint,
the obvious conclusion we must draw from the facts of experimental
embryology and from the regeneration of lost parts is that the organism
behaves as a co-ordinated system even in the very earliest stages of its
development ; and that this co-ordination is of a degree of complexity

D.—ZOOLOGY gI

quite unknown in the physical world. It is important to notice that this
complexity of structure is essentially of a dynamic nature. We may say,
if we feel disposed, that it is a system which is physically unstable—but
where in the chemical world do we find such unstable systems acting in
such a way as to build up and not to break down a highly complex
structure ?

It must be noted that the organising centres of the egg possess physical
properties by virtue of which their activity may be influenced by external
conditions. The development of a frog’s egg is affected in a definite
way by a gradient of temperature applied along particular axes, and we
know that the egg will not develop in the absence of atmospheric oxygen.
Can we not say with equal truth that the production of a motor car would
also be affected by keeping one end of the factory at 30° C. and the other
at o° C.? Would it not also be affected by depriving the system of
atmospheric oxygen? ‘The effect of such conditions can be measured
in terms of physical chemistry, but do they throw any real light on
the type of organisation necessary for the production of a car or of an
organism ?

Within the sphere of embryology we can recognise, more clearly than
in any other biological science, the two main attributes of living matter :
(1) an inherent complexity of structure, and (2) a dynamic potentiality
of initiating events which either do not occur at all or only occur very
infrequently in inanimate systems.

Similar inferences can be drawn from another great sphere of experi-
mental inquiry—namely, a study of the relationship between the fully
grown organism and its physical and chemical environment, but in this
case we tend to concentrate on the physical events rather than on the
potentiality of the organism to control or vary its own activities. For
example, many animals have the power to elaborate a peculiarly beautiful
chemical machine for the conveyance of oxygen to the tissues. In such
cases our main objective is a description of the physico-chemical properties
of such respiratory systems, and as these are clearly susceptible to statistical
treatment they can be described in terms of known physical laws. So
also, in the adult animal, the phenomena of co-ordinated behaviour are
clearly associated with the central nervous system, and the physical signs
of this co-ordination are rapidly being analysed by appropriate physical
methods, but it is important to remember that the phenomena of regulative
control are present long before the central nervous system has been fully
differentiated, and are not infrequently detectible in the undivided egg.
If we are fully to understand the mechanisms of respiration and of co-
ordinated behaviour we must bear in mind the manner in which the
fully formed systems come into existence, and not concentrate exclusively
on the more obvious physical characteristics of the fully developed
mechanisms.

Let us now try to summarise the position. The only laws which
physics has provided for an analysis of biological phenomena rest on a
Statistical basis ; they only apply to systems which contain a large number
of participating units and only describe natural phenomena in terms of
probability and not of absolute truth. If we accept these laws as a means
of describing the behaviour or the structure of an organism, we must

92 SECTIONAL ADDRESSES

accept the conventions attached to the laws and agree to ignore such events
as are improbable although they may conceivably occur. From this
point of view, the spontaneous origin of living from inanimate matter
must be regarded as a highly improbable event, and as such can be assumed
not to have occurred. Similarly, the development of an organism from
so-called undifferentiated protoplasm involves processes which are entirely
without parallel in inanimate nature. So long as this state of our know-
ledge persists, it is dangerous to assume that the statistical laws of physics
can satisfactorily describe all biological events. Our knowledge of the
physical and biological properties of living matter suggests that the
fundamental unit of structure is extremely small, and that it contains
potentialities for change which are unique in the universe. These pro-
perties we must accept as fundamental axioms of our science which may
or may not prove (in the future) to have their parallel in the physical
world. It may seem presumptuous for the biologist to set up postulates
peculiar to his own sphere; it would be more fitting perhaps for him to
accept, with medieval humility, the assumptions of his physical brethren.
One wonders, however, at times whether the concepts of intrinsic
organisation and of emergent evolution are entirely absent from modern
physics. Even if this is not the case, we can fortify ourselves by the
knowledge that physics has from time to time changed its fundamental
assumptions with advantage to itself and to the world. Those biologists
who are inclined to accept the views I have ventured to put forward
may be encouraged by the remark of Prof. Niels Bohr which very
recently came to my notice. He says: ‘ The existence of life must
be considered as an elementary fact that cannot be explained, but must
be taken as a starting-point in biology, in a similar way as the quantum of
action, which appears as an irrational element from the point of view of
classical mechanical physics, taken together with the existence of the
elementary particles, forms the foundation of atomic physics.’

Not infrequently the physiologist can restrict his interest to the physical
properties of isolated organs—the origin of which does not concern him.
The zoologist, on the other hand, knows that the beautifully adapted
mechanism known as an ‘ organ ’ was evolved from a system unlike itself
and may, in turn, initiate something new. For this reason, he cannot
afford to forget what may be called the ‘ intrinsic potentiality of the living
organism.’ He may or may not be able to use this conception as a
guide to more adequate observations, but it should be constantly in his
mind. Experimental zoology can be divided into two types of study :
(1) the investigation of the physical and the chemical properties of living
organisms ; (2) a study of the intrinsic potentialities of living matter,
revealing as it does a co-ordination of events which is without inani-
mate parallel. In the first type of work we must use each new weapon
which the physicist can give us. In the second type of work, however,
biology must be the mistress and not the servant of physics or of chemistry
—she must make her own foundations, and build on them fearlessly,
prepared to change her views, if need be, but not prepared to force the
wine of life into bottles which were designed for use in the simpler and
less intoxicating fields of chemical science.

SECTION E.—GEOGRAPHY.

GEOGRAPHY AS MENTAL EQUIPMENT

ADDRESS BY
THE RT. HON. LORD MESTON, K.C.S.I.,

PRESIDENT OF THE SECTION,

Most of us believe that every branch of human knowledge wisely
pursued—every true science, in fact—provides training for the intellect,
furniture for the mind, and solace for the spirit. That this claim can
justly be made on behalf of geography is the argument of an amateur
observer in the present paper. ‘To hear geography described as a
science at all comes not without an element of surprise to many in our
older generation, whose education followed normal lines in the third or
the early fourth quarter of last century. To them geography was the
dreariest part of their school curriculum, an arid catalogue of physical
features and figures. ‘To-day it presents itself as a systematic grouping
of facts, with their causes and their effects, fascinating in their variety and
vividly human in their interest. In this sense it is a new science, so new
that many of its devotees mournfully speak of it as the Cinderella of
sciences. It is, says Dr. H. R. Mills, a synthetic science—and most
synthetic products are relatively new—deriving its data largely from
geology, meteorology, anthropology, and other bordering sciences. Its
youth, however, is among its charms ; and for its entry into the fraternity
of sciences it has two illustrious sponsors. One is the gallant succession
of explorers of the earth’s surface, whose enterprise, though it never
ceases, has reached a definite stage of accomplishment with the opening
up of Arabia, the surveys of the Antarctic continent, and the flight over
Everest. The other is the growing body of students engaged on the
human aspects of geography, in tracing out the relations between
man and his physical environment, which constitute its philosophic
basis.

Being anxious to avoid all shadow of controversy, I must here pause
to register the claim, pressed by Professor Burrows among others, that
geography is not young but very old, as old at least as Ptolemy, a mother
science which has given birth to astronomy, botany, archzology, as well
as the other specialised sciences already mentioned. Which of these
two views is the more orthodox may be left for another day. What is
common to them both is that geography is a function of a number of
_ other sciences ; and one of the difficulties attending its future may quite

_ possibly be that of establishing boundaries between it and them, whether

94 SECTIONAL ADDRESSES

they be lineal descendents or merely neighbours. Even the layman knows
how puzzling it is—and often how unnecessary—to mark out frontiers
between adjoining sciences. There will often, probably always, be an
undefined borderland, into which both neighbours stray on their legitimate
rounds, though working generally, unlike trespassers across political
frontiers, in mutual helpfulness when they meet. Such a borderland
must of necessity surround geography ; and in some directions indeed
it seems to be more extensive than the science, when thoroughly estab-
lished, will require. All that need be postulated at present is that, in
order to be a competent geographer, it is not imperative that you should
first be a skilled astronomer, geologist, and historian. Your value as a
teacher and as a student will be enhanced by some acquaintance with
these and the other bordering sciences; but to the ordinary man or
woman with no such equipment, geography will still offer a vast and
self-contained field of intelligent interest. It is from the standpoint of
this ordinary man or woman that I would invite you to survey with me
some portions of the field, to consider how they serve the purposes of a
true science, and then to enquire how this science can be advanced (the
word is taken from the British Association’s title) so as to enter more
intimately into the cultural outfit of future ordinary men and women
like ourselves.

lp

To many there is a particular attraction in that remote corner of the
field where geography stands disclosed as a science, not of immutable
but of ever-changing data, as a study not of a solid earth and everlasting
hills, but of a surface amply responding to Lucretius’ doctrine of flux.
We mortals of the day live, it is surmised, in an inter-glacial epoch. It
is only a fraction of time since this green and pleasant land of England
was buried deep under an ice-cap, such as Admiral Byrd saw with some-
thing akin to terror, when he was flying in the Antarctic. It may be
only another fraction of time before all that we see around us to-day
is crushed into oblivion by another glacial visitation. How many such
changes and catastrophes in the past will the record of geography unfold
when we are able to read it? Meanwhile we can only guess at some of
them ; picture after picture of an earlier world-surface passing through
the mind, without any pretence at chronological sequence. We can
travel, for example, from the ice-bound Britain of which we have just
been thinking to the African Sahara, then a moist, warm expanse of open
grass-land, abounding in flocks and herds, and peopled by men primitive
enough, but yet with a startling artistic skill in rock drawings. Or, instead
of wandering south from the glaciers of Central Europe, we can turn
east to the other gigantic ice-fields, which then lay over the uplands of
Asia and segregated, in their own home territories, to develop on their
own separate lines, the progenitors of some of the chief racial families
of mankind to-day. On our way we should pass that ancient central
Asian ocean which is now representated by shrunken fragments in Lake
Aral and the Caspian Sea. If, following the same line of thought, we
try to cast our mind still further back, we get into a sphere of endless

E.—GEOGRAPHY 95

speculation in picturing some of the tremendous changes which have
taken place in the distribution of land and sea since the Tertiary era.
The union of England and France by a river valley instead of a stormy
Channel would be a relatively modern feature in the landscape ; so would
the land-bridges across the Mediterranean, of which only the broken
piers remain in Malta and certain other islands. Working backwards,
the student would see North America severed from South America by an
ocean which has long receded ; and Africa divided in two by another
great stretch of water. As if in compensation, he would find the Asiatic
continent running unbroken through Malaya into Borneo and Java,
until it faced, across a comparatively narrow waterway, the ancient
Australiasian continent, which embraced Celebes, New Guinea, their
adjacent archipelago and our modern Australia. To depict in the
imagination a world so constituted, is given to few of us; but I would
suggest one help, however inadequate, in carrying the fancy back into the
Tertiary age. Climb the Puy de Déme—now an easy enough task—
on a clear day, and let the eye travel slowly over the mass of clear-cut
volcanic cones which surround you on almost every side, ranging from
mountains 4,000 feet high to mere pimples on cultivated fields. Then
imagine all these at work, belching out flame and fume, lava and sulphur,
the sky darkened by smoke and dust, and the earth a maze of roaring
furnaces. It is from such an inferno that time has evolved the smiling
landscape of Auvergne to-day.

Out of any attempted survey of this particular part of the field, or
what we might call pre-historic geography, two reflections emerge.
The first is that, at this phase, geography is entirely dependent on
other sciences, especially geology, and cannot yet claim an independent
existence. The second is that, at this phase, it has hardly any conceivable
interest for us except in relation to the movements of life—and primarily
of man—about the globe. Amid these forgotten seas, those wastes of
glaciers and zones of volcanic fire, there seem to have been stray enclaves
of habitable land. It is those oases which form the focus of our interest
to-day, with the help which they give in explaining the sharply differential
characteristics of certain races of the human family. Or, if the mind
turns rather to the puzzling similarities which have been detected in
widely scattered races, it may find, in the hypothesis of old land-bridges
over otherwise pathless oceans, support for the theory of early migrations.
Did the primitive Mongol, after long isolation in eastern Asia, succeed
in drafting some of his tribes across the Bering Strait to become the
progenitors of the American Indian? Did the human family which we
call the Alpine race, imprisoned through a long glacial epoch in Turkestan,
ultimately force their way into Russia, the Balkans, Mesopotamia and
Southern India? Similarly, did the stock which scientists try to dis-
entangle as the Nordic, after protracted incubation behind the Ural
mountains, issue through the melting ice into the Baltic coasts and finally
dominate the Indo-European situation? Or was the conformation of
the ancient continents such as to permit the aboriginal negroes of Africa
to wander, almost all the way dry-shod, the enormous distances through
Asia to Australia or into Melanesia? These are gigantic assumptions ;

96 SECTIONAL ADDRESSES

but, as we know, they are not regarded as impossible by the school of
anthropologists, who trace all mankind to one ancestral home. ‘There is,
of course, another theory, but the controversy is not within the ambit of
my topic to-day. It may be that the march of our science will yet test
both hypotheses more thoroughly than is feasible at the present state of
our knowledge. There is at any rate little question that in the subject
of these rival views lies the chief interest of modern man in pre-historic

geography.
II.

That constant change is the law of geography, as of life, is an axiom
which calls for no dramatic flights of fancy into a remote past. Change
is all around us to-day; and to many lay students of geography the
visible and superficial changes, as opposed to the vaster geological move-
ments, in the face of nature have a peculiar attraction of their own.
Picturesque details are always with us. One of us, for example, may
have examined the treasures collected by Sir Aurel Stein as evidence that
vast tracts in Central Asia, which are now no better than sandy deserts
were, not so very long ago, the home of a rich and cultured people.
Another may have served in Mesopotamia, and seen how the traditional
Garden of Eden has been transformed into a malarial waste of marshes.
A third, staying at home and spending a summer holiday on the South
coast of our own country, may have reflected that Roman galleys once
sailed from the beach where he stood across to the Thames through
waterways which are now the cornfields and hop-gardens of Kent.
These half-obliterated watercourses are for ever catching the observant
eye : they abound across the railway line from Amiens to Boulogne, and
their well-worn pebbles are turned up by the plough in countless English
denes and combes.

The agencies of change, however, are tireless rather than picturesque ;
and their very assiduity makes them the fitting subject of study and
experiment. Probably the easiest of them all, from the ordinary student’s
point of view, is the wastage of mountain ranges. Look, for example,
at a hill such as the Saleve outside Geneva, and no trained eye is needed
to see how it is steadily slipping into the plain below. A vivid picture
rises to my memory from another continent. It was one morning, after
two days of torrential rain, at a hill station in the outer Himalayas. A small
plateau, on which rested a military cemetery amidst a glade of deodars
and rhododendron trees, had broken away during the night from the
rock behind and dropped, as a solid mass, into the valley 1,000 feet
below. There it lay, with the trees and the tombstones still standing,
athwart the stream which ran through the valley and which was rapidly
banking up into a temporary miniature lake. Some houses in the valley
had been engulfed in the landslide, and several lives lost. By this time
no doubt the scar on the hillside has healed, and part of the debris—
disintegrated deodars, graves and ruined homesteads—is helping to build
up a patch of new rice land somewhere in the Sunderbuns. The incident
opened my eyes to the evidence everywhere of similar attrition which has
been going on unremittingly since the mountains came into being ; and

ses) eee

E.—GEOGRAPHY 97

in India, with its fine cadastral records, there are potentialities of measuring
the erosion of the hillsides and the corresponding formation of deltas.
In most maritime countries another possibility of quantitative study
exists in the relentless crumpling of the earth’s surface which is slowly
raising some coast lines and depressing others. ‘These, after all, are only
casual examples of the knowledge which is capable of being gleaned in
this part of the geographical field—the part commonly described as
physical geography. And, incidentally, it seems less than justice to
stigmatise this branch of our science as synthetic. It relies for help
on research in climatology, meteorology, oceanography and so on; but
its problems have a dignity of their own, and a clear place in the general
pursuit of physical knowledge. The surface of our lithosphere ; its
response to the influences which beat upon it—rain, winds, tides, ocean
currents, etc.; the processes of denudation, accretion, desiccation,
fertility, and so on, these offer material for study and the systematic
assemblage and analysis of facts which justify the claim I set out to urge
on behalf of geography as a whole. The philosophy and purpose of
physical geography will be discussed later ;. they are in close accord
with the reflections in which we indulged as we meditated on pre-historic

geography.
irr

Meanwhile let me turn to another aspect of geography, more familiar
to most of us laymen because it bulked so largely in our early education—
that side of it which is associated with history and is sometimes called
political geography. In the dark ages of last century to which I am
always alluding, it hardly merited so imposing a name; for the theme
of our ordinary school maps was mainly the division of the land into
national and administrative areas ; and the acme of absurdity was reached
when we were set to draw maps of England, with its counties a mosiac
of gaudy colours, but often with no place for rivers, mountains or even
towns. From that imbecility it seems a long journey to a modern
historical atlas, such for example as the admirable compendium edited
by Mr. Ramsay Muir. But the relation of geography to history is still
far from sufficiently intimate in our ordinary teaching of either subject.
This would be true even if it referred only to the intelligent use of
maps as adjuncts, so to say, of visual instruction in history. To take
an example, consider how few persons of a normal standard of education
could sketch, with the haziest approach to accuracy, a picture of the
Europe with which Cromwell had to deal, or contrast it with the Europe
which Napoleon started to reconstruct. Then think how little terrors
such a question would have for anyone who had glanced at two half-
pages in Mr. Ramsay Muir’s atlas. On one side he would have seen,
the date being that of our English Restoration, three of the great con-
tinental powers of that day—Sweden, Poland and Turkey—holding
between them a solid block of territory stretching from the Arctic Ocean
to the Mediterranean, which shut Russia off from the sea and out of
Europe, dominated Prussia and dwarfed all the modern States of Central
Europe. On the opposite half-page he would have observed that, when

E

98 SECTIONAL ADDRESSES

Napoleon came on the scene, Poland was dismembered and no longer
on the map, Sweden and Turkey were maimed and shrunken, and the
three great realms of Russia, Prussia, and Austria were overshadowing
Europe. Let a person of the most moderate intelligence get those two
vignettes into his head, and the framework for nearly a century and a
half of crowded history is at his command.

It is of course by no means only, or even mainly, of its cartographic or
diagrammatic functions that we think when we try to press geography
into closer touch with history in our educational system. Geography
and its first cousin economics have very largely shaped history, and
without some knowledge of them the study of history is liable to be both
arid and misleading. ‘That is a truism to which it will be convenient to
return later. A consequence of it, however, at which it is worth while to
glance in passing, is that geography has much to teach to those who are
actually making history to-day, and equally merits attention by those who
fill the useful réle of critics of the makers of history. We are frequently
told that a little knowledge of geography would have been of advantage
at Paris while the Peace Treaties were being negotiated in 1919-20.
Possibly so; but a bowing acquaintance with geography would not be
out of place in the multitude who find it so easy to pull the treaties to
pieces. I say nothing about the Polish corridor. For various reasons we
may fear or even dislike it; but geography jogs our memory as to the
long history of Poland’s wide access to the sea, and as to the isolation in
which East Prussia was born and prospered. A less simple issue is
raised by the energetic and expensive propaganda now being carried on
for a revision, on ethnological and geographical grounds, of the new
boundaries of Hungary. The ethnography of the Succession States of
the old Habsburg Empire may well puzzle the wisest of us; but the
framers of the Treaty of ‘Trianon were certainly not ignorant of geography.
It is one thing to claim that the broad plain between the Tatra range and
the Danube eastward of Bratislava is Magyar in culture. It would have
been a very different matter to include that fertile area in the borders of
Hungary ; and the prosperity which has come to Bratislava and Komarom,
in spite of racial grievances, is some tribute to the geographical basis of
the new boundaries. Further east, still along the Danube, there were
racial arguments for leaving a slice of Carpathian Ruthenia in Hungary ;
but the result, to quote Dr. Seton Watson, would have been ‘ to cut the
natural communication between a long series of valleys, to cut off the
hinterland—one of the poorest and most neglected districts of the old
Hungary—from the plains which produce the food, to leave Ruthenia
without railways, and to destroy the railway connections between Czecho-
slovakia and Roumania.’ These are minor but pregnant instances of the
value of the large-scale map in the making of history.

Having now glanced at several sections of the perimeter of our field,
we have found in each of them one definite pointer towards the centre of
interest which is common to them all. Prehistoric geography attracts
us by reason of its mystery and romance; but the romance lies in the
fact that the grim powers of nature—oceans, volcanoes, sinking con-
tinents, towering glaciers—were all co-operating in the slow preparation

E.—GEOGRAPHY 99

of a surface for our globe on which life can exist. When we come nearer
historic time, we think of geography in terms of a medium in which at
least primates can multiply and move, and in which ultimately homo
sapiens can establish abiding places for his different families. If we then
turn to physical geography, we are thinking ‘mainly of how the forces of
nature can be observed and calculated in their action upon the habitable
globe ; in other words, in what measure they are tending to make it
more endurable or less endurable for human beings. Lastly, when we
come to political geography, we are concerned frankly with, and only
with, the distribution of the habitable area of our planet among the
various groups of men and women who call themselves nations. It is
the human aspect of geography which is permanently in the background
of all its sections; and the essential scientific value and interest of
geography lies in the part which it plays in preparing and furnishing a
home for mankind. Of what interest or value to us would be the geo-
graphy of the Milky Way, or even of the Moon, so long as we know of no
life which it would influence ? and is not our sporadic excitement about
the geography of Mars aroused solely by our curiosity as to whether the
changes observable on that planet are, or are not, the work of hands and
intelligences somehow akin to ours ?

LN,

Thus we arrive at what seems the predestined centre of the field, at
geography which has no adjectival label, and which one would hesitate
even to call human geography, lest there should thus be conveyed some
suggestion of implied antithesis. It is the study of geography as the
science of man’s physical framework, his home, the material for his
existence. Seeing that all life lives together, what we are really thinking
of is not man alone, but animals and plants as well. By the inclusion of
these, however, the area to be surveyed becomes so vast that I cannot
touch to-day on those parts of the field which are of special interest to
the zoologist and the botanist. They have their own entrée to our
science, but in a sense so specialised that the ordinary amateur geographer
has no qualifications for discussing it. Taking human geography
therefore as exactly what its name indicates and no more, we find in its
lay-out the whole study of the relations between man and inanimate
nature. If this round globe had a voice which we could hear, and if it
cared to use our language, it would probably describe our theme as the
study of a tiny and prolific parasite upon its skin. We naturally think
better of ourselves. Our study is one of actions and reactions; it in-
vestigates the reasons why the multiplication and distribution of man is
influenced by geographical features, and on the other hand the methods
by which man, reacting to those features, endeavours to modify them.
It is the whole problem of environment and adaptation. As that
eccentric but stimulating writer, Hendrik Van Loon, expresses it, ‘ the
roots of any given people are situated deep in the soil and in the soul.
The soil has influenced the soul, and the soul has influenced the soil.’

As on all other subjects on which students feel deeply, sharp differences

100 SECTIONAL ADDRESSES

have arisen over the treatment of this human geography, mainly focus-
ing, it would appear, on the order of precedence between environment
and adaptation in time-space. It would be unbecoming, without know-
ledge of the arguments, to enter this arena; but I submit that some of
the disputants have been a little severe in pouring scorn on the early
exponents of the theme. Old Jean Bodin, it may be, did not see much
beyond his nose when he divided the world into the cold zone of the
stupid but vigorous democrats, the hot zone of the intelligent but lazy
victims of theocracy or any other despotism, and the temperate zone
occupied by happy France and its ideal monarchy. But at least he did
some mapping out in his own way, just as Strabo had done in his, and he
set men thinking. Then Buckle, if I may miss all the great names in the
interval, comes in for a good deal of mild sarcasm. It is true that his
famous chapter upon the influence of nature on man is marred by
curious lapses ; as, for example, when he professes ignorance of the cause
why all the mighty rivers in the New World flow to its eastern coast, and
none of them to the western; or again, when he lumps together the
peoples of Sweden and Norway, and of Spain and Portugal, as being * all
remarkable for a certain instability and fickleness of character.’ But, if
occasional odd sayings like these are overlooked, there is much in his
general argument with which at least one school of modern anthro-
pologists must be in sympathy. That there is any radical or original
difference between the various races of mankind, he regards as ‘ alto-
gether hypothetical,’ and the existing discrepancies he endeavours to
trace to the influences of climate, soil and food. It must be admitted
that, as his analysis proceeds, the promised explanation of racial differences
evaporates, but there survives a review of political and social tendencies,
in which there is little to challenge, especially when we remember that
he is dealing exclusively with early societies. In such societies, he argues,
the accumulation of wealth is largely a matter of climate and soil; with
wealth comes leisure, and with leisure comes civilisation. Hence civilisa-
tion appeared first in those lands where nature unaided begat wealth—
in India, Egypt, Peru and Mexico. But where food is abundant and
cheap, population tends to increase unduly, and the standards of life
deteriorate. ‘Thus, in countries where climate and soil are favourable
and food is ‘ provided by nature gratuitously and without a struggle,’
wealth has always abounded, but it has been unequally distributed ; and
consequently there has been no just division of political power, no
democratic spirit, but only despotism in the upper, and ‘ contemptible
subservience ’ among the lower orders. Progress accordingly has been
insecure and society unstable ; natural decay has set in, and the invasions
of sturdier races have completed the tale of doom.

As a philosophic survey, there seems no patent absurdity in all this,
though it sounds somewhat elementary now ; and the argument is relieved
by telling patches of colour, as when Buckle describes how the alluvial
wealth of Southern Asia transmuted the roving savages, the wandering
shepherds of Arabia into the cultured monarchs of Cordova, Delhi and
Baghdad. An even finer passage is that in which he distinguishes Brazil
from other countries where nature is generous with her gifts. In the

E.—GEOGRAPHY 101

flow and abundance of life, he writes, ‘ Brazil is marked above all the other
countries of the earth. But, amid this pomp and splendour of nature,
no place is left for man. He is reduced to insignificance by the majesty
with which he is surrounded’; and so on. Finally we reach an argu-
ment which is independent of any purely literary charm; it comes when
Buckle leaves climate, soil and food, and speculates on man’s sensitiveness
to what he calls the aspects of nature. They fall into two categories,
those which excite the imagination, and those which address themselves
to the understanding. In countries where the former abound, in the
shape of mighty mountains, earthquakes, or devastating pestilence, man
is conscious of his own unimportance, and the powers of nature fetter
his will. Where, on the contrary, nature is gentle in her manifestations,
man regains confidence and exercises authority. Buckle takes India and
Greece as types of the two extremes. In India the tropical grandeurs
and perils have led to an uncontrolled ascendancy of the imagination,
which runs riot in its literature, its art, and its theology ; fear governs
men’s minds and the gods are monstrous. In Greece, at the opposite
end of the scale, nature is friendly, and the imagination quickly loses its
supremacy. Reason gains dominion, superstition dies, and the enquiring
and sceptical faculties of the understanding are cultivated. A touchstone,
Buckle suggests, is to be found in hero-worship: the canonisation of
mortals soon became a recognised part of Greek religion ; while in India
the whole tendency was to widen the distance between men and their
deities. From this pregnant series of contrasts he concludes that “ every-
where the hand of nature is upon us, and the history of the human mind
can only be understood by connecting with it the history and the aspects
of the material universe.’

V.

In this summing-up we may all agree. Generalisation is a seductive
and flowery meadow, but it is studded with pitfalls, and into several of
_ these it may be that Buckle, with all his erudition, stumbled. Neverthe-
less is there not wide scope for investigation into the rdle which geography
plays, at first in shaping religions, and afterwards in maintaining morals ?
This very contrast to which we. have just been listening between Greece
and India is full of suggestions. Wherever it was situated (and this
probably we shall never know), there was assuredly one common ancestral
home for the main gods of Olympus and the earlier occupants of the
Indo-Aryan pantheon ; on this point the evidence of philology is con-
clusive. The possibility is that, in the region where they were first
worshipped, those divinities were the great natural phenomena, which
man, as soon as he learned to think, watched with wonder and reverence :
the Sky-father, the Earth-mother, the Sun, the thunder, the fertilising
rain-cloud. Most of these survived into Greek mythology, but it was
very largely mythology. They had come down from some ancient cradle
of the race as a part of its culture. They were honoured by shrines, by
sacrifices, and offerings on festive occasions ; but they were never the
object of fear. In that land of clear air and sparkling sea, there was no
gloom about the temples. The deities in time were personified, moving

102 SECTIONAL ADDRESSES

like men and among men, with similar passions to men. The Greek
artists fashioned their statues in the form of men and women, supreme
only in their grace and beauty. Poets narrated their conversations and
sang of their quarrels. Gradually, alongside the formal national rites in
their honour, the impish popular wit began to fasten uponthem, Jupiter’s
infidelities, Juno’s jealousies, Mercury’s petty larcenies, Vulcan’s
stupidity, Cupid’s mischief, finally scattered the idea of awe, and the
Greek mind was liberated to reason out for itself the problem of existence
and the canons of right living. In all this geography undoubtedly had
a hand. Her peculiar mountain system had divided Greece into a
number of separate little communities, allies at times, enemies at others,
but always vigilant for their physical fitness in the defence of their home
cities. Her extensive and sheltered seaboard brought to her doors all
the busy intellectual life of the Mediterranean world. With athletic
bodies, sane and alert intellects, her children had no room for super-
stitous fears of the unknown, and they laid the foundations of modern
scientific thought.

Into India virtually the same theogony had been imported by the Indo-
Aryan invaders of two or three millennia before Christ. But into how
different a world they came. Isolated by gigantic mountain ranges and
stormy oceans from her neighbours, India had very little living contact
with the thoughts or interests of other lands. Within her borders the
workings of nature were hard and often cruel. Drought and famine at
periodic intervals swept off their thousands and their hundreds of
thousands. Diseases attacked the land in mass formation ; so did flood,
earthquake, tempest, everything against which man is powerless. Beasts
of prey swarmed, and no humble home was safe from snakes whose sting
was inevitable death. ‘The landscape, too, had its times of grimness, as
those of us know who have lived in the plains through Indian hot weathers.
The hills were awe-inspiring rather than friendly, and the forests held
particular dread for those early simple people. In this environment the
gods soon lost all human touch. The first Veda had addressed them in
stately and reverent hymns ; but its strains were foreign to the soil and
were never renewed. The Hindu pantheon became a huge gallery of
godlings and goblins, in which the heavenly beings of the primitive
Aryan stock got for the most part changed into objects of terror to be
propitiated and, whenever possible, avoided. The cult of Krishna, it is
true, shows how the human heart yearns for a divinity which is consoling
and kindly ; but Sri Krishna’s observances are only a brief interlude in
the gloom of India’s religious life. The representations of the gods in
statuary and painting are deliberately monstrous, as if to mark their
distance from man, and to our western taste almost always repulsive. In
tracing this connexion between the rigours of nature and the severity of
men’s creeds, I would not be taken as ignoring that side of India’s mind
which strives daringly to plumb the unknowable. In pure metaphysic it
is possible that India has something to teach to lands where geography
is kinder; but here again the vague mysticism of her speculation has

some analogy to the vastness of her plains and the inaccessible sanctuaries
of her hills.

E.—GEOGRAPHY 103

If we turn to two other great religions, Judaism and Islam, is it
altogether fanciful to surmise that geography has been directly concerned
in their development ? Their central idea is the oneness of God, not
as a universal soul, but a solitary, omnipotent and jealous power. We
are told by scholars that Judaism in origin was the triumph of one tribal
god, Jehovah, over a number of other rivals. It is not implied, as I
understand, that the individual tribes were polytheistic, though each
had its own name and attributes for its own protecting deity. Be that
as it may, the conception of unity was paramount among the Hebrew
stock; and it was militantly re-stated by Mahomed. Why did
unitariansim so fiercely possess the mind of Arabia, to the exclusion of
the more complex creeds which permeated the rest of Asia? The
Semitic spirit will hardly furnish the explanation, because it has not
always and everywhere been incompatible with idolatry. It is in the
daily life of the desert-dweller that we must look for the reason, in its
solitude, its stern simplicity, its concentration of thought and purpose
on the business of the moment. ‘There is no room for the luxury of
polytheism, and no time ; furthermore, the unity of surrounding nature
postulates the same quality in the Creator. With other religions the
case may not be so straightforward ; and I am not sure how far it is
possible to pursue the same line of thought into the great reforming
movements of the world. Buddhism, for example, presents a curious
problem, with its complete disappearance from the land of its birth and
its fervid acceptance in other geographical areas. Or, coming back to
Europe, we have the familiar theories as to the spread of Calvinism and
the present-day distribution of Protestantism and Roman Catholicism.
The ground, however, is too delicate for an amateur geographer. There
is also very little left of the raw material for such enquiries. Our modern
creeds cross oceans and capture new territory, just as our modern lan-
guages do, with more reliance, let us hope, on their intrinsic merits than
on geographical considerations.

VI.

The last section of the survey through which we have been scampering
is human geography on its material and practical side. Here we study
nothing less than the eternal conflict of nature versus man,—the rdéle
which Michelet assigned, though not convincingly, to history. Often it is
a real conflict, with times and places at which nature defeats man, with
others at which man gains, or seems to gain, the victory. Often, and
more often as civilisation advances, it settles down into bouts of diplomacy,
where man endeavours to get on terms with nature. Geography, if he
understands it, helps to tell man where defeat has hitherto been final,
where victories can be snatched, how relations of mutual aid can be
established. Moralising in a general way on individual instances, it
would point to the Alpine barrier, which at first protected Rome from
the north, later admitted the barbarians, and then for centuries compli-
cated Italy’s connection with Central Europe, until engineering skill
bored holes through it and cleared away many of the old troubles. Or
it would tell how the Appalachian barrier for long dictated the lines of

104 SECTIONAL ADDRESSES

colonisation in North America, pinning the English settlements down
to the. Atlantic coast, and leaving the Mississipi valley open to the enter-
prise of the French. Or, harking much further back, it would point
to an older barrier, the tumbled hills and impenetrable forests running
across the Indian peninsula parallel to the Nerbudda valley, which
protected, it may be for a thousand years, the Dravidian culture of the
south from the invasion by Indo-Aryan influences. As types of whole
nations which have had to wrestle with nature, it might single out Spain
and Holland. Spain, after the melting away of its oversea dominion and
the decay of its prestige in Europe, unconsciously surrendered to its
geographical position. Sheltered behind the Pyrenees, it showed a
disposition to cut itself out of European politics ; partitioned into un-
connected sections by intractable mountain ranges, it has allowed the
same habit of local dissension, which rendered it an easy prey to the Moors,
to divide its people and weaken its national life once more. Holland,
on the contrary, typifies a stout refusal to surrender to nature. Its
people, undismayed by losing their former command of the High Seas,
turned upon their own sea and ejected it ; so that they have transformed
into a rich agricultural and industrial land what was once a vast expense
of tidal marsh and fen, and they are still doing it.

These are only haphazard incidents in the age-long contest. ‘The
chief purposes of human geography are to record how the forces are
arrayed to-day, and to help in the intelligent estimating of how they
will sway the future. The materials for its task are the extreme diversity
of nature on the one hand, and the unity of man on the other ; for it
must deal with the family of mankind as a whole, and with their needs
as a whole: a home, food, and clothing, and the labour on nature’s products
by which they earn their shelter and their means of existence. As it
stands on the threshold of its modern task, geography has to sound its
trumpet and call in the support of its bordering sciences, geology,
climatology, botany and all the others, but most especially of one which
has not yet been mentioned ; for only with their help can it succeed.
How it will prosper in its endeavour is the responsibility of our educa-
tionalists ; and it is no small satisfaction to know how far they are prepared
to go in giving our new science its appropriate place in the teaching
curricula of our educational system. But in that direction there is still
much to be done. For, in order to fit geography more usefully into
the mental equipment of educated men and women, it seems that the
problem is to secure a new emphasis on the physical features of our
globe, so as to give them an organic and dynamic, rather than a tabular
and static, value.

If we think of the world as an abiding place and study the geography
of any one country first from that point of view, it does not satisfy us to
know the names of its chief towns and rivers, or of its mountains, capes,
and bays should it happen to possess any. Each city has some
individuality, and a dossier of its own, into which we should like to
peep. ‘There is something to tell us how it came into existence, whether
it is growing or decaying, what keeps it together, what is its racial, political,
or commercial importance ; in short, why men built it, why they live in

E.—GEOGRAPHY 105

it, and what they do. We should also, if time permits, be interested to
know something of its story in the past, what men in it have fought for,
whether it has often changed hands or creeds, and such personal details
as to why we call it Oslo when it was once Christiania, or why old St.
Petersburg is now Leningrad or whatever its name is to-day or may
happen to be to-morrow. When we get outside the cities, the countryside
also has its tale. Is it agricultural ; and if so, what is the pressure of
population on it; or is it mainly a land of manufacturing activities ?
How much of it is unoccupied, and why ; has it been converted into a
home for grouse and stags instead of hardy crofters, or has man been
warned off by malaria or the tsetse-fly? If the next chapter of our
study is the sustenance which the country offers to man, we find a great
deal to discard in our old authorities, and much investigation to be
undertaken with a fresh mind. In the matter of climate, for example,
we must get rid of our smug statistics of average rainfall and mean
temperature—among the most misleading data which pseudo-science
has ever invented. The climate of the country which we are surveying
will require a more intelligent, though not necessarily an elaborate,
estimate. So with the soil, and the fertility of its different areas ; its
irrigation if the rainfall needs supplementing, and the facilities for
artificial irrigation. ‘Thence to the produce of the soil is an easy step,
though here also discrimination is advisable. Rice may be grown which
the indigenes can eat, but which it would be useless to export because it
is unsuitable for milling ; or cotton which its growers can use, but with
so poor a staple that no manufacturing country will look at it. The
agricultural output as a whole needs more sympathetic treatment than
our text-books often give it. ‘The same may be said about the mineral
products, especially coal ; and the careful student will watch the opening
for the development of electrical energy, which we must continue to get
from either fuel or water until Faraday’s great-great-disciples discover
how to extract it from sunbeams or the circumambient ether. Another
step takes us to the manufacturing features of the country. What are
its industrial centres? To what extent are its manufactures rooted in
the soil, or due to other special causes, or merely fortuitous ? It will be
increasingly important to discriminate between industries with definite
local advantages (like shipbuilding on the Clyde) and industries at the
mercy of foreign competition (like jute in Dundee, and now cotton in
Lancashire). Is the necessary labour available among the adjacent
population ; are wages high or low ; can labour be imported if required ?
Finally, how does nature help or hinder the marketing of the
output ?

The last question brings up the whole problem of transport, the third
point of view from which the geography of the country has to be studied ;
and here the co-operation of nature and man has a sphere particularly
its own ; especially in the navigation of great rivers, a subject on which
the ordinary reader is often profoundly ignorant. Whether nature co-
operated, or was defeated, in the matter of the Suez and Panama canals,
is little more than a dialectic point. ‘The important fact is that transport
is (as indeed it always has been) in a state of transition ; the advantages

E2

106 SECTIONAL ADDRESSES

which it confers are constantly being bestowed here and confiscated there ;
and a vigilant geography is possibly more essential at this point than at
any other. It is true, says Chisholm, that man cuts through an isthmus
if it is in his way; but geography determines what isthmuses to cut,
and deploys the local conditions which man must understand before he
decides to act. Railways are amenable to the same set of considerations ;
so are harbours: geography has a powerful say in the alinement of the
former and the location of the latter. Many generations may not pass
before transport by air has revolutionised all this, and left our railways
and highroads as curiosities in the same category as our English canal
system to-day. But, like the free extraction of electrical energy, this
is a contingency which we can leave geography to deal with when the
moment arrives. Meanwhile it should be teaching us something of what
has been done to make transport easier and shorter, and pointing the way
to further advance in the same direction.

If commerce and industry, the lifeblood of the progressive races of
mankind, are becoming more and more dependent on sound geographical
knowledge, is it heresy to step down for an instant, and suggest that
geography might also help man to enjoy his life? In one of the latest
manuals on the United States, it was refreshing to find an enthusiastic
page about the Yellowstone Park and the Grand Cafion. Might it not
be possible, in text-books on our own land, to hear a little about the
Scottish highlands, or the Welsh mountains, or the Cumberland lakes ?
And generally, would it be practicable, without poaching on Baedeker,
to touch here and there on the beauty spots of the world, or even to
mention, in passing, a great picture-gallery or a famous shrine ?

Let me, with apologies for this lapse into esthetics, return to the country
in which we were asking geography to tell us something of its residents,
its primary products, its industries and its means of transport. It is not
the only country in the world ; and by the time that we have pursued
similar investigations for its neighbours, we shall have reached two
incidental conclusions of some importance. One is the intimate alliance
which must be established between geography and economics. ‘They
have become sister sciences. On its commercial side geography’s kin-
ship with economics is just as close as it is with geology on the physical
side ; the only difference in the relationship being that, whereas on the
structural side of its work geography builds upon data provided by
geology, on the human side it may very well, without loss of self-respect,
engage itself in furnishing reliable material for the economist. The
second conclusion is borne in upon us as we study the movements of
population, the changes in industry which are liable to throw whole
divisions of the labour army out of employment, the competition for
markets, and all the struggle for existence on the earth’s crust. They
suggest that geography may become a more useful agency than hitherto
for locating danger-spots in the world from the standpoint of international
peace. There are plenty of Naboth’s vineyards in our midst, and an
intelligent study of geography should help to identify at least some of
them, and to warn in time whatever organisation the nations may entrust
with the policing of our unruly humankind.

E.—GEOGRAPHY 107

VII.

I must now bring my rambling tale to a close. It has been a plea,
not to a converted audience like this, but to a sceptical and on the whole
an older generation, that geography is entitled to the full honours of
a science. To the objection that it has to borrow so much of its raw
material from other sciences, the answer is that the material is already
there for the service of human knowledge generally, just as mathematics
is at the service of astronomy, or physics and chemistry at the service of
geology. Moreover, there is none of the bordering sciences which is
prepared to undertake the tasks and fill the rdle of geography. Its
positive claim is that, while always indenting freely on existing sources of
knowledge, it is building up for itself, sifting and classifying, a body of
knowledge which is found nowhere else, and which has a unity of its own
and a purpose of its own. ‘This process, we claim, raises it definitely to
the dignity of a distinctive science.

Its unity is not impaired by the variety of its interests, some of which
we have been cursorily surveying. Like many a family that is only lately
ennobled, it can assert a respectable antiquity. It may not be able to
produce maps showing the exact conformation of the earth’s surface in
the ages when it was occupied by the mammoth and Neanderthal man ;
but, from the teachings of geology, it can deduce approximately the position
of land, water and ice-caps at the time when the races of mankind were
in their cradles ; and, keeping abreast of geological change, it can guess
the routes of their subsequent migrations. It can bring the moulding of
the habitable globe, with reasonable certainty, down to our own day ;
and the careful geographer can record the surface changes which are now
going on, and estimate their force and their pace. Alongside of those
changes he will examine the physical influences which make certain
portions of the earth suitable or unsuitable for human occupation, as well
as those which facilitate or obstruct the intercourse of mankind. Geo-
graphy will then carry us into the detailed investigation of the settlements
of mankind, with reference more particularly to their national groupings
and needs. Here, hand in hand with economics, it will explore the
manner in which the various countries of the world are used for man’s
habitation, and under what conditions of life and labour and productivity
they are occupied. Finally, geography in its hours of leisure may tell
us where to see the supreme glories of nature, and in its more serious
moods it may warn the League of Nations where to expect those causes of
economic and territorial friction which imperil world peace.

Through all this diversity runs a golden thread of unity, in the human
interest which binds the whole story together. Geography is essentially
the science which treats of man’s home, and the steady adaptation of the
surface of our globe to be his dwelling-place and his workshop. And
just as geography has its essential unity, so also is it transfused by a
common purpose, the study of the relations between man and nature.
If to this it can add—and why not ?—the ambition to help in improving
those relations, then we complete its scientific purpose by associating with
ita moral aim. Thus, at the risk of wearisome repetition, it is claimed

108 SECTIONAL ADDRESSES

that we have the assemblage, the testing and the analysis of facts, with
a unified direction and a definite practical aim, which amply respond
to the definition of ascience. And to the three criteria which the ordinary
man expects science to satisfy, geography presents a ready face. As
a training for the intellect, it does not rely on balances, test-tubes,
mathematical formule, and the like; but it answers Dr. Whitehead’s
desideratum in being a process of measuring rather than of classifying ;
and it is an adequate school for exact observation and wise deduction.
As a contribution to the solacing spirit of humanity, its work in removing
misunderstandings between peoples and forestalling friction may become
increasingly valuable. And as a mental equipment it yields to none of
the kindred branches of knowledge. Apart from its importance to the
traveller and the student of international affairs, it is essential to the
economist. Not less so to the historian; you have only to compare
Trevelyan’s account of Marlborough’s campaigns with most other narra-
tives of the same events, in order to see how an acute appreciation of the
geographical setting of warfare is powerful to convert arid prose into a
living picture. Lastly, without geography the statesman is liable to
grievous error; and it is indispensable knowledge to the practical
industrialist and the planner of big business.

Feeling as we do on the subject, can we expedite the advancement of
geography to its proper place in our educational system? It was for the
purpose of evoking discussion on that question that I ventured on this
address, speaking as one who learned nothing about geography in youth,
and who realises the handicap. Since Oxford and Cambridge formally
recognised the subject forty years ago great strides have been made.
Perhaps the most encouraging advance is the growing attention to regional
studies, to what Dr. Bryan calls the cultural landscape. It is a landscape,
as he shows us, upon which each one of us looks out every morning of our
lives ; and its very familiarity may have led in the past to its neglect.
But on the steady advancement of this regional work, if we can only get its
methods properly taught, will depend the future of the science. Mean-
while the foundations for it have to be laid in the elementary and secondary
schools, and it is here that we still find blind spots in the national outlook
on the advantages of the systematic teaching of geography on modern
lines. Ata recent exhibition held in this city a remarkable demonstration
was given of the remedies which are being applied ; and in other directions,
especially in the admirable character of some of our newer text-books,
there are signs of better things coming. The time is ripe for a combined
forward move ; is it possible for our meeting here to provide the necessary
stimulus ?

In conclusion, may I offer this Section E my most grateful thanks for
the high honour they have done me in electing me their President for the
year, and my heartfelt apologies for the poverty of my response.

SECTION F._ECONOMIC SCIENCE AND STATISTICS.

THE GOLD STANDARD

ADDRESS BY
PROF. J. H. JONES,

PRESIDENT OF THE SECTION.

Wuen the Association, through its representatives, conferred upon me
the honour of electing me President of Section F for the current year,
I felt that the subject of the Presidential Address was determined for me
by the present state of affairs in the world. Currency stability, broadly
defined—or, better, undefined—is a condition of economic and social
progress. The outstanding problem of statesmanship is to restore that
stability which the world enjoyed before the outbreak of the recent war.
I believe that the causes of present instability and the conditions of
future stability can be described without the introduction of technical
terms likely to bewilder those who are not professional economists.
I therefore felt it to be my duty to devote my paper to a discussion of the
gold standard and to address the lay rather than the professional section
of the audience. I shall begin with a very brief survey of the past.

Li

Before the war of 1914-18 the gold standard was among the things
taken for granted as an element of western civilisation. It had served
England for nearly a century. The echoes of the bimetallic controversy
on the continent of Europe had already died away. It was a controversy
that belonged to the nineteenth century. The silver question had
ceased to be ‘spot news’ in the newspapers of the United States of
America. The spirit of nationalism in currency affairs was on holiday.
When, in the last three decades of the nineteenth century, one country
after another joined the gold standard group, their action was held to be
a sign of progress and they seemed to hold their heads higher than before.
They acquired prestige. It was thought that in the Far East the process
of industrialisation would be marked—as, indeed, it had already been
marked in India and Japan—by a transition from a silver standard to
a gold standard adjusted to national conditions.

An unvarying price average was not, however, among the achievements
of the gold standard. For roughly two decades before the Franco-
Prussian war, the so-called general level of prices had risen under the

IIo SECTIONAL ADDRESSES

influence of an increase in the rate of annual supply of gold following
upon the Australian and Californian discoveries. The post-war boom,
which reached its greatest height in the winter of 1872-73, was followed
by a downward trend which, if measured from the top of the boom to
the bottom of a depression, continued for approximately twenty-three
years. his trend in prices is usually attributed to a fall in the rate of
annual supply of gold, but I believe it to have been due, in greater measure,
to a rapid increase in the world demand for gold required for monetary
purposes. It covered the period during which the gold standard became
popular. One after another of the silver and bimetallic countries trans-
ferred their allegiance to gold. The United States returned to gold
after several years on a paper standard. New territories were exploited,
and the respective Governments adopted the gold standard. ‘The world
demand for gold reflected the process of transition ; it grew far more
rapidly than trade and population, and more rapidly than it could be
expected to grow under any other conditions or at any time in the future.
By the end of the century practically the whole of the modern industrial
world was on the gold standard, and from that time forward the standard
was free from the complications and dangers created by the appearance
of new disciples. It had become, to all intents and purposes, a world
standard. It could be judged on its merits as an international standard.
For the time being the countries that had not yet adopted it could be
regarded as relatively minor exceptions. The growth in the demand
for gold would be expected to keep pace with the growth in population
and in trade per head. During the remainder of the period ending in
1914 there was a fall in the relative amount of gold needed as money.
Not only was the banknote increasingly employed in ordinary transactions,
but in English-speaking and other communities the cheque or its equi-
valent was growing in popularity. While on the one side the rate of
increase in the demand for gold was affected by the cessation of the
march of nations towards the gold standard and the growth in the use
of substitutes for gold coins, on the other the rate of annual supply was
increased by the development of the South African gold mines. For
these reasons the downward trend in prices came to an end about 1895
or 1896 and was replaced by an upward trend which continued until the
outbreak of the world war and the suspension of the gold standard.
"The rise in prices during this period was not acceptable to everybody.
The lag in wages caused serious discontent and probably hastened the
growth of national organisations capable of much good but also of serious
harm. Forces were being generated which have materially helped to
shape economic and social events since the war. But the period of rising
prices was also one of rapidly developing trade and relatively high profits.
The discontent was that of the employed worker rather than, as at present,
of the unemployed worker. The former might complain of inequalities
in the distribution of wealth, but he could not complain of the pernicious
effects of ‘ deflation.’ As the gold standard permitted a steady increase
in the supply of money, and a rise in prices, the arguments now frequently
employed against the gold standard would have sounded foolish. ‘The
standard itself was enjoying a respite from popular criticism. In its

F.—ECONOMIC SCIENCE AND STATISTICS III

broad sense it was accepted on all sides as not merely inevitable but also
desirable.

Then came the war, with the usual economic consequences of war.
The gold standard was abandoned by nearly every country and currencies
were left to the mercy of needy Governments. The inevitable war-time
inflation was followed by the customary post-war boom and the process
of inflation was carried a stage farther. The subsequent period of
depression and falling prices imposed a searching test of economic policy
and revealed the degree of exhaustion from which the various countries
suffered. Currency instability and trade depression were associated in the
minds of people as cause (or part cause) and effect. It was assumed
that if and when currency stability was restored the world would have
a chance of recovery: without such stability recovery was impossible.
It was known, even at that time, that stability was a term that begged
most of the questions at issue, but such a detail was of no consequence
at a time when people longed for the restoration of pre-war conditions.
The world that disappeared in 1914 appeared, in retrospect, something
like our picture of Paradise. The financial leaders were strongly sup-
ported by public opinion when they pressed for a return to the gold
standard.

The world returned to gold. The defeated countries, whose currencies
had been destroyed by inflation pursued to its logical end (though not
in obedience to logic), created new currencies linked to gold. After
* looking the dollar in the face ’ for a couple of years we restored the gold
standard in 1925 at the pre-war rate. In the following year France and
Belgium stabilised their currencies in relation to gold and in 1928 restored
the gold standard, France fixing her currency at about one-fifth the
pre-war gold value. Meanwhile most other countries had joined the
gold standard group. Within the space of four years the gold standard
had been restored, and it remained in office—though not always in
power—until 1931, when it was again destroyed. From 1924 to 1929
most of the currencies of the world were stable, and the economic
world made rapid progress, although, for reasons that will presently be
noted, Great Britain did not enjoy a reasonable share of that progress.

The depression in trade after 1929 imposed too heavy a strain upon
our own country and in 1931 we again suspended specie payment. Our
example was followed at intervals by a large number of other countries
and now the world is divided into two parts, the group of countries that
have abandoned the gold standard and those that still, in fact or in theory,
have clung to it. When, a few months ago, the United States joined the
former, it became evident that the influence of gold was weaker than it
had been at any time since the war.

In this country the gold standard had appeared to act as a strait-jacket.
The paper pound had been given such a high gold value that our free-
dom was severely restricted. In spite of pessimistic predictions before
the step was taken the feeling engendered by the suspension of gold in
1931 was one of newly found freedom. The fall in the external value
of our currency actually stimulated trade. We found, however, that
we were merely enjoying a larger individual share of a diminishing total.

112 SECTIONAL ADDRESSES

And other countries discovered that they could, with advantage, join in
the game of ‘ beggar-my-neighbour,’ which France had been quietly
playing for several years and we had begun to play in boisterous fashion.
Then followed the new practice of ‘ competitive depreciation ’ with the
aid of instruments euphemistically called ‘ exchange stabilisation’ or
‘exchange equalisation’ funds. Before this new practice spread we
were enjoying our new freedom. Gold was a ‘ fair weather standard,’
to which we were in no hurry to return. America wanted us to return
to gold, but why should we rush into new danger? Disillusioriment
came when the United States (and therefore Canada) joined in the new
game. ‘The most recent experience, with new and strong players, has
led us to believe that, after all, the game is not worth the candie, and
that what we had termed a strait jacket was merely that sort of discipline
which is a condition of freedom. The gold standard promises once more
to become popular.

II.

The brief survey that I have submitted suggests the need for a restate-
ment of monetary theory. In spite of all that has been published in
recent years I do not believe that the monetary standard has yet received
adequate treatment ds a separate problem. In most cases the discussion
of the standard has been more or less incidental to the discussion of other
problems that either appear more urgent or are regarded as the central
theme of the writer. Naturally I do not propose, in this paper, to attempt
to fill the gap. But I venture to attempt to place before you those issues
which, in my opinion, can be appreciated by the general public and must
be faced if we wish to restore and afterwards maintain the gold standard
in this and other countries. Moreover, I shall submit reasons for my
belief that we should again seek to establish that standard, and that some
modifications recently suggested would tend to weaken rather than enhance
its value as an instrument of social progress.

Money is the means by which we secure ownership of things that we
desire, or obtain services of various kinds. The amount of money paid
for goods and services is the result of bargaining between buyers and
sellers, and this result is influenced by certain fundamental considerations.
One of these is the connection or sympathy that normally exists between
the rates of payment (which I shall call wages) prevailing for personal
services. Ifa coal miner earned ten times as much as a railway worker
everybody would know that there was some highly abnormal influence
at work which would ultimately disappear. Relative wages are governed
by silent and persistent forces known to every student of elementary
economics. ‘They tend to arrange themselves around a mean wage in
the manner determined by such forces. In a world of change the dis-
persion of actual wage rates at any time is never precisely that which the
persistent forces tend to produce ; nevertheless the correcting influences
are always at work. Again, the ‘ short period,’ during which deviations
from the ‘ normal ’ distribution about the mean level may continue, tends
to grow longer. ‘The mills of competition grind slowly. But they con-

F.—ECONOMIC SCIENCE AND STATISTICS 113

tinue to grind. We know that a rise or fall in the wages of one group
will not be permanent unless it is followed by a corrresponding change in
the wages of the other group, or unless there has been a change in the
nature of the persistent forces to which I have referred. It is precisely
this sympathy in wage movements that gives significance to the conception
of an average wage and to movements in that average.

If it be true that the relationship between individual wages is not
arbitrary, it is also true that the relationship between individual prices is
not arbitrary. In the long run prices are governed by costs, and costs
ultimately mean wages. Even economic rent, in the last resort, is a
function of the wage average. If prices are governed by costs and costs
by wages, and if relative wages obey a law of distribution, it follows that
actual prices also tend towards a ‘ normal’ arrangement or distribution.
If a house of ten rooms could be purchased for the same sum as a hundred
tons of coal, everybody would recognise the existence of some abnormal
influence which could not fail, ultimately, to bring a correcting influence
into play. A rise or fall in a large group of prices will not be permanent
unless either a similar change takes place in the remaining group or a change
has occurred in the real costs, and therefore money costs, of supply.
It is precisely this sympathy in prices that gives significance to changes
in the price average or general level of prices. As in the case of wages
so, too, in the case of prices : the ‘ short period,’ during which deviations
from the ‘normal’ distribution may continue, tends to grow longer ;
but in the long run the effect of the persistent force of competition
(broadly interpreted) becomes evident even in a constantly changing
world.

These elementary facts seem to me to provide the true foundation of
a theory of money. The supply of money needed by a community, and
the supply of money that can be absorbed by a community, is a function
of the price average. If every pound of wages or of prices were called
ten pounds, the community would merely be using ten times as much
money as before. Conversely, if the supply of money is fixed, the price
average must conform to that supply, and in a state of equilibrium the
wage average and the price average will reflect the normal distribution of
individual wages and prices. But a change in the supply of money
produces intermediate effects before the final state of equilibrium is
reached. Nor is it necessary to stress the practical importance of these
intermediate effects, which will presently be considered. At the present
stage, however, it is desirable to confine our attention to the characteristics
of a community in a state of equilibrium in the sense of being free from
the intermediate disturbances of a process of change.

I have referred to the existence of a normal distribution of wages and
of prices. The statements that I made are applicable to every community
in which order is maintained, either through the force of competition or
by legal enactment. But the normal relationship of wages or of prices
is not the same in all communities: each has its own characteristics.
Thus, for example, the relative rates of remuneration of school teachers,
coal-miners and railway workers may not be the same, under normal con-
ditions, in Great Britain as in Germany. ‘The normal distribution may

114 SECTIONAL ADDRESSES

vary, within narrow limits, even between different parts of Great Britain.
The statement may be extended to include prices. Nevertheless it is
true to say that for each community there exists a normal relationship of
wages and of prices towards which actual wages and prices tend. I
assume this broad generalisation in all that follows.

My next statement is equally elementary. It is a truism that some
commodities and services supply local markets while others supply
national or international markets. In the market, whether it be local or
world-wide, there is a strong tendency towards a common price. Within
this country the price would be quoted in the same money, but in other
countries it would be quoted in some other kind of money. If, however,
we exported a commodity we would normally expect to be paid, in foreign
money, an amount equivalent to the British money obtainable for it if it
were sold at home. ‘The means of payment may be some foreign money
—we may, for example, accept payment in marks—but the measure of
value is our own money.

For the purpose of simplifying the statement I shall assume commodities
(including services) to be divided into two groups, international and
domestic, the former comprising those which are commonly exported
from one country to another and the latter those which supply local
markets. Further, I shall neglect variations in costs of transport. Finally,
I shall assume that all communities or countries employ gold as money.
It follows that international commodities command the same prices in all
countries. British exports are sold at the same prices as German exports
or American exports. But we have already seen that the prices of British
exports are normally related to the prices of all other things produced and
sold in Great Britain. Consequently the price average or general price
level in this country will be such as to produce the international prices
for international commodities, while the wage average or general level
of wages will be such (under a normal distribution of individual wages)
as to produce that price average. It does not, however, follow that the
wage average in this country must be the same as in other countries.
The wage average will be a function of natural conditions, industrial
technique and human efficiency; but it must be such as to enable
the country to maintain the price average dictated by international
conditions.

The same general truth may be expressed in another way, Gold, like
other international commodities, is distributed among the markets
(countries) of the world in such a way as to command the same value in
all. Value in this connection means purchasing power. It follows that
in the state of equilibrium represented by such a distribution of gold,
the exports and imports of a country are balanced.” It must be so, for

1 It is immaterial that, in this case, we accept the risk of exchange : it would
be possible for us to cover that risk, and the cost of covering it would be a prime
cost and a component part of the price in pounds. In a state of equilibrium
there would be no such risk.

2 It should not be forgotten that I am assuming exchange to be confined
to commodities, including services. I shall presently refer to movements of
capital.

F.—ECONOMIC SCIENCE AND STATISTICS 115

it is evident that if exports do not balance imports there will be a flow of
gold from one country to others. This flow will only cease when a true
equation has been established.®

It will be clear from the statements already made that if all countries
employ gold, and only gold, as currency, each must accept the wage and
price average or level dictated by the price average of international goods,
and that this will be determined by the gold supply in relation to the
demand. If the gold supply is x the price average will be half as high
as if the supply were 2x, for in making such a comparison we may assume
the rapidity of circulation to be the same in the two cases. Sucha currency
therefore imposes a discipline upon each country ; it must march in step
with the others. If one country found a gold mine within its boundaries,
issued currency to the amount of the new supply and raised wages and
prices to the extent of the new available currency, exports of other com-
modities would fall and imports increase, with the result that the gold
would flow out until a new equilibrium was reached at a correspondingly
higher international price average. During the intermediate stages the
industries supplying international commodities would be depressed
in the country possessing the new gold mine, and correspondingly
more active in other countries. This change in the state of trade
would be the active force that would restore the new state of
equilibrium.

It will also be evident that the same results will follow if, instead of
using gold as currency, each country employs paper representing gold,
pound for pound, or dollar for dollar, so that any variation in the supply
of gold is automatically followed by a variation in the supply of paper
currency. Nor is the case altered if gold represents not a hundred per
cent. but x per cent. of the paper currency. For it is clear that a given
variation in the supply of gold is followed, automatically, by a similar
percentage variation in the supply of currency. Moreover, it is obvious
that the smaller the percentage gold reserve (that is to say, the greater
the economy in the use of gold) the higher the price average of inter-
national goods and the wage and price average within each country. But
it remains true that each country is subjected to the discipline to which
I have referred.

Provided one condition is satisfied, the case is not altered if, instead
of merely employing paper currency the supply of which is automatically
adjusted to the supply of gold, a country also employs means of payment,
such as the cheque, the supply of which may vary independently of the
supply of gold. The condition is that the country remains on the gold
standard. The gold standard is a legal enactment to the effect that the
- legal tender of a country shall be convertible on demand into a specified

3 In the complex economic system which I shall consider at a later stage,
exchange equilibrium between two or more countries may be defined in either
of two ways, namely, a rate of exchange which maintains a balance of payments
and a rate which represents equivalence of price levels. These are not necessarily
identical. In a changing world they are not even likely to be identical. Failure
to distinguish between the two, and to state in which sense equilibrium is being
employed, has clouded much recent controversy.

116 SECTIONAL ADDRESSES

quantity of gold. Its economic significance is that it maintains a fixed
rate of exchange.

While a country is on that standard it is forced to adjust its price average,
and therefore its wage average, to the international price average. So
long as the currency is a stated proportion of the gold supply the currency
adjustment to a change in the latter is automatic. But when such
currency is supplemented by means of payment the supply of which is
not automatically controlled, some other means of adjustment must be
found. In modern communities the duty of adjusting the supply of
money, in its broad sense, and thereby administering the Gold Standard
Act, is entrusted to the Central Bank or some equivalent organisation.
The Central Bank is given the right to issue legal tender, and the supply
is always—though, not necessarily—specified in relation to gold supply.°
But there is no legal regulation of the use of other means of payment.
Control is left in the hands of the Central Bank, and the instrument of
control is the rate of discount, supplemented and made effective by open
market operations.®

By means of the rate of discount, reinforced, when necessary, by open
market operations, the bank is able to control the supply of means of
payment and thereby to adjust the wage and price average to the inter-
national price average. That being so, control by law of the supply of
legal tender is not inevitable. It may still be desirable, for it is usual
for the discount policy of the bank to be governed by the supply of legal
tender held in reserve and this, in turn, is determined by gold movements.
Nevertheless it represents a stage in the evolution of the credit system
rather than an integral part of a perfect system. It is even more desirable
in other countries than in Great Britain. On the other hand it is clear
that the proportion of gold held against currency may be materially

4 In the English Gold Standard Act of 1925 it was provided that legal tender
was only convertible into gold provided that the amount to be converted was
not worth less, at the defined rate, than 400 ounces of gold; but this provision
was merely a safeguard against the use of gold for internal purposes, such as
currency. The paper pound was declared to be convertible into gold at the
rate of £3 17s. 103d. per ounce of standard gold, that is to say, it was worth the
gold contained in the pre-war sovereign.

5 The precise methods differ in different countries. We favour a fixed fiduciary
issue ; other countries favour a fixed percentage gold reserve. This difference
is not fundamental. The former produces less violent reactions and therefore
facilitates a steady adjustment. The latter tends to produce unnecessary
fluctuations during a process of adjustment to a new state of equilibrium. The
English method seems to me better than that employed in the United States.

6 It is important to stress the fact that the Central Bank is not a free agent.
It is entrusted with the duty of maintaining the gold standard, and its action
must be guided by the need for fulfilling its obligation under the Act which
defines the standard. Since 1925 the Bank of England has been criticised on
numerous occasions for pursuing a discount policy which was regarded as inimical
to industrial progress. I do not suggest that the policy of the Bank has always
been above reproach. I do not, indeed, believe that academic economists
usually possess sufficient information to justify comment upon current policy.
It is clear, however, that much of the popular criticism of the Bank has been
due to failure to distinguish between the necessities imposed by the Act of 1925
and the policy of the Bank in circumstances that allowed freedom of choice.

F.—ECONOMIC SCIENCE AND STATISTICS 117

altered without prejudice to the present system. ‘The latter secures an
automatic adjustment of the internal price average to the international
price average, and this may be done with a 30 per cent. gold reserve as
effectively as with a 40 per cent. reserve. A change from the larger to
the smaller reserve would permit a substantial rise in the international
price level.

The discussion of the gold standard has been based, so far, upon an
important assumption, namely, that trade between countries consists of
the exchange of commodities, including such services as shipping.
I have ignored capital movements and interest payments. On that
assumption I have tried to show that, when countries are on the gold
standard, their internal wage and price averages must be adjusted to the
price average of international goods. In a state of equilibrium trade
between the countries will be balanced, that is to say, exports and imports
will be equal in total value. Within each country the wage and price
averages will represent a normal distribution of particular wages and
particular prices. If equilibrium is disturbed gold movements will
follow. In practice the equilibrium between countries will quickly be
restored through the adjustment of the internal prices of international
goods following depression on the one side or, on the other, greater
activity. But the resulting internal disequilibrium is not so quickly
removed. Some trades are affected more quickly and seriously than others ;
some are sheltered, others unsheltered. Wage rates in the latter fall out
of line with wage rates in the former. So long as this adjustment is
delayed the intermediate effects will continue. But in the long run the
condition of domestic disequilibrium will be changed and a new position
of stable equilibrium reached, both within the country and between
different countries.

In the next stage of the discussion it is necessary to consider the effects
of capital movements. One of the commodities entering into the final
price average is capital, which, for my present purpose, I shall divide
into investment capital and liquid capital. It is well known that the
price of capital is higher in new countries than in countries which, in the
industrial sense, have reached maturity, and that the difference is greater
than the measure of relative risk. Hence we find a movement of capital
from older to younger countries, enabling the latter to develop more
rapidly than they would be able to do without such assistance. Investment
is an import (of bonds) which must be offset by an equivalent export of
commodities. Other things being equal an investing country therefore
enjoys an excess of current exports of commodities (including current
services) over imports. We need not pause to consider whether foreign
investment or the excess of exports is the cause, or which came first.
It is sufficient to point out that, in a position of equilibrium, the price
average within a country must again be such as to make the price average
of exports equal to the international price average and that, for com-
modities (including current services), the average will be lower than
it would be if capital were not being exported. But in due course the
lending country receives interest, and the amount of interest increases
annually. This inflow of interest neutralises a corresponding outward

118 SECTIONAL ADDRESSES

flow of capital. By 1914 the interest receipts of Great Britain were
apparently less than the amount of capital annually added to our foreign
investments. Our exports of commodities (including current services)
appeared to be less than our imports of the same kind. We were rein-
vesting abroad nearly the whole of the interest upon accumulated invest-
ments, but apparently we already needed a small proportion of such
interest to pay for current imports. A debtor state which had ceased to
borrow also possessed a surplus of commodity exports, the surplus being
needed to pay the interest on accumulated debt. Such was the position
of the United States of America before the outbreak of the world
war.

The growth of long-term investment was normally so slow and regular
that it did not destroy the internal equilibrium of the investing country.
For short periods it might invest more or less than the commodity surplus
representing the sum available for investment. But in such cases the
balance of payments was maintained by the transfer of liquid capital.
The investment operation was supplemented by a credit operation.
Similarly, if for any other reason there was a temporary excess of imports
or exports the surplus or deficit was removed by a movement of liquid
capital.

It is here that we find the essential difference between investment
capital and liquid capital. Investment might well be termed an industry
resembling coal mining or cotton manufacture. It possessed (if we
ignore cyclical fluctuations) a fairly constant market outside the country
and had been built up slowly upon the assumption that the market was
comparatively safe and likely to grow. Other industries, supplying the
commodities representing the export surplus available for investment,
had also grown up alongside the investment industry, their growth being
based upon the assumption of continuity in the growth of investment.
In short, investment was an integral part of the industrial structure and
an influence determining the remaining permanent features of the latter.
It was not an accident of growth or an occasional visitor. Continuity
was of its essence, and if all foreign markets for British capital had suddenly
disappeared, industry would have been reduced, for a time, to a state of
chaos. Liquid capital, on the other hand, was employed, in different
places and at different times, as an equalising factor. Its purpose was
to restore or maintain temporary equilibrium when equilibrium had
already been destroyed or threatened ; to ease the restoration of true or
stable equilibrium by reducing the intermediate effects of a process of
change or the effects of some temporary disturbing factor. I shall
endeavour to show that some of our most serious difficulties since the war
have been due to the fact that the distinction between investment capital
and liquid capital has lost much of its pre-war significance.

III.

The conditions that I have described in the second section seem to me
an essential part of a secure foundation for the working of the gold
standard. But they do not indicate all the conditions that must be satisfied.

F.—ECONOMIC SCIENCE AND STATISTICS 119

In order that this may be made clear it may be desirable to indicate very
briefly the features of the pre-war gold standard and the essential
differences between the working of the pre-war standard and the working
of the standard since the war came to an end.”

The pre-war standard was of slow growth and became the foundation
of a financial system of a highly complex character regarded from the
point of view both of structure and of function. The standard was
adopted by one country after another under conditions favourable to its
operation ; it represented a choice between three or more alternatives,
and its adoption was regarded as a real advance. The first important
point that I would emphasise is that the industrial structure had been
adapted to the requirements of the standard. The normal level of wages,
costs and prices was adapted to the rate of exchange and consequently
to the international level of prices. The currency was neither over-
valued nor undervalued, but neutral. The theory of comparative costs
afforded a real explanation of the distribution of industry and trade
between nations. Changes in the distribution of trade were slow and
continuous and were due either to changes in the relationships of real
costs of production or to changes in tariff policies. It is, of course, true
that changes occurred in the relation of the gold supply to the world
demand for gold and therefore in the international price level, but these
were so slow as to present no serious obstacle to the adjustment of wages
and costs in individual countries. In this connection it should be observed
that gold was allowed to move freely from one country to another in
response to economic influences and that movement was only due to such
influences.

In the second place, the savings of the people were invested in long-
term securities. A comparatively small amount was added every year
to the fund of liquid capital employed in financing trade ; but this fund
was determined by trade requirements and by the opportunities for long-
term investment rather than by the willingness or unwillingness of their
Owners to invest.

In the third place, the long-term investments of lending countries,
such as Great Britain, Germany and France, were appropriate to the
industrial structures of beth lending and borrowing countries. Thus,
for example, the industrial structure of Great Britain and the annual
overseas investments of Great Britain formed pieces which fitted together
to form part of the economic mosaic.

In the fourth place, although most of the countries of the world were
living under protective systems, and of systems of greater or less pro-
tection, tariffs were not employed to correct temporary failures to balance
international payments during periods of depression. Protection repre-
sented a choice of alternatives and in each case the system was carefully
thought out and determined by long-term considerations. For a rela-
tively long period of years a protective system could be regarded as a

7 I discussed these in greater detail in a course of four lectures delivered shortly
before Christmas to the London Institute of Bankers and published in the Journal
of that Institute. F

120 SECTIONAL ADDRESSES

constant ; international trade adapted itself to that system and for this
reason the system did not seriously prejudice the operation of the gold
standard. This statement does not constitute a defence of protection.

Finally, the credit system of the world was not only firmly organised,
but organised in such a way as to facilitate the working of the gold standard.
The Bank of England acted not only as the Central Bank of Great Britain,
but also as a sort of International Bank of Economic Settlements. In
time of need it was able to draw funds from other countries and to employ
those funds at the place of need and in the manner dictated by that
need. One of the outstanding features of the system was that, when
any country was in distress, the Bank of England was able and ready to
mobilise the reserves of the world and to rush to the rescue of that country.
Credit or liquid capital was thus a balancing influence rather than an
influence employed to destroy an existing state of equilibrium. If actual
gold was needed it was forthcoming, as in the case of the United States
of America during the crisis of 1907; if a short-term loan was needed
gold was not unnecessarily moved from one country to another; gold
movements merely supplemented credit operations. Gold was not an
alternative to a short loan, neither was it moved about in such a way as
to necessitate a counteracting short loan operation. Both credit and gold
movements were correcting rather than disturbing influences; they
restored rather than destroyed equilibrium. The Bank of England
adopted a more or less neutral attitude in the sense that it performed the
essential functions of an International Bank and regarded the problem
of monetary stability as an international problem. I do not, of course,
suggest that its attitude was altruistic and that Great Britain voluntarily
adopted such an attitude merely in the interests of world stability and
progress. Such was not the case. The economic structure of Great
Britain and the position that she held as the largest investing country
and the centre of world finance made her individual interests identical
with the interests of the world as a whole. There was no conflict, or
presumed conflict, between the one and the many.

IV.

In all these respects the post-war world has differed from the pre-war
world. Moreover, it seems to me that it is in precisely these differences
that we find the real explanation of the failure of the gold standard, and
that, before we can hope to establish any international standard that will
stand the test of time, it will be necessary to restore those conditions which
made the pre-war gold standard not merely workable but also highly
successful.

In the first place, the post-war gold standard was not of slow growth.
Most of the countries that had abandoned gold under the pressure of
war rushed back within the short space of about four years, and with-
out considering with sufficient care the changes that had occurred in
the underlying economic conditions. ‘The result was that in some cases
the rates of exchange were fixed too high and in other cases too low.
I may refer briefly to the two outstanding examples—Great Britain and

F.—ECONOMIC SCIENCE AND STATISTICS 121

France. In 1925 we returned to the gold standard, and in doing so
gave the pound the same gold value as it possessed before the war, that
is to say, we restored the pre-war dollar rate of four dollars eighty-six
cents to the pound. It was felt by many critics that such a value was too
high in relation to the relative wholesale price levels of Great Britain
and the United States of America. For several months before we returned
to gold the dollar value of sterling had been rising, as the result of a
transfer of funds to this country, without any change in the underlying
economic conditions. Our price level, it was said, was appropriate to
the dollar rate that prevailed before such transfer took place, so that in
restoring gold at the pre-war parity the Government overvalued our
currency, the extent of overvaluation being estimated roughly at 10 per
cent. It was therefore necessary to reduce our price level by 10 per
cent. in order to be able to supply international goods at the international
price level.

It seems to me that that criticism was inadequate. After the boom
of 1920 we suffered a period of severe depression during which wage
rates in the industries supplying international goods (that is to say, the
unsheltered industries) were reduced to an extent far exceeding the
reductions that were made in the rates of wages prevailing in sheltered
industries. In spite of these reductions the return upon capital invested
in the sheltered industries fell below the normal rate obtainable in the
sheltered industries. ‘Thus we were already suffering from an internal
industrial disequilibrium ; the normal distribution of particular wages to
which I referred in the second section had been seriously disturbed.
Although the wholesale price level for international goods was made,
Say, 10 per cent. too high by the return to gold, it represented a price
level based upon an unduly low wage average in the industries concerned
and an unduly low average return upon the capital invested in such
industries. For that reason I believe that the degree of overvaluation
was seriously underestimated by the majority of those who objected to
the conditions under which we returned to the gold standard. The
new standard imposed two tasks upon this country, the first being to
reduce by 10 per cent. the price average or price level of the products
of the unsheltered industries, the second being to make this new level
represent a normal distribution of wages, costs, prices and profits through-
out the whole of British industry. Even if there had been no other
factor in the situation it is clear that an almost impossible task had been
imposed upon the nation. But a further difficulty arose, after 1925, in
consequence of a fairly steady fall in the world price level itself. In
spite of the reductions in wage rates in the years that followed the return
to gold, I do not believe that we succeeded in doing more than keep
pace with the world price level. We had failed in the double task that
had been set by the restoration of the gold standard.

_ The overvaluation of the pound inevitably produced a depressing
effect upon British industry. It acted as a veiled tax upon exports and
a veiled bounty upon imports, with the result that our export surplus
was considerably less than would otherwise have been the case. At
the same time the world was in need of capital and the tradition of London

122 SECTIONAL ADDRESSES

as a centre of foreign investment led to an attempt to meet this world
demand. British capital was invested abroad to an extent exceeding
the available export surplus, but this result was hidden by the fact that
during the same period other countries sent their liquid capital to London
in search of security. I shall return to that point presently ; at the
present stage I wish to stress the fact that, if such funds had not been
imported to this country, the underlying weakness of our position would
have been revealed earlier. It would have been necessary to maintain
even higher discount rates than those which prevailed and to pursue a
policy of more severe deflation. The depression in trade would have
been even greater than actually proved to be the case. This danger was
averted by the importation of funds from other countries, although such
importation created a danger of another character which will be presently
considered.

The case of France differed materially from our own case. When,
after a period during which the value of the franc was stabilised, the
French Government restored the gold standard, the franc was given a
value of approximately one-fifth the pre-war value in terms of gold.
But the wage, cost and price levels in that country were such as to suggest
a value far higher than that actually given to the franc. The result was
that while in Great Britain the gold wage level was about 75 per cent. above
the pre-war level, in France it was even below the pre-war level, and even
at the present time seems to be little if any above the pre-war level. It is
precisely for this reason that the French at the present time are able to
contemplate with equanimity the prospect of a return to prosperity with-
out any rise in the price level of that country. Further, the undervalua-
tion of the French franc acted as a veiled bounty upon all exports and
a veiled tax upon all imports. The temporary effect was to increase the
export surplus (which was further increased by the receipt of Reparation
payments from Germany) and to enable the French to amass balances
which were left within call in other countries. The funds that accumu-
lated in this country were largely French funds.

In the second place, as we have already seen, a large proportion of the
savings of the people of different countries, instead of being invested in
long-term securities, were held within call. Thus a vast amount of
capital (estimated at two thousand million pounds), which should, and
normally would, have been invested in industrial and other long-term
securities, was held in liquid form and was moved about in search
of security—security which included rapid realisability and was of
more importance than a substantial difference in the rate of interest.
That confidence which is generated by peace and normal economic
development was lacking; the risk factor was overvalued. One result
was that industries became heavily burdened with fixed-interest and
short-term debts. In this connection it is important for the future to
observe that the distinction between investment capital and what I have
called liquid capital has lost much of its importance. The war has resulted
in a large increase in securities (mainly issued by governments) which can
be realised upon an international market with very little delay. These
securities are now held to a greater extent than in the past by people who

F.—ECONOMIC SCIENCE AND STATISTICS 123

wish to retain their capital within call. They are therefore far more
susceptible to sudden changes in demand and immediately available
supply, and their existence on such a large scale has added to the
instability of the post-war economic world.

In the third place, a change of the first importance has taken place in
the financial relationships of nations without a corresponding change in
their industrial structures. The United States of America provides the
outstanding but by no means the only example of such change. Im-
mediately before the war that country, although a heavy debtor, had
ceased or almost ceased to be, on balance, a borrower. Her industrial
structure was appropriate to that state of affairs. She possessed a large
export surplus representing interest upon, and to some extent the repay-
ment of, the accumulated loans of the past. The war enabled her not
merely to pay off her debts but also to become an important creditor
state. Her industrial structure remained practically the same as before ;
the interest element was transferred from one side to the other side of
her account with the rest of the world. Not only did she possess an
export surplus in respect of commodities and personal services but that
surplus was now augmented (where once it was offset) by interest pay-
ments. She was like Mr. Manhattan of comic opera fame, “all dressed
up and no place to go.”’ One factor in the situation is the amount owing
to America in respect of so-called war debts, but from her point of view
it is not an important factor. The much discussed transfer problem is
as relevant to and important for America in the case of other forms of
indebtedness as in that of the debts of other governments. What is
peculiar to the so-called war debts is the fact that they represent a con-
tract between two governments, but this is of no international economic
significance.

The failure to fit the industrial structure of the world to the new
financial relationships between nations constituted one of the real diffi-
culties in operating the post-war standard. I have already referred to
the fact that, before the war, gold moved from one country to another in
response to economic influences and that such movement produced its
effect upon monetary policy and relative price levels. Since the war
the changed financial relationships have caused not merely a large-scale
movement of gold but also a concentration of gold in those countries in
which the change in financial relationships, with the given industrial
structure, had not been fully offset by a policy of foreign investment.
Thus France and America have jointly amassed a large proportion of the
total world supply. But they have not allowed that supply to produce its
pre-war effects. About ten years ago Mr. McKenna rightly pointed out
that America was on a dollar standard, not the gold standard. It is,
I believe, literally true to say that at no time since 1920 has the United
States been on the gold standard in the full technical sense of the words.
It is equally true to say that France, while legally on the gold standard
since 1928, has never accepted the implications of that standard. The
reason for the failure of these two countries to employ the gold standard
in the full sense of the words is to be found in their unwillingness either
to adapt their industrial structures to the new finanical relationship or to

124 SECTIONAL ADDRESSES

embark upon such a policy of foreign investment as would enable them
to maintain the existing industrial structure.

Again, the credit system of the world has been completely disorganised.
The change in the relative financial strengths of Great Britain, America
and other countries, has tended to reduce the pre-eminence of London
as the financial centre of the world; the power of the City has been
challenged by New York and Paris. But that is not the only change that
has occurred. I have already referred to the existence of a large mass
of liquid capital that would normally have been absorbed by industry in
the form of long-term investments. This liquid capital has not been
employed by the Central Banks as a stabilising factor ; on the contrary,
it has proved to be a disturbing factor. Before the war the Bank of
England, as the centre or controller of international credit, employed
such credit in the service of distressed countries and thereby maintained
financial stability. Since the war it has not been able to perform this
function with the same effect, while other countries that were able to
render assistance could not be relied upon. When the credit of any
country was threatened, foreigners withdrew their funds in search of
security. When, in 1931, we needed the type of assistance that we were
accustomed to render to other countries, the latter deserted us like rats
deserting a sinking ship. A large mass of liquid capital moved about the
world leaving crisis in its train and creating embarrassment to the countries
that it sought, always hunting for security without ever being sure of
finding it. The most recent victim of the damage wrought by this
movement is the United States of America.

NV:

In the fourth section of my paper I have tried to indicate those
differences between the pre-war and the post-war gold standards which
accounted for the success of the former and the failure of the latter. The
question arises whether, under present conditions, it is worth while either
to restore the gold standard or to establish any other form of international
metallic standard. It is known to all economists that the difficulties of
working the post-war gold standard were increased by technical defects
in banking organisation, particularly in the United States of America
and in France. A discussion of these defects would not be possible in
this paper; I refer to them merely to indicate that I am aware of their
existence. But I believe, and I therefore assume, that if the more funda-
mental difficulties to which I have referred were overcome it would be
possible to solve purely technical problems.

The essential feature of the gold standard is that it maintains a fixed
rate of exchange, establishes an international price system in the sense
of a common measure of value, and controls the internal or domestic
supply of currency and therefore the domestic level of prices. It seems
to me that if we are to return to the gold standard it must be a standard
that retains this feature. Before the war a movement of gold from one
country to another automatically reacted upon the relative supplies of
money in the countries affected. It has been suggested by the Gold

F.—ECONOMIC SCIENCE AND STATISTICS 125

Delegation appointed by the Economic Section of the League of Nations
that in future the various countries should maintain free reserves of gold.
The gold supply of a country should be divided into two parts, the first
being the legal reserve against currency, the second being the surplus
available for export. The purpose of the scheme is to secure that an
export of gold from or an import of gold into the reserve should not react
upon the currency policy of the country concerned.

It seems to me that this proposal would destroy the vital element in
the gold standard. In recent years we have seen how free reserves are
actually employed in practice. In America they were placed on the
most inaccessible shelves of the vaults of the Central Banks, In many
of the smaller countries they were virtually added to the legal reserves.
They were exported with extreme reluctance and the loss of gold even
from those reserves reacted upon the discount and currency policies of
the losers. Further, it is clear that if all countries maintained free
reserves, a considerable proportion of the total reserve of gold in the world
would be rendered ineffective as a foundation for currency, with the result
that the gold price level would be lower than under the alternative system.
But the real argument against the proposed system is that a movement of
gold would not be producing the effect upon internal policy that such a
movement ought to produce under normal conditions. At best we should
be using the cumbrous method of moving actual gold instead of the pre-
war method of moving liquid capital or providing credit ; at the worst it
would delay a domestic adjustment so long as to make such adjustment
greater and more difficult and thus endanger the standard itself. For
these reasons it seems to me that the proposal does not constitute an
improvement upon the pre-war gold standard. ‘The same reasons lead
me to believe that the suggested compromise of establishing and main-
taining a wide margin between the buying and selling prices of gold
would destroy what is most valuable in the gold standard.

If we ignore other metallic systems it seems to me that the real issue
lies between the gold standard, rigorously interpreted, and the main-
tenance of national: currencies which are not linked together by being
linked to gold or to any other common measure. When we abandoned
the gold standard the alternative achieved considerable popularity in
this country, but all recent experience has shown that, during a period
of currency disturbance, it tends to increase rather than reduce our
difficulties. My objection to the system, however, is due not to the
fact that it has created or intensified difficulties under present conditions,
but to the fact that it would create difficulties of the present type even
though it were introduced under the best possible conditions. ‘The
system has been advocated on the ground that it would enable us or any
other nation to pursue a currency policy that would maintain a stable
price level. For reasons which I cannot give in this paper I believe
that precisely that sort of stability which they seek is more likely to be
achieved under the gold standard than under a system in which such
stability is the immediate object of national policy. But it seems to me
that a wider and deeper issue than even price stability is involved in the
discussion of the two alternative monetary systems. The national

126 SECTIONAL ADDRESSES

currency system is but one aspect of economic nationalism or economic
isolation, of which tariffs is another. A national system of currency is
intelligible if not defensible for a nation which isolates itself from the
family of nations. It is not, however, consistent with a policy of inter-
nationalism in other departments of economic activity. The gold standard
stands for internationalism in economic affairs ; it is a condition of free
development of trade between nations. Nor should it be forgotten that,
if most countries were on the gold standard, secular changes in the value
of gold would be relatively small. Post-war changes in the value of
gold have been due not to the gold standard but to the failure of a number
of countries to operate that standard.

Without pausing to consider the case for bimetallism, I venture to
express the belief that the restoration of the gold standard is necessary
to the progress of the world in that future which is worth considering.
I am content to leave the twenty-first century to our great-grandchildren.
I do not, however, suggest that the gold standard should be immediately
restored ; on the contrary, I fear that political considerations will drive
us back to that standard before the essential preliminaries have been
properly considered. In the first place, it would be folly on our part
to return to gold until we knew precisely the rate of exchange that would
enable international trade to be distributed in the manner determined
by real costs of production. The new rates should be determined by
purchasing power parities. We are not yet agreed, however, upon the
precise meaning of purchasing power parity, neither do we possess the
information that would enable us to estimate purchasing power parity,
howsoever defined. Again, we should not return to gold until the price
averages of different countries, expressed in their respective currencies,
have reached those heights which are regarded as satisfactory; for it
is clear that subsequent changes must be international rather than purely
domestic in character. Further, we should not restore the gold standard
until individual countries are prepared to pursue investment policies
that are appropriate to the remaining parts of their economic structures.
It is too much to hope that the great mass of liquid capital which now
readily—too readily—flows from one country to another will quickly
be invested in long-term securities and thereby cease to be a danger
to the financial stability of a number of countries, but it should be easy
to form an international exchange stabilisation fund under the control
of an appropriate body which, in effect, would perform the pre-war
international function of the Bank of England. Such a body would
direct the flow of funds according to the needs of individual countries,
not, as at present, in the opposite direction.

A word should be added on the question of tariffs. Before the war
the tariff system of each country was determined by long-term considera-
tions. During the last few years all countries (our own included) have
found refuge in the doctrines of the mercantilists of earlier days. ‘Tariffs
have been used not to direct the development of industry but to direct
the immediate flow of trade. An adverse balance of trade is no longer
regarded as an incident of economic growth but as a calamity to be avoided
at all costs. An established system of protection is not inconsistent

F.—ECONOMIC SCIENCE AND STATISTICS 127

with the operation of the gold standard, but frequent tariff manipulation
to meet fluctuating trade balances is bound to render any international
currency standard impossible. It is too much to hope that the world
will abandon tariffs as a measure of protection, but it will be difficult
to maintain the gold standard unless the countries of the world are pre-
pared to abandon the system of ad hoc trade restrictions to overcome
occasional deficits on current accounts. I do not believe, however, that
I am too optimistic in stating that this difficulty would quickly disappear.
The new practice of adjusting tariffs to failures to balance payments is
largely the product of the failure of our credit system. If liquid capital
had gone to the rescue of, instead of running away from, countries with
adverse balances the need for dealing with the situation in another way
would not have arisen. I therefore believe that if we could solve the
problem of controlling the flow of credit, either through the creation of
an international exchange stabilisation fund, or in some other way, the
difficulties created by the new restrictions upon trade would also be
solved.

We are frequently told that a return to the gold standard is impossible
so long as the world supply of gold is so largely concentrated in two

countries. It is no doubt true that the present distribution of gold

presents a serious difficulty, but I do not regard it as an insuperable

_ difficulty. The present distribution of gold is the result of those post-war

l(t

influences to which I have already referred. If we could restore those
conditions which are essential to the maintenance of the gold standard it
is not unlikely that a redistribution of gold according to apparent need
would be accepted. Gold is only preferred to an earning asset so long as

_ the earnings of the latter do not exceed the money estimate of the risk

involved. In the last resort, however, the international price level in

_ terms of gold matters less than the domestic price levels expressed in local

currencies, so that the difficulty created by an unequal distribution of

_ gold could be overcome by giving an appropriate gold value to paper

currency and maintaining a relatively low legal reserve. Moreover, if

domestic price levels, expressed in local currencies, are sufficiently high,

the burden of fixed debts necessitating a flow of payments from one

country to another would not be so heavy as to endanger the gold standard.
A recent judgment in this country, and still more recent pronouncements
in the United States, have shown that debts contracted in gold are no
longer payable in the gold value expressed in the bonds. A foreign debt
payable ‘in sterling in gold’ in this country can be paid in sterling ;
a gold bond payable in gold dollars can be paid in dollars. This decision
has produced a profound effect upon the significance of the gold price
level in the world and, therefore, upon the present distribution of gold
supplies. For these reasons, while admitting the importance of a change
in the distribution of gold, I do not believe that the present distribution,
or the probable distribution in the near future, constitutes an insuperable
obstacle to the return to the gold standard.

I hope it will be evident that I neither contemplate nor desire an im-
mediate return to the gold standard. Many changes must take place before
such action can be taken with safety. When a new currency measure is

128 SECTIONAL ADDRESSES

passed we shall be legislating not for a year but, we hope, for a generation
or more. It should not be forgotten, however, that the gold standard is
a form of discipline which may itself help to restore some of those con-
ditions that enable it to be operated with success. It is a problem in the
art of government to decide when the necessary changes have occurred,
and how much may be left to the discipline of the standard itself. In
deciding the actual gold value to be given to sterling, I hope that the
post-war difficulties of the unsheltered industries will not be forgotten by
the Treasury.

SECTION G.—ENGINEERING,

SOME EXPERIENCES IN MECHANICAL
ENGINEERING

ADDRESS BY
RICHARD W. ALLEN, C.B.E.,
PRESIDENT OF THE SECTION.

THE variety and range of subject-matter selected for the addresses of
this Section reminds me how vast a field of human endeavour is now
occupied by the engineer ; how manifold are the branches of his pro-
fession ; how diversified are the activities ; and with reflections such as
these, I realised that I could not hope to range over the whole of the
relatively limited though still vast field of mechanical engineering, though
through a life of fifty years I came to the conclusion that for the purpose
of this address ‘ Some Experiences in Mechanical Engineering ’ may be
a suitable subject.

While discussing the progress which has taken place it seems desirable
to give some definition of what is meant by ‘mechanical engineering.’ The
expression is often used loosely, and indeed it is not easy to sum up the
scope of mechanical engineering in a few words. For electrical engineer-
ing activities are almost inseparably interwoven with those of the
mechanical engineer ; and the same may be said of civil engineering.
There is in truth no hard-and-fast dividing line between the various
branches of the engineering profession ; no one point at which we may
confidently say, ‘ Here mechanical engineering ends, and there some
other form of engineering activity begins.’ Nevertheless it is manifest
that if engineering can best be defined as the adaptation of the forces of
nature for the service of mankind, then, I suggest, mechanical engineering
may be described as that branch which deals with invention, design,
construction, and the installation and operation of machinery by means
of which those forces are harnessed and applied.

By the extent to which natural resources are thus utilised one may
measure—materially, if not morally—the degree of civilisation of a people.
The story of the progress of civilisation, in the use of machinery, is a
fascinating but a somewhat neglected study. Just as the accumulations
of succeeding ages have buried the remains of early man, so the rapid
succession of new inventions and the modifications of old ones have
heaped up a quantity of material that tends to diminish our appreciation
of the labours of the past. We are apt to take most things for granted,
and to pay little heed to the efforts of those earlier workers by whose
labours we profit—notably in the use of machines.

¥F

130 SECTIONAL ADDRESSES

The history of discovery and invention constitutes, indeed, a relatively
insignificant portion of ‘ history.” Too frequently does this consist
almost exclusively of a recital of the political changes, the military achieve-
ments, and the rise and fall of nations and peoples, and of the men who
have had brief authority over them. Men and even nations pass and are
forgotten, but knowledge begets knowledge and cannot be stayed, con-
tinuing to expand at a rate which it seems that no past epoch can possibly
rival, while it must be exceedingly doubtful whether the future will afford
a parallel ; but a time will assuredly come when the achievements of men
and matters of the present day will be appraised at their full value.

It is, above all, an age of time-saving and labour-saving devices. If
mechanical engineering is not to fail in its destiny, then its gift to mankind
must be that of increased leisure. It must be admitted, however, that at
present the ‘ load ’ is distributed very unevenly, nearly three millions of
our people being unemployed, so that they must be carried on the shoulders
of the rest. There can be no question that we are now moving so quickly
that it often seems doubtful whether mankind can adapt itself to the
rapidly changing conditions ; and there is thus even a tendency to ques-
tion the advantage of science, and the value of progress, as factors in
human happiness. It is as if conservative and unimaginative humanity,
caught up by a sea of advancing and fast-accumulating knowledge, sorely
buffeted by the waves it has created, is being carried into unknown waters,
far from the lighthouses of past experience.

In mechanical engineering the last few decades have witnessed almost
incredible advances. We who live in these amazing times cannot appre-
ciate the rate of change, and can comprehend only imperfectly the vastness
of the new era. One may recollect that Francis Bacon, whom Sir Richard
Gregory has designated as the great apostle of modern scientific method,
‘aspired to take all knowledge for his province.’ It is a striking com-
mentary upon the progress of science that engineering knowledge alone
is now far beyond the scope of any one man, even though he were of the
mental calibre of the great Lord Chancellor himself.

It may be useful to look back over the past fifty years and consider the
changes which that period has effected in the field of mechanical engineer-
ing. ‘Turning first to electric power plant, we may note that, fifty years ago,
there were no steam turbines, no Diesel engines, no petrol engines—
indeed, no internal combustion engines of any kind other than gas engines.
Again, while the electrical generation, transmission and application of
power were then practically unknown, it is estimated that the world’s
production of electrical energy to-day is of the order of 200,000 million
units per annum. As recently as the year 1895 Lord Kelvin put forward
the statement that he saw no reason why power stations of 100,000 h.p.
under one roof should not be feasible in the future. This prediction,
then regarded. as a fantastic dream, has been abundantly fulfilled, for the
development of this power in one turbo-generator is now accomplished ;
and here we may consider briefly the development of three very important
contributions to mechanical science—namely, the steam turbine, the
Diesel engine, and the centrifugal pump.

The development of the steam turbine has taken place entirely during

G.—ENGINEERING 131

the last fifty years. It was the great pioneering labours of Sir Charles
Parsons, however, which laid the main foundations for the turbine design
of to-day. He saw the need for compounding his first turbine, of reaction
type. This simple non-condensing turbine was naturally very un-
economical, and as a result the condensing turbine was conceived, where-
upon turbine steam consumptions and costs began to approximate to
those of the best reciprocating engines. In the early stages of turbine
development considerable difficulty arose from the fact of this prime
mover being more suitable for large outputs, for which in those times
there was no demand. Parsons next initiated the application of the
turbine to ship propulsion, building the s.s. Turbinia, in which the pro-
pellers were driven direct ; the result being that, while the turbine speed
was too low, that of the propellers was too high to give the best results.

In the meantime the experience gained on the Turbinia had resulted
in the design and adoption of the geared turbine, which not only improved
the position for the smaller sets on land, but also found the solution to
the problem of marine propulsion—namely, a turbine running at a high
speed and a propeller at a much lower one, thus producing a condition
which gave maximum efficiency.

Progress on the marine side has been so rapid that units capable of
developing 50,000 shaft h.p. have been constructed.

On land the progress has been no less rapid, and the application of the
geared turbine has enabled continuous current dynamos to be built for
capacities up to 3,000 kw. per machine. Further, the application of the
geared turbine has been extended to operating various kinds of mills
and to other fields where its greater economy of space and steam con-
sumption give it advantages over the steam engine.

Recent developments in turbine design have tended to endorse the

principle laid down by Carnot, that the temperature of heat supply

should be separated as widely as possible from that of heat rejection.
Thus, total temperatures are creeping upwards. Among other means
of improving the efficiency is that of feed heating by means of steam
tapped off from the turbine between the expansions.

There are many examples of large turbine plant approaching a thermal
efficiency of 30 per cent. from fuel to electricity, and machines have been
constructed giving, at the terminals, one kw.-hour for 10,000 B.Th.U.,
corresponding to a thermal efficiency of the turbine of more than
34 per cent. Although there are turbines at present in commission
developing 200,000 kw., these very large machines, I understand, show
little, if any, improvement in efficiency over a machine having an output
of, say, 40,000 to 50,000 kw. ; and it seems rather unlikely that the size
of unit will tend to increase in the future.

The development of the oil engine is another feature of cardinal im-
portance in recent engineering history. It was only forty-one years ago
that Dr. Rudolf Diesel obtained his famous patent which was destined to
effect a revolution in the design of an oil engine. It was the intention of
the inventor to burn coal direct in the working cylinder, but this was
found to be impracticable, owing to the large quantities of unburnt
residue. He thereupon turned to the possibilities of oil, and, after four

132 SECTIONAL ADDRESSES

years of persevering experiment, the first practical engine was constructed.
It may be that a satisfactory internal combustion engine, utilising powdered
coal as fuel, will be one of the developments of the future ; but so far oil
has proved to be the only fuel capable of satisfactory employment in
engines of the Diesel type.

We may consider for a moment the conditions under which the fuel
was to be burnt in the working cylinder, conditions which—whether the
fuel be in colloidal or liquid form, and whether its injection be by high-
pressure air or by mechanical means—are fundamentally the same to-day.
The Diesel cycle relies, for the ignition of the fuel delivered to the cylinder
during the working stroke, upon the temperature resulting from the high-
compression pressure to which the charge of air is submitted, a pressure
of some 500 lb. per sq. in. Ignition begins at about top dead centre,
and continues for a definite part of the power stroke. The burning of
the charge takes place at roughly constant pressure, the process being
sometimes designated as the ‘ slow combustion ’ or ‘ constant pressure ’
cycle. In comparison with other available types of prime mover, the
earliest practical Diesel engines were thermally very efficient, and this,
together with the manifold advantages of oil for fuel, has led to an
increasing exploitation of the oil engine down to the present day.

The advantages of the Diesel engine for ship propulsion—resulting in
a decided economy as regards fuel, space, weight—were recognised early
in the present century. A milestone in the history of technical develop-
ment is denoted by the launching of the Se/andia twenty-three years
ago, a vessel 370 ft. long, fitted with a four-cycle engine. It is interest-
ing to record that this ship is still in service and very successful results
are still being obtained. During the last twenty years considerable
developments in the building of marine Diesel engines have taken place.

The supply of high-pressure air for fuel injection purposes has always
been a difficult problem. With normal designs, a pressure of at least
1,000 lb. per sq. in. must be available, while the compressors must keep
in tune for long periods of service, involving a considerable maintenance
charge for suction and delivery valves, cooling coils and compressor pistons.
Again, several years before Diesel’s patent, Ackroyd Stuart had made use
of mechanical injection on a low-compression engine, but, in spite of the
various advantages of this system of injection, there was for a long time no
serious attempt to apply it to the Diesel engine. Not only does the
employment of mechanical injection remove the disadvantages associated
with high-pressure air, but dispensing with the compressor drive from the
crankshaft improves engine balance, reduces the overall length and weight
of the power unit, and increases the overall thermal efficiency of the
engine. A notable feature of the mechanical injection engine is the
ability of the governor to take sole charge of the engine throughout the
entire power and speed range, without the necessary complications by
having the blast air supply under control when running under a varying
speed range.’

More recent developments in engines operating on both the ‘ constant
pressure ’ and ‘ mixed pressure ’ cycles have led to gradual but persistent
reductions in the weight and size of the components, thus enabling speeds

G.—ENGINEERING 133

to be raised and the power output per unit of weight greatly increased.
At the present day engines are made of a vast number of different types,
two- and four-cycle, single- and double-acting, vertical and horizontal,
each meeting a particular set of conditions in service. Starting by com-
pressed air is still the most usual method, being universal in the case of
large engines. For traction purposes, however, and for the smaller
stationary sets, electrical and mechanical methods now receive increasing
attention.

There is boundless scope for the application of the Diesel engine, both
actual and potential. Its low initial cost, the limited space required for
its installation, the ease of starting from cold, and its low costs of operation
and maintenance, are all contributory to its great industrial exploitation,
particularly for such public services as water and electricity supply,
sewage and drainage, apart from industrial application. For marine
purposes the Diesel engine is making steady progress in its adoption for
the main propelling machinery. With its convenience and reliability
for auxiliary purposes it is so widely appreciated as to require only passing
mention here. Examples of this type of plant are to be seen in many
modern passenger ships. The recent development of a high-speed
engine, combined with small size and low specific weight, make this
engine particularly suitable in railway work for locomotives, where low
operating costs and low standby losses are essential. This is a sphere
into which the Diesel engine in our country has only recently entered, but
its singular suitability for this type of service encourages one to expect
rapid strides to be made in this direction. So far as industrial road
vehicles are concerned, this type of oil engine has come to stay, while its
resiliency of running has permitted its installation in crowded residential
areas—even in the basements of steel structures consisting of flats, where
freedom from noise and vibration are imperative. There seems, indeed,
to be no limit to the sphere of utility—of necessity, even—for this prime
mover. .

The centrifugal pump is also largely a development of the period under
review. As is frequently the case, the principle was known long before
it was applied successfully to practical uses. There is evidence that
Leonardo da Vinci, the great artist, engineer and inventor, realised the
possibility of utilising centrifugal force for raising water, though the
invention of the centrifugal pump is usually attributed to Johann Jordan.

So far as known records go, centrifugal pumps began to be used for
industrial purposes in the second decade of last century ; but at the time
of the Great Exhibition in 1851 they were still regarded as a mysterious
novelty. One shown by Appold at this exhibition created much interest
because its impellers would pass an orange, this being one of the first
steps in an important modern application of this pump, that of dealing
with solid materials. For a long time the centrifugal pump could not
compete with that of the plunger type for the greater pressures and heads,
its efficiency falling off rapidly in the higher ranges, so that its use was
confined chiefly to low lifts. When Osborne Reynolds’s patent was
disclosed in 1875 the multi-stage turbine centrifugal pump appeared, and
the use of guide vanes was found greatly to improve the hydraulic

134 SECTIONAL ADDRESSES

efficiency at heads which had hitherto been thought quite outside the
range of this pump.

In the pioneer days of centrifugal pump development, when the method
of calculation for design was somewhat rudimentary, a number of basic
facts were discovered experimentally, from which empirical relationships
were devised to meet the various conditions imposed. Later on, the
advances made in the design of high-speed prime movers, particularly
of steam engines and electric motors, gained for this type of pump a pre-
eminence which it has maintained ever since and seems likely to enjoy
for some time to come. ‘To-day, although we have still much to learn,
centrifugal pump design has become a highly specialised study, and
characteristics can be forecast, for numerous combinations of conditions,
with a reasonable degree of accuracy. Compared with the plunger type,
the centrifugal pump has the advantages of much lower capital and main-
tenance cost, with concomitant economy in space and weight, which
renders it particularly suitable for use on board ship. It can be run in
special cases with a shut-off head. It has a reasonable measure of un-
chokeability, while its delivery at constant pressure makes it peculiarly
applicable to boiler feed and similar duties.

A striking application of this pump has been in the handling of coal,
sands, gravels, and the like, where, in spite of the abrasive nature of the
materials, maintenance costs can be kept comparatively low, while lined
pumps of special construction are capable of passing stones and boulders
up to the size of the delivery branch.

The much improved efficiency now obtainable from centrifugal turbo-
pumps has led to a marked increase in their use for waterworks installa-
tions, where the high speed enables large quantities of water to be de-
livered from a comparatively small bore-hole. ‘The pump is suspended,
often many hundred feet below the surface, from a rising main, the
impellers being driven by vertical shafting supported in bearings fitted
to the rising main itself, or, occasionally, by an electric motor which runs
submerged.

A comparatively recent development is the axial-flow type of pump,
and this, with its advantages of reduced weight and space, and higher
speed, may—when dealing with low heads—be said to carry the low cost
of construction and installation a stage further. Because the flow is uni-
directional, the pump being merely an incident in the pipe, higher speeds
can be obtained with lighter prime movers. Intermediate types, partly
centrifugal and partly axial-flow, have also been devised. While no one
dare prophesy as to the future of the pump, it would appear that both
centrifugal and axial-flow types are in essence so simple that it is difficult
to see how any future improvement can be expected, except in detail.

These technical developments have amazingly increased the field of
application of the centrifugal pump, particularly for graving and floating
docks, impounding for wet docks, and in the drainage of watery wastes
and the irrigation of barren deserts, so as to bring large areas of ground
previously unproductive into a state of high fertility—often affording,
indeed, a sure means of subsistence to peoples whose very existence had
hitherto been precarious. In our own country, before the beginning of

G.—ENGINEERING 135

the present century, only a comparatively small area of the fenland had
been drained, and then almost entirely by antique methods, as by scoop
wheels driven by windmills or beam engines, whose efficiency was in
inverse ratio to their esthetic value. Here the development of modern
steam and oil engine-driven centrifugal pumps has supplied a consider-
able impetus to reclamation. In China and Japan great areas of waste
land have similarly been drained and brought into cultivation.

The economic advantages of irrigation work in Egypt and the Sudan
are familiar to many. In Egypt during the last fifty years the develop-
ments are very remarkable for their size and number of installations.
Only after a visit to that country can one fully appreciate the vastness of
the enterprise and the work carried out there by the engineer. In the
Sudan, irrigation schemes date from the Battle of Omdurman, when the
power of the Mahdi was broken by Lord Kitchener, and the tribes of the
Sudan, whose previous occupation had been largely that of war, had
somehow or other to maintain themselves in a country ill supplied by
nature with the means of peaceful existence. The suggestion that cotton
could be successfully grown in the Sudan, followed by the construction
of experimental pumping stations—even so far afield as Fashoda—was
crowned with success, leading to the foundation of the Gezira Irrigation
Scheme and to the formation of the Sudan Plantations Syndicate, so that
to-day the Sudan furnishes a considerable proportion of the world’s
supply of this commodity, and of the highest quality. In many other
countries, as Australia, New Zealand and elsewhere, irrigation methods
only possible by the installation of modern pumping plant have resulted—
as, for example, at Mildura—in the development of Australia’s great fruit-
growing industries.

Another field in which production has been greatly increased by
mechanical methods is the tin industry of the Federated Malay States.
The antiquated Chinese method of raising water from mines by means of
hand buckets, sometimes in one or two up to as many as six stages, was
slow, laborious and costly, as compared with the use of a centrifugal pump
of modern type. Again, the method of hydraulicing—where a jet of
high-pressure water is directed against a hillside, so as to wash it com-
pletely away for treatment—has provided still further scope for the use
of centrifugal pumping plant.

Shipbuilding has always been one of our national industries in which
we Britishers take a legitimate pride—an industry in which we are leaders
throughout the world. Wherever the British flag flies, in the Navy or
the Mercantile Marine, graving or floating docks are to be found. To the
engineer the design and construction of such docks present problems of
absorbing interest—problems ever new, since the conditions to be faced
differ widely between one country and another, requiring special treatment
to suit the local surroundings.

To deal adequately with the pumping machinery required for graving
and floating docks both at home and abroad would take too long, but
nevertheless it is a subject which has always appealed to me as one not
only fascinating but full of romance.

A survey of recent mechanical progress, though only in outline, would

136 SECTIONAL ADDRESSES

be incomplete without reference to the various classes of machinery used
for purposes of production. Nevertheless the changes which have taken
place in recent years are so extensive that they can only be indicated here
in general terms. It would be difficult, without reference to illustrations
in the records of the time, or to actual exhibits such as those in the Science
Museum at South Kensington, to convey to the younger generation of
engineers how elementary was most of the industrial machinery of 1883
compared with that of to-day—how relatively limited in quantity, capacity
and range. Yet already the seeds of change had been sown. For several
decades British ideals in machine construction had been in conflict with
those which had found their way to this country from abroad. British
engineers were accustomed to an ample factor of safety, massive design,
slow-speed operation, and a regard for appearance. On the other hand,
engineers in foreign countries were undoubtedly more ready to experi-
ment freely with novel designs, and were responsible for introducing into
this country what was then known as the ‘ manufacturing principle,’
whereby large numbers of standardised articles were produced by repeti-
tion processes, with the aid of special-purpose machines designed for
a single operation, thus reducing the necessity for skilled labour. As
far back as 18541 it is recorded that Joseph Whitworth visited the United
States and reported favourably on machinery for repetition work. In
devising machinery of this kind, he reported, ‘ the Americans showed an
amount of ingenuity, combined with undaunted energy, which we would
do well to emulate if we meant to hold our present position in the great
markets of the world.’ About the same time James Nasmyth had visited
the Colt pistol factory, then newly established in England,? and confessed
that he had felt humiliated by the experience. He remarked further
that ‘ The acquaintance with correct principles has been carried out in
a fearless and masterly manner, and they have been pushed to their fullest
extent ; and the result is the attainment of perfection such as I have never
seen before.’* But though British engineers of outstanding ability thus
gave generous recognition to the lessons which were to be learnt from
abroad, there was—as Nasmyth himself pointed out—‘ a degree of timidity
resulting from traditional notions, and attachment to old systems’; and
this conservatism, no doubt reinforced by relatively lower labour costs,
still held back the thoroughgoing mechanisation of British industry
fifty years ago, and indeed for long afterwards. But in the end, with our
well-known genius for compromise, we have succeeded in combining the
best features of both types, with the result that British machinery still
maintains its high prestige in the markets of the world. It is noteworthy
too that other countries have not hesitated to benefit by the high
traditions of design and workmanship which have always been upheld by
British engineers.

But though the adoption wherever possible of repetition methods,
involving standardisation and interchangeability of parts, had a marked

1 New York Industrial Exhibition: Special Reports of Mr. George Wallis
and Mr. Joseph Whitworth, Parliamentary Papers, 1854, vol. xxxvi.

2 Colt’s factory established in England, 1851.

3 Select Committee on Small-Arms, Parliamentary Papers, 1854, vol. xviii.

G.—ENGINEERING 137

influence on mechanical engineering progress, there was another influence
which was destined to bring about revolutionary changes in the design
and construction of machinery, in this country and, indeed, the world
over. This was the gradual substitution of science, and the scientific
method, for the ‘ rule-of-thumb’ procedure of the so-called ‘ practical
man.’ The change in this regard has taken place almost entirely during
the past fifty years.

As Sir Alfred Ewing pointed out in his Presidential Address to this
section a few years ago, there were in 1881 a few great leaders—a Kelvin
or a Hopkinson—who possessed the right kind of basic understanding,
who could turn to theory for guidance and had the engineer’s instinct to
give it application. But most of the zealous workers of those days were
groping in what was at best a half light, full of enterprise and enthusiasm
and not much more. But the few great mentors to whom Sir Alfred
Ewing referred were the pioneers who helped to bring about what I
believe to have been a great material revolution in human affairs. For it
was they, together with other leaders in the universities and elsewhere,
who laboured at the development of engineering theory, and who first
taught us to realise the illimitable benefits to be secured by the application
of physical science to the whole range of engineering activity. When
I look back over the period now under review I realise that the greatest
lesson conveyed is that the advancement of engineering is in the last
resort determined by the advancement of physical science. I would,
indeed, go further, and say that my experience, specialised though it has
been, has taught me that the whole structure of modern civilisation rests
upon the progressive application of physical science to the ever expanding
requirements of mankind.

During the past half-century there has been a similarly phenomenal
development in many other branches of mechanical engineering, notably
those concerned with the naval and military services, radio-communica-
tion, aviation, transport (including rail and road), etc. etc. Considerations
of time make it impossible to deal adequately with these developments
here, but, as we have already seen, it seems certain that at no previous time
in the history of the world has mechanical development been so rapid.

While the history of engineering development is a fascinating subject,
we have to live in the present, at a time when economic considerations
have become of vital importance in their bearing upon technical matters,
so that no apology should be necessary for discussing very briefly the
scientific methods of carrying out an engineering installation of to-day.

Years ago any engineering firm of repute could obtain a considerable
proportion of its work with no particular effort, sometimes even without
the necessity of preparing a contract. Such times have gone by. There
is severe competition for what seems often a somewhat limited amount of
work, and sustained and intensive effort is necessary to secure the amount
of business requisite to keep open one’s works. ‘The soil must be tilled
diligently—sometimes, indeed, for years—before the crop is reaped.
To achieve this end no effort must be spared. A prospective customer
often requires much education as to the savings which will accrue from the
substitution of new and modern plant for his obsolete machinery, and to

F2

138 SECTIONAL ADDRESSES

appreciate fully the varying considerations of first cost, running expenses,
maintenance charges, and the like. Where, as with Government depart-
ments or municipal authorities, the scheme has often been developed to
a considerable extent before tenders are called for, less preliminary work
by a firm is required. The difficulties of preparing an estimate are not
always fully appreciated, for changes in the costs of labour and materials
must be envisaged, while urgent work will require the working of over-
time, at higher rates. Consideration must be given to the financial stand-
ing of the customer, the necessary safeguards for both parties must be
provided, and, in recent years, where foreign customers are concerned,
the fluctuating rates of exchange have created further problems with
corresponding anxieties.

In the engineering of a large installation it is not always possible for
those at the head of affairs to attend to more than the general scheme.
An engineer of suitable experience is consequently deputed to conduct
the whole contract in all its branches, and he will call upon the technical
experts attached to the various departments concerned. A document,
referred to as a technical order sheet, is issued containing a concise synopsis
of the client’s specification, all special requirements and relevant matter
concerning duties, speeds, consumptions of the various units comprising
the whole installation. ‘This document must further contain all informa-
tion necessary for the various departments of offices and works. Accurate
detailed records must be kept of all expenditure incurred in the con-
struction and installation of the machinery. This can best be done by
assigning to each section of the work a letter to indicate the class of
machinery, and a series of numbers to denote the individual items. ‘These
identification marks will be stamped on each of the parts and will appear
finally upon the finished article, thus facilitating the ordering of spare
parts at a later date. Against these numbers, the draughtsman will book
his time, the foreman will draw his materials from the stores, and the
workman will fill up his time sheets. The cost office will then have no
difficulty in ascertaining the expenditure at any stage of a contract, and
will ultimately arrive at the total cost in full detail, for guidance in future
estimates.

The question of housing the machinery has also to be considered, and
if new plant has to be erected and operated beside existing plant which
must meanwhile be kept running, difficulties may arise, the overcoming
of which may call for ingenuity and resource of a high order. The
preparation of drawings is the most important step in the earlier stages
of a contract, and success will depend very largely upon the amount of
thought and time that has been given to the work in the design and
drawing office. As in the case of correspondence, so also with the drawing
office, one leading draughtsman must be in charge of the whole of the
work, so that the various sections of the scheme may be in harmonious
relation with each other. Having obtained all the necessary technical
details from the design office, the leading draughtsman will prepare
a preliminary lay-out of the scheme, and this is critically examined, in
conjunction with the customer, to settle any new points which may then
have arisen. When all has been suitably arranged, a general arrangement

G.—ENGINEERING 139

drawing is prepared, followed by detail drawings of the larger parts,
which are issued to the pattern shop and forge, while foundation drawings
are sent to the customer, so that the buildings can be constructed or
adapted. Drawings of all remaining details and pipework will follow,
complete with lists of material and any special drawings for erection on
site.

An important section of the works manager’s organisation is the plan-
ning department. This department will interest itself in preparing
a programme of dates by which the different items must be complete in
pattern shop, foundry, smiths’ shop, machine shop, erecting shop, etc.,
so that the promised delivery date will be adhered to. ‘This also involves
a programme of work for the larger machine tools extending possibly
six months ahead, specifying the hours allowed for the different operations.

The quality of the materials is the concern of the works laboratory,
which must ensure that all material specifications are complied with, and,
where the customer’s inspector desires to witness tests, must arrange for
these to be carried out without the causation of delay in delivering the
material in question to the machine shops. In addition to such routine
testing, the laboratory should carry out considerable investigatory work,
to keep up with the ever-increasing demands of the designer and for the
improvement of materials generally. Those parts of the machinery
required to withstand pressure must be subjected to hydraulic tests some
50 to 100 per cent. in excess of the maximum anticipated.

Where possible, running tests are made at the firm’s works under condi-
tions approximating to those on site. A Diesel engine and dynamo set
should be tested separately, the engine by the dynamometer brake method,
and the dynamo electrically ; and a combined test may finally be run in
the presence of the purchaser. The testing of steam turbines usually
presents greater difficulties by reason of the great variation in conditions,
but enough data must be thus accumulated on which to base a judgment
of performance. Pump testing has also its complications, for a mine
pump may deliver a small quantity of water against a head of 3,000 ft.,
while a graving dock pump may be required to handle a large quantity
against a head of less than 50 ft.

Transport of the finished machinery to site must be considered from
the efficiency point of view by rail, road, water, or air, the last named from
necessity rather than efficiency.

In concluding this part of the address which refers to engineering
works of various kinds, I have endeavoured to show the changing circum-
stances in which we live to-day and the difficulties which we have to face,
requiring constant research and experiment. I would here like to pay
my tribute to the Director, Sir Joseph Petavel, and his staff at the National
Physical Laboratory, and express my gratitude for the help they have so
readily given. It is my experience, and I recommend it to others, that
when one is faced with a difficult problem the staff at the National Physical
Laboratory is always ready to offer advice. I have not forgotten the recent
meeting held at the Royal Society, under the chairmanship of Sir Richard
Glazebrook, when a discussion took place on the suggestions for research
work required for the advancement in engineering.

140 SECTIONAL ADDRESSES

Further, all engineers owe a debt to the British Standards Institution,
a very live body under the able directorship of Mr. LeMaistre, which
has secured for our country a leadership in standards. Much time is now
saved by the adoption of the various standards recommended by the
Institution.

Here also I must refer to the invaluable services rendered by the
technical Press of this country—of which those old-established journals,
The Engineer and Engineering, are outstanding examples and repre-
sentative of all that is best in modern journalism. It may be safely
asserted that no news service throughout the world is actuated by higher
principles, has a greater regard for accuracy, or shows a more steadfast
sense of responsibility than that provided by our technical journals. The
result is a trustworthy and highly educational record of engineering
progress, illustrated by admirably selected examples of recent practice and
developments both at home and abroad. To the leading articles in these
journals most of us have long been accustomed to turn for helpful and
stimulating comment upon matters of current interest.

Having dealt very briefly with a few reflections and given examples of
modern engineering, this cannot be regarded as a complete story without
a few remarks on the subject of the human side of engineering.

I have frequently been asked the question by many professors in
engineering, ‘ What kind of work do you give our students todo?’ That
is a natural question, and the answer is largely dependent on the young
engineer’s outlook after he has served his pupilage.

The system of training which I am interested in was started by my
father over fifty years ago, established on a sound basis, and has proved
remarkably successful. The scheme has been modified from time to
time to keep pace with changing circumstances, especially post-war
conditions.

It will be obvious that the industry cannot be carried on efficiently
without a continuous supply of highly trained engineers and craftsmen,
and the training of the engineer is the all-important question. All
systems of workshop training should be available without payment of
premium, and it is now general practice to pay wages to all students and
apprentices. It is necessary to provide workshop training for three main
classes of students. First, there is the student who wishes to become
a professional engineer, capable of taking highly responsible positions on
the administrative, executive, technical or commercial sides of the
industry. There is, and there always will be, a considerable diversity of
opinion as to the merits of different systems of training for the higher
posts, and, since the characteristics and personality of the individual are
varied, it becomes obvious that the course which is ideal for one is
not necessarily best suited for another. In any case, a university training
is desirable, as developing a disciplined mind and ensuring that thorough
grounding in the fundamentals without which no engineer can be complete.
An essentially Scottish system of training, which has proved very success-
ful, is the ‘ sandwich system’ of winter in college and summer in the
works. It is sometimes advocated that a student should undergo some
years of works training before proceeding to the university. My own

G.—ENGINEERING 141

experience leads me to believe that a university course, followed by works
training, will be found generally most successful. Having completed the
university portion of his training, it is not advisable for the student to
decide upon the particular section of the industry in which he will engage,
for, without a thorough working knowledge of the whole, neither he him-
self, nor those who have so far been responsible for his training, can possess
sufficient data about his capabilities, or the particular branch of engineer-
ing for which he is most suited. Before this is decided it is essential that
he should spend three years in some selected engineering works, passing
from the pattern shop through the foundry to the forge, on to the machine
and fitting and erecting shops, through the steam engine, oil engine, and
electrical testing departments, and so on to the drawing and design
offices. Interspersed among this portion of his training there will be
various periods of erection work either at home or abroad. Some time
in his third year of training he and his superiors can begin to form an
opinion concerning the branch in which his particular abilities can be
most fruitfully employed. He may be mathematically minded, in which
case he would be most useful on the scientific and technical side, A man
of strong practical bent would find ample scope for his talents in some
such post as that of assistant to the works manager. Or his predilections
and personal attributes may constitute him an ideal salesman; or he may
have a desire to go abroad. In the training of the engineer this practical
experience, obtained in all the main departments of a large works, must
be regarded as a fundamental necessity, and he will obtain at the same
time that contact with and understanding of his fellow-men which will
give him a capacity for co-operation and leadership, indispensable for the
professional engineer of to-day.

There is next the student who comes into the works from a public or
secondary school, after reaching School Certificate or Higher School
Certificate standard. He may ultimately attain to the same posts as are
available to the university-trained student, but the road is harder, and only
to be traversed by those possessed of enthusiasm and determination. Not
only must he pursue a three or four years’ course, passing through all the
main departments, but he must also attend evening classes, so as to raise
his education as nearly as possible to the standard of the university student.
During his passage through the works he must become a student of one
of the three institutions—Civil, Mechanical and Electrical Engineers—
and, if his capabilities be wide enough, he should take an external uni-
versity degree. Much hard and intensive work is entailed, and there are
many who fall by the wayside, either from physical disability or flagging
enthusiasm. But those who succeed, whose character impels them to
overcome, by pains and tribulation, an initial handicap which can prove
very hampering, are among the salt of the profession.

A further problem of industrial training is involved in the production
of craftsmen, chiefly recruited from boys leaving an elementary school at
the age of fourteen or fifteen, who, after a preliminary probationary period
in the works, are apprenticed, at the age of sixteen years, to some par-
ticular branch of the trade. It is obvious that the general training of any
such boy must continue in some way or other during the whole of his

142 SECTIONAL ADDRESSES

apprenticeship, for only thus can he acquire the educational and technical
equipment necessary for his duties and position. ‘The way to the attain-
ment of more responsible positions must not be barred even to these, who
should not be allowed to pursue their way unencouraged by the hope of
attaining a worth-while goal. ‘Thus, while the boy, during his five years’
apprenticeship, is attending evening classes and seeking to acquire know-
ledge in all possible ways by which to qualify himself for the pursuit of
his trade, he should be able, by competitive examination in the works, to
qualify for a ‘ student scholarship,’ from which point he may advance to
positions normally open only to those with university or equivalent
training. The ‘ scholarship ladder’ from the elementary school to the
university must have its equivalent ‘ apprenticeship ladder ’ in the works,
and it must be just as possible to-day for another George Stephenson to
begin at the bottom of the social ladder and achieve the heights above.

The training of boys other than apprentices presents an even more
difficult problem. Such boys may often be temporarily engaged in
‘ blind-alley ’ occupations, and it is essential to provide for their transfer,
at a sufficiently early period, into other channels which provide proper
opportunities for advancement and the attainment of a satisfactory status.
Any boy worth training should, of course, become an apprentice, when
his training is automatically provided for.

Training, however, is not confined solely to the material and technical
side. Although the passage of a student through any works may appear
to be a severe and laboriously practical affair, it should at the same time
engender a spirit very much akin to the Public School spirit, which is
essential to the formation of a true engineering character. Amongst our
own students at Bedford this spirit is fostered, even though past students
may be scattered over the whole world, by the publication of an annual
Works Magazine, and the formation of a Past and Present Students
Association, which holds an annual reunion and dinner, maintaining
contact which is so valuable.

One cannot leave this subject without paying a justly deserved tribute
to the craftsman upon whom devolves the task of translating the ideas of
others into practical shape. The production of work of the first quality
necessitates the loyal and intelligent co-operation of all, and the quality
of the finished article reflects the ability of every one of those responsible
for its production. ‘There must also be remembered those who are sent,
often abroad, to bring the erection and completion of some engineering
works to a successful issue. Such men must possess ability, character,
and that quality of leadership which, difficult though it may be to define,
is none the less real and essential. Circumstances may sometimes be
those presenting unparalleled difficulties, but the fact that they are in-
variably overcome, and that other countries have on occasion employed
British engineers to erect their work, affords striking confirmation that
they stand pre-eminent in their craft.

I must here refer to the work of the Institution of Mechanical Engineers.
The Institution was founded with the objects of promoting the theory
and practice of the science in all its branches, to promote inventions use-
ful to its members and the community, to afford opportunities for the

G.—ENGINEERING 143

meeting and interchange of ideas, and the collection and publication of
information concerning mechanical engineering in general. To the
development of both the science and the art the Institution has made
many notable contributions, and the advancement in status of the
mechanical engineer of to-day is due very largely to its intensive and
continued efforts.

The work of this body has been no less valuable in the matter of train-
ing. The successive stages of Studentship, Graduateship, Associate
Membership and full membership of the Institution—combining an
examination with the requisite practical experience for each grade—
constitute a means of qualification for higher posts, and this course
should be followed by every young student, whether or not he already
possesses a university degree. ‘To the student who does not, it affords
an alternative qualification of the same merit. That the Institution has
faithfully pursued the aim of giving the widest possible training and the
amplest of opportunities to those young men whose education is not of
university standard is patent from the fact that it provides, to the ele-
mentary school boy, a means of attaining further knowledge. Thus, by
attending the evening classes of any recognised technical institute, and by
dint of hard work, he can obtain National Certificates in Engineering
subjects, exempting him from certain portions both of the Studentship
and Associate Membership examinations. From this point his education
and works training can proceed, side by side, until he is elected an
Associate Member. The university engineering graduate, provided he
possesses the requisite works experience, may be elected to the Associate
Membership without further examination. It will be clear, therefore,
that—largely by the efforts of the Institution—a complete scheme of organi-
sation for training in mechanical engineering exists in this country,
and that the way to advancement is in no way barred to the young student
who has not had the advantage of a university training, so that an adequate
supply of trained engineers should thus be assured.

It is widely recognised to-day that too intensively mechanised an
existence has a somewhat soul-destroying tendency. Welfare work is
designed to counteract this influence, and may be defined as a systematic
and sustained effort to humanise industry. The efficient worker must
enjoy both physical and mental health, must possess undistorted ambition,
and must have a true conception of citizenship and his responsibility to
all his fellow-men. The making of a community of such individuals is
the aim of welfare work. The need for such work would be demonstrated,
if it were not already self-evident, by the fact that the Industrial Welfare
Society now numbers among its members most of the leading firms in
the country. The Society is particularly fortunate in having for its
President H.R.H. the Duke of York. All engineers who have the welfare
of the industry at heart must be infinitely grateful to His Royal Highness
for his leadership in this vital matter, not only for the interest he shows
and the great amount of time which he devotes to visiting so many works,
but for the many practical suggestions for the betterment of conditions
which he has made. It is impossible to overestimate the importance of
welfare work among young men, for they are the next generation of

144 SECTIONAL ADDRESSES

engineering workers. ‘The welfare supervisor is responsible for the mental .
and physical well-being, the work, the progress and the destiny of each
individual, and he must endeavour to provide such amenities as will lead
to the achievement of happiness and the making of good citizens. Many
works now provide a Boys’ Club, by which the natural desire of all boys
for companionship may be fulfilled and a spirit of team work promoted.
Indoor games of all kinds and reading and writing rooms should be
provided. The club should be run entirely by the boys themselves,
who thus learn the meaning of corporate life and individual responsibility.
The need for physical training is now becoming much more widely
recognised, and a gymnasium is thus an important adjunct. For the
welfare of the employees generally there should be the library, and the
‘recreation club,’ possessing its own sports field, where the sporting
instincts of all employees—embracing the vigours of football, cricket,
hockey, tennis, etc-—may be catered for; while the sociable habits of
the men are also fostered by the ‘ Men’s Institute.” In the case of many
firms much, indeed, is done, and very little is left undone, to improve the
conditions of all employees, both within and outside the works, and such
amenities cannot but result in a general widening of outlook and a greater
happiness.

In conclusion : these, then, are a few of the thoughts that have occurred
tome. Whatever their worth, they have at least this advantage—that they
are the product, not of ‘a cloistered seclusion, far from the heat and dust of
life,’ but are directly derived from personal contact with, and observation of,
men and things. And this, after all, is the essence of the scientific method
as I understand it—to learn as far as possible directly from observation
and experiment rather than indirectly from books. I find this view
upheld by one of the greatest of former Presidents of the British Associa-
tion, the late Prof. T. H. Huxley, who said: ‘The great benefit
which a scientific education bestows, whether as training or as knowledge,
is dependent upon the extent to which the mind of the student is brought
into immediate contact with facts—upon the degree to which he learns
the habit of appealing directly to Nature, and of acquiring through his
senses concrete images of those properties of things which are, and always
will be, but approximately expressed in human language.’

SECTION H.-ANTHROPOLOGY.

WHAT IS TRADITION ?

ADDRESS BY
. THE RT. HON. LORD RAGLAN,
PRESIDENT OF THE SECTION.

A DICTIONARY definition of tradition is ‘ anything that is handed down
‘orally from age to age’; that definition I propose to adopt, and shall
begin by considering what it is that is handed down orally from age to
age. ‘Tradition then consists of—

(1) Methods of farming. Traditional methods are in most places
followed in breeding, feeding, milking and killing animals; in
ploughing, manuring and sowing the land, and in harvesting and
storing the crops.

(2) Methods of craftsmanship. Houses are built; weapons, tools,
implements, utensils, clothes and ornaments are made, in most
cases, by traditional methods.

(3) Methods of eating, drinking, and preparing food.

(4) Methods of dealing with property. Even in civilised countries
systems of land tenure, inheritance, and transfer of property are
usually traditional.

(5) Marriage customs and ceremonies ; bride-price, divorce, etc.

(6) Rites and ceremonies at birth, death and initiation.

(7) Etiquette. There are traditional ways of saluting, and of eating,
dressing, and behaving in company.

(8) Superstitions.

(9) Games, sports, songs and dances.

(10) Traditional narratives.

Leaving aside for a moment the traditional narrative, we may then
regard tradition as a code which, entirely in the case of the savage and very
largely in the case of the civilised, regulates the conduct and activities
of mankind throughout life. However much tradition may vary from
group to group, it always has this in common, that it must be learnt in all
its aspects by the younger members of the group, whatever the group may
consist of, before the older members will admit them to the full privileges
of membership. Whether a tradition is rational or irrational makes not
the slightest difference; traditions about unlucky days or unlucky
numbers are enforced as strictly as traditions of honesty and truthfulness.
The traditions of our best schools and professions contain many absurdi-
ties, as do those of our courts of justice and of Parliament.

Tradition, then, is a code of rules, covering every aspect of human life,

146 SECTIONAL ADDRESSES

which, though not taught by schoolmasters or enforced by the police, is
handed down orally from the older to the younger members of the group,
and enforced by public opinion within the group.

To this description there is one apparent exception, the traditional
narrative, and to this I shall devote the remainder of this address. It
must, however, be borne in mind that in any group the traditional narra-
tive forms a mere fraction of the great body of tradition, of which some
at least of the other forms are of far greater sociological importance.

The traditional narrative takes various forms, such as myth, legend,
epic poem, ballad, saga and fairy tale. It has been usual in the past to
divide these into two main classes, those which were believed to contain
a kernel of genuine historical fact, and those which were regarded as
purely fictitious. With fiction I shall deal later ; I shall now consider
the claim of the traditional narrative to be the repository of historical fact.

Tue Basis oF History.

The theory that traditional narrative embodies historical fact is based
on the assumption that among the members of every community in which
quasi-historical narratives are related there exists, and has existed for
hundreds or thousands of years, a strong and continuous interest in the
past history of the community, and a strong and continuous desire to
preserve the facts of that history as accurately as possible. ‘There appears
to be no evidence to justify such an assumption.

Why should anyone wish to know what happened before he was born ?
There is no obvious reason, and as a fact very few people do. All over the
world we find people living in the neighbourhood of ancient ruins without
taking the slightest interest in them. NHistoric monuments are being
destroyed in England to-day, and by educated and responsible persons.
If we wish to know who lived in a certain house a hundred years ago, it is
of little use to ask the local inhabitants ; we may find some elder whose
father worked there, but the odds are against it. Do we find, in any part
of the world, young people sitting at the feet of the aged, and eagerly
drinking in all that they can tell them of the events of their youth ?
Nowhere that I have ever heard of ; the old man in his anecdotage is
universally regarded as a bore.

Even when there is some slight interest in local history, it is the result
of inquiries by students or tourists ; persons who study local history are
called antiquaries, and they are rare in the most civilised countries.

As regards general history, he would be an optimist who would maintain
that 1 per cent. of the inhabitants of Europe had any real knowledge of
or interest in the subject. It is true that at times and places of high
general culture there have often been a certain number of persons who
studied history in the hope of understanding how people thought and
acted under different social conditions, or of finding in the past the key
to the future. It is also true that since the time of Herodotus many of
the masterpieces of prose have been historical works, and that history has
therefore tended to form part of the educational curriculum. None of
these considerations, however, could affect the illiterate, who are interested
in the present and the immediate future, but never in the past.

H.—ANTHROPOLOGY 147

The only writer on tradition who has touched on this point, so far as
I can learn, is Prof. Chadwick, who says: ‘ 'The existence of a poem
‘or story which deals with reminiscences of tribal conflicts necessarily
* presupposes an absorbing interest in tribal history.’ He goes on toshow
that this interest could only be due to patriotism, but fails to realise that
patriots are notoriously indifferent to facts; any fable which gratifies
their national pride is history to them. ‘The conclusion seems to be that
since illiterate persons are never interested in history, historical facts can
never be transmitted by illiterate persons.

In case, however, we may be thought to have gone too fast, let us ask
another question: should illiterate persons wish to transmit historical
facts from age to age, would they be able todo so? Let us first be clear
as to what we mean by ‘ from age to age.’ We do not speak of our
parents’ reminiscences as tradition, or apply the term to anything that
happened within the memory of living men. We apply it only to events
which may be supposed to have happened in the more or less remote past.
We must also note that when a tradition is written down it ceases to be a
tradition, and becomes merely the account of a tradition, unless we can
be sure that those who repeat it have not been influenced by the written
record. We may say then that a traditional narrative is one which has
been handed down for at least a hundred years by people who have
derived it from purely oral sources.

Let us now consider what are the sources of history. Apart from
archeological evidence, which, however valuable, is seldom a guide to
actual incidents, we may divide them into four classes :

(z) Accounts written at the time by persons who were present at the
events which they describe—letters, despatches, memoranda,
diaries.

(2) Accounts written by persons who were present, but not till some
time afterwards—autobiographies, reminiscences, inscriptions.

(3) Accounts written by people who obtained their information from
actors or spectators shortly after the event—annals, chronicles,
proceedings of trials, newsletters, press reports, diplomatic corre~
spondence. These would not be accepted as evidence in a court of
law, but are often very properly accepted by the court of history.

(4) Accounts obtained by questioning people as to what happened a
long time before, or accounts obtained at second or third hand.
These are often recorded as survivors’ tales, conversations, memories,
gleanings.

Now it should be clear that the first three are, in varying degree, the
only genuine sources of history. The fourth may be useful for reconciling
discrepancies or filling in details, but would not be accepted as a satisfac-
tory authority for a fact otherwise unknown. I know an old gentleman
living not far from Leicester who has personal reminiscences of the
French Revolution of 1848, but the fact would hardly be accepted on his
sole authority. Second-hand evidence is not admitted in a court of law
because it is notoriously unreliable. It is admitted by historians, but

1H. M. Chadwick, The Heroic Age, p. 273.

148 SECTIONAL ADDRESSES

only if it is given by persons especially well placed or well qualified to
obtain it. No one would accept a fact on fourth-hand evidence alone,
yet this is what tradition is at best. Why historical facts should be capable
of accurate oral transmission for hundreds and even thousands of years,
while no other fact can pass down the length of a street without hopeless
distortion, no one, so far as I can learn, has attempted to explain. Until
someone has done so I shall feel justified in concluding not merely that
no illiterate person has ever wished to transmit an historical fact, but that
no illiterate person would be capable of transmitting an historical fact even
if he wished to, and that M. Gaston Paris was right when he said that there
was no such thing as historic oral tradition.

‘TRADITION AND IMAGINATION.

At a later stage I shall give illustrations showing that incidents which
occur in tradition are never historical, and, conversely, that historical facts
never find their way into tradition. Here it will be convenient to deal
with the belief that certain forms of the traditional narrative are the result
of imagination, and then to set out my own view of the origin of the
traditional narrative. ‘The attempt to divide it into two classes, the his-
torical and the imaginative, has been made by various writers, notably
Hartland, MacCulloch and Krappe.?

Hartland tells us* that the art of story-telling is the outcome of an
instinct implanted universally in the human mind, and that in the Marchen
or fairy tale ‘ the reins are thrown upon the neck of the imagination.’
MacCulloch says that all over the world simple stories were invented,
and that ‘ as time went on and man’s inventive and imaginative faculties
‘ developed, these simple stories . . . became incidents in longer tales.’ 4
Krappe says that it is ‘ certainly excusable to take the common-sense view,
‘ and to regard the fairy tale as a definite type of popular fiction, primarily
‘ designed to please and to entertain.’ ®

Having stated it as an axiom that fairy tales are the product of the
story-tellers’ imagination, all three writers proceed, with a convenient
inconsistency, to show that no story-teller ever displays any imagination
whatever. It will perhaps suffice to quote Hartland. He says that ‘ it is
‘ by no means an uncommon thing for the rustic story-teller to be unable
‘to explain episodes in any other way than Uncle Remus—‘ She wuz in
‘ de tale, en de tale I give you like hit were gunto me.”’ After telling us
that Gaelic stories often contain obsolete words; that Swahili story-
tellers hardly understand the sung parts of their stories, and that Eskimo
story-tellers have to stick as closely as possible to the traditional version,
he concludes that, wherever and whenever stories are told, ‘ the endeavour
“to render to the audience just that which the speaker has himself received
‘ from his predecessors is paramount.’® ‘Then where does the imagina-
tion come in? There is no more evidence that illiterate people invent
fables than there is that they transmit historical facts. We must seek the
origin of the traditional narrative elsewhere.

* E.S. Hartland, The Science of Fairy Tales; J. A. MacCulloch, The Childhood
of Fiction; A. H. Krappe, The Science of Folklore.
SSP pirn23: 4 P. 457. SIPHyire 6 Pp. 18, 21.

H.—ANTHROPOLOGY 149

THE ORIGIN OF THE TRADITIONAL NARRATIVE.

I said at the beginning of this address that all forms of tradition, with
the apparent exception of the traditional narrative, were rules of conduct,
and I do not believe that the traditional narrative is really an exception
at all. In my view all traditional narratives are, or once were, rules—
rules for the performance of rites or ritual dramas. Every rite or drama
necessarily consists of a sequence of incidents, and the account of such rite
or drama is therefore necessarily in narrative form. Unlike historical
events, the interest of which can seldom be more than academic, the
account of these rites must be preserved, because on their correct per-
formance is believed to depend the prosperity of the community, and can
be preserved because, unlike historical events, which occur but once, and
usually in the presence of but few, these rites are performed repeatedly,
and in the presence of all. Many of these rites and these narratives are
world-wide, or nearly so, but variations occur, because there is always a
tendency to tighten up the ritual in times of adversity and slack off in
times of prosperity, and the narrative, being an account of what has been
done rather than what zs done, is usually a little different from the ritual.
Finally, in many cases, the ritual ceases altogether to be performed, but
the narrative has itself acquired sanctity, and may be passed on, neces-
sarily with minor modifications, for many generations, until at last it is
either written down or forgotten.

In my view this represents, in brief, the history of every genuine tradi-
tional narrative. I hope to make this view convincing by the performance
of three tasks : the first is to show by illustration that there is no connec-
tion between tradition and history ; the second is to show that the ritual
drama has in fact played a large enough part in the life of mankind to
account for the number and variety of the traditional narratives ; the third
is to show that the features of these narratives can be explained, and can
only be explained satisfactorily, as features of the ritual drama. It will
first, however, be as well to deal with two forms of pseudo-tradition, the
* family tradition ’ and the ‘ local tradition.’

‘ FaMILY TRADITION.’

There are in this country many families whose ‘ traditions ’ take them
back to the time of the Norman Conquest, when their ancestors are
alleged to have distinguished themselves either on the side of the Normans
or of the Saxons. It can be said without fear of contradiction from those
who have studied the subject that not one of these is a genuine tradition.
All are the work of pedigree fakers, who have flourished from very early
times, and there is not a word of truth in any of them. No English
family can trace a genuine descent to the Saxons, and though there are a
few families with a genuine Norman descent, this in no cases goes as far
back as the eleventh century. Innumerable examples of these faked
pedigrees and spurious traditions can be found in the works of Dr. Horace
Round and Mr. Oswald Barron. Those who believe that a craving for
historical accuracy is the ruling passion of the human race would no doubt
suppose that all these families were very grateful to Dr. Round and

150 SECTIONAL ADDRESSES

Mr. Barron for correcting their pedigrees, but they would be very muc
mistaken. I will give one example.

One of our oldest families is that of Wake, of which the present head is
Sir Hereward Wake, thirteenth Baronet. ‘The family ‘ tradition ’ is that itis
descended in the direct male line from the famous Saxon hero, Hereward
the Wake. The facts appear to be these. In 1166 a Norman called
Hugh Wac came over from Normandy and married the heiress of the
Norman FitzGilbert, lord of Bourne, in Lincolnshire. About two
hundred years later the family of Wake, as it had then become, having
attained to wealth and importance, thought itself entitled to a more high-
sounding pedigree, and having discovered that a Saxon called Hereward
had once owned a small part of the lordship of Bourne, decided to adopt
the great Saxon hero as ancestor. For this purpose a pedigree was
forged, conferring titles, ancestors and descendants upon the Hereward
who lived at Bourne, and to make this pedigree more convincing there was
conferred upon the Saxon hero the hitherto unheard-of cognomen of ‘the
‘Wake.’ ‘There are some obscurities in the story, but the following facts
seem certain: that Hereward was never called ‘the Wake’ till he was
adopted as ancestor by the Wake family about the middle of the fourteenth
century ; that the Wake family has no traceable connection with Hereward
or any other Saxon ; and that the first Wake to be christened Hereward
was born in 1851. As regards Hereward the Saxon hero, he may have
been a real person, but the fact that among his exploits are narrated the
slaughter of a gigantic bear in Scotland, and the rescue of a Cornish
princess, suggests that he was a mythical hero after whom Hereward of
Bourne and other Saxons were named.’

This story has many points of interest which can be followed up by
those who care todo so. I shall leave it there, but before passing from the
subject of ‘ family tradition ’ shall ask those who believe in it one question :
Can any one of them produce a single fact about his great-grandfather
which has not been placed on record? My great-grandfather, the first
Lord Raglan, was a man of some distinction, and yet, though I often visited
his daughters, who lived well on into the present century, I know practically
nothing about him that is not in print.

‘LocaL TRADITION.’

Sir G. L. Gomme, in his Folklore as an Historical Science, attempts to
establish the historical value of local tradition, but is constrained to admit
that it may often be mere false history, started by the local antiquary. In
my view, with certain exceptions which I shall come to later, it is always
false history. Let us take an example. ‘There is a well-known folk-story
of the Faithful Hound, variants of which are found in many parts of
Europe, Asia and Africa. It is probably derived from a rite, similar to
that described in Genesis xxii, by which a pretence is made of sacrificing
a child, and an animal substituted at the last moment. The popularity
of this story in Wales, and the fact that in an English version the dog

? D.N.B., s.v. ‘Hereward’; J. H. Round, Feudal England, p. 161; The
Ancestor, vol. ii, pp. 109-113.
8 S. Baring-Gould, Curious Myths of the Middle Ages, pp. 134 seq.

H.—ANTHROPOLOGY 151

is called Kill-hart, apparently led, in the late eighteenth century, to the
localisation of the story at Beddgelert, a village near Snowdon, the name
of which is thought to mean the grave of Kelert, an early saint. The fact
that Llewellyn is a popular North Welsh hero, and the enterprise of a
local innkeeper, who about 1830 set up a tombstone at a suitable spot,
were sufficient to establish a ‘ tradition ’ which was accepted by thousands,
not merely of the ignorant but of the learned.?

Where local traditions are not the result of such guesswork, they
usually arise from ignorance and superstition. Krappe!? tells us that
‘the dolmens of France and the British Isles are the work of fairies ;
‘the remains of the Roman limes are attributed by German peasants to
‘the Devil, who divided the earth with Our Lord, and erected the wall
“to mark the boundary. The ruins of the Roman amphitheatres of
“Southern France are called the “ palais de Gallienne,’’ Galienne being
“a powerful Moorish princess and the wife of Charlemagne. To the
* fellahin of modern Egypt the pyramids are the work of the jinn.’ Those
who believe that Caesar’s Camp was constructed by Cesar are morally
bound to believe that the Devil’s Dyke was constructed by the Devil.
Czsar’s Camp in Sussex, excavated by General Pitt-Rivers, proved to be
of Norman origin.

But while we find on the one hand that local tradition, whenever it can
be checked, proves to be untrue, we find on the other that real events
never find their way into local tradition. Near where I live are the
remains of a score of castles, many of them the scene of historic sieges
and other events. Yet not only are chere no authentic traditions about
these events—there are no traditions at all.

I will conclude my remarks on this part of the subject by noting that
there is one possibility of a genuine local tradition—where the repetition
of a ritual drama at a given spot gives rise to the belief that the events
enacted in the drama. really occurred at that spot. There are various
parts of the world, particularly Ancient Greece, in which this type of
tradition has probably come into existence.

TRADITION AND ENGLISH History.

Those writers who have tried to establish the historicity of tradition
have invariably, so far as I can learn, adopted the method of taking some
period the history of which is totally unknown, examining the traditions
which they assume to belong to that period, striking out all miraculous
or otherwise improbable incidents, and then dilating upon the verisimili-
tude of the residue. I shall follow a totally different method. I shall
take a period the history of which is known, the feudal age in England, and
see what tradition has had to say about that. According to the usually
accepted theories, outstanding personalities in the history of a country
never fail to leave their mark on tradition. Now who were the outstand-
ing personalities of the period in question? No one, I suppose, will
object to the inclusion of William the Conqueror and Edward I. The
Norman Conquest in the one case, and the conquest of Simon de Montfort,

* J. Jacobs, Celtic Fairy Tales, pp. 261-264. 10 Op. cit., p. 75.

152 SECTIONAL ADDRESSES

Wales and Scotland in the other, cannot have failed to create a tremendous
impression at the time, and this impression, according to the theory
which has been repeatedly applied to the Iliad, for example, should have
perpetuated itself in tradition. Yet what traditions do we find? Of
William the Conqueror, that he fell on landing, and that he destroyed a
number of towns and villages to make the New Forest. Of Edward I, that
his life was saved by his queen, and that he created his newly born son
Prince of Wales. All these traditions are completely devoid of historical
foundation. Of the real achievements of these two great monarchs
tradition had nothing to say whatever.

Similarly the only traditions of Henry II and Richard I are the fabulous
tales of Queen Eleanor and Fair Rosamund, and of Blondel outside the
castle.

With the traditional accounts of Henry V, those that have been made
famous by Shakespeare, I shall deal at greater length. ‘They tell us that
he spent his youth in drinking and debauchery, in and about London, in
company with highwaymen, pickpockets, and other disreputable persons ;
that he was imprisoned by Chief Justice Gascoigne, whom after his
accession he pardoned and continued in office ; and that on his accession
his character, or at any rate his conduct, changed suddenly and completely.
The authorities for these stories are Sir Thomas Elyot’s The Governor
(1531) and Edward Hall’s Union of the Noble and Illustrious Houses of
Lancaster and York (1542). ‘These two highly respectable authors seem
to have relied largely on matter already in print, some of it dating from
within fifty years of Henry V’s death. I know no argument for the
historicity of any traditional narrative which cannot be applied to these
stories—yet there is not a word of truth in any of them.

The facts are these. In 1400, at the age of thirteen, Henry became his
father’s representative in Wales, made his headquarters at Chester, and
spent the next seven years in almost continuous warfare with Owen
Glendower and his allies. In 1407 he led a successful invasion of Scotland.
In 1408 he was employed as Warden of the Cinque Ports, and at Calais.
In the following year, owing to his father’s illness, he became regent, and
continued as such until 1412. During this period his character as a ruler
was marred only by his religious bigotry, and what seems to be the only
authentic anecdote of the time describes the part he played at the burning
of John Badby the Lollard. In 1412 an attempt was made to induce
Henry IV, whose ill-health continued to unfit him for his duties, to
abdicate, but his refusal to do so, together with differences on foreign
policy, led to the withdrawal of the future Henry V from court, probably
to Wales, till his father’s death a year later. He did not reappoint Sir
William Gascoigne as Chief Justice, and there is no truth in the story that
the latter committed him to prison.

These facts are drawn from the Dictionary of National Biography, which
sums up the question by saying that ‘ his youth was spent on the battle-
‘ field and in the council chamber, and the popular tradition (immortalised
‘ by Shakespeare) of his riotous and dissolute conduct is not supported by
‘contemporary authority.’ According to Sir Charles Oman, “his life was
‘ sober and orderly. . . . He was grave and earnest in speech, courteous

H.—ANTHROPOLOGY 153

‘ in all his dealings, and an enemy of flatterers and favourites. His sincere
‘ piety bordered on asceticism.’

Even had there been no contemporary records of the youth of Henry V,
there are points in the account adopted by Shakespeare which might lead
the sober critic to doubt its veracity. The first is that it would be, to say
the least, surprising that a man should be an idle and dissolute scapegrace
one day, and the first soldier and statesman of his age the next. The
second is that the stories belong to an ancient and widespread class of
folk-tales. Had, however, our critic ventured to express his doubts, with
what scorn would he not have been assailed by believers in the historicity
of tradition! ‘ Here,’ they would have said, ‘ is an impudent fellow who
‘ pretends to know more about the fifteenth century than those who lived
‘in it. The facts which he dares to dispute were placed on record by
‘educated and respectable persons, the first historians of their day.
* Could anything be more absurd than to suppose that they would invent
‘ discreditable stories about a national hero, at a time when all the facts
‘ of his career must have been widely known? No reasonable person can
* doubt that Falstaff was as real as Piers Gaveston.’ As we have seen,
however, the only evidence for Falstaff’s existence is tradition, and tradi-
tion can never be evidence for an historical fact. He is a purely mythical
character, who plays Silenus to Henry’s Dionysus, as does Abu Nawas
to the Dionysus of Hariin ar-Reshid.

The assimilation of the king to Dionysus no doubt goes back to a time
when an aspirant to the throne had to perform various rites and undergo
various ordeals, but whether these stories had previously been told of
other English princes, and became permanently attached to Henry V
through the invention of printing, or whether they were recently introduced
from classical sources, I have no idea.

It may be objected that Henry V, an historical character, appears in
tradition, and that tradition is therefore to that extent historical ; but this
isnotso. ‘The characters in a traditional narrative are often anonymous.
When named they may be supernatural beings, or persons for whose

existence there is no real evidence. When the names of real persons are
mentioned, these names form no part of the tradition, but merely part of
the machinery by which the tradition is transmitted. Just as the same
smart saying may be attributed to half a dozen wits in succession, so the
same feat may be attributed to half a dozen heroes in succession, but it is
the anecdote or feat which, if it is transmitted from age to age, becomes a
tradition, and not the ephemeral name. The name selected is that of
some prominent person whose memory is fading ; who has been dead,
that is to say, for about a hundred years, or less if the real facts have never
been widely known. His name remains attached to the tradition till some
other suitable person has been dead for a suitable length of time.

This explains certain facts which have puzzled Prof. Gilbert Murray,
who asks : ‘ Why do they [sc. the Homeric poets] refer not to any war-
“fare that was going on at the time of their composition, but to war-
“fare of forgotten peoples under forgotten conditions in the past? .. .
“What shall one say of this? Merely that there is no cause for surprise.
“It seems to be the normal instinct of a poet, at least of an epic poet. The

154 SECTIONAL ADDRESSES

‘ earliest version of the Song of Roland which we possess was written by an
‘ Anglo-Norman scribe some thirty years after the Conquest of England.
“If the Normans of that age wanted an epic sung to them, surely a good
‘ subject lay ready to hand. Yet as a matter of fact their great epic is all
‘about Roland, dead three hundred years before, not about William the
‘Conqueror. The fugitive Britons of Wales made no epic to tell of their
‘ conquest by the Saxons ; they turned to a dim-shining Arthur belonging
“to the vaguest past. Neither did the Saxons who were conquering them
‘make epics about that conquest. They sang how at some unknown
‘time a legendary and mythical Beowulf had conquered a legendary
* Grendel.’ #4

The true explanation has nothing to do with instinct ; it is that epic
poetry, like other forms of traditional narrative, deals with ritual drama,
and not with historical fact. Real people and events can only be identified
with ritual drama when their memory has become vague. Roland could
not have been made to fall at Hastings before about 1166, and by that
time the form of the epic was fixed in writing. What we learn from the
Song of Roland are old traditional tales which were probably attached to
Charlemagne about a hundred years after his death. ‘The real facts of
his career, like all historical facts, have been, and could only be, ascertained
from contemporary written records.

In this connection Dr. Leaf remarks: ‘ When they [the Normans]
“ crossed the Channel to invade England, they seem to have lost all sense of
‘their Teutonic kinship with the Saxons, and it is doubtful if they even
‘knew that their name meant Northmen. The war-song which Taillefer
* chanted as they marched to battle was not a Viking saga, but the song of
‘Roland.’ 1* He realised that a people can completely forget its origin
within a hundred and sixty years—yet still believed in the continuity of
historical tradition !

Tue RiTuaL DRAMA.

If, as I hold, the traditional narrative is always an account of a ritual
drama, then the present incidence of traditional narratives must coincide
with the present or past incidence of ritual dramas ; that is to say that in
areas where traditional narratives are numerous and elaborate, ritual
dramas must be, or have been, numerous and elaborate, and where they
are few, simple, or non-existent, ritual dramas must be, or have been, few,
simple, or non-existent. And, conversely, where we find ritual dramas,
there we must expect to find corresponding traditional narratives.

A preliminary survey of the world suggests that our expectations would
be fulfilled. ‘Thus among the Yuma Indians of the Colorado the principal
ritual drama is the creation rite, and the principal traditional narrative is
a description of that rite in quasi-historical language. We find a similar
drama and a similar narrative among the Marindineeze of Dutch New
Guinea. Among the Shiluk of the Upper Nile the principal ritual drama
is the installation of the king, and the principal traditional narrative is an

11 Gilbert Murray, The Rise of the Greek Epic, pp. 52-55.
12 W. Leaf, Homer and History, p. 46.

H.—ANTHROPOLOGY 155

account of this installation, describing how the image of the mythical
Nyakang is brought to Fashoda as if a real god-king came to Fashoda.

Where these facts are realised, they are usually attributed to com-
memoration. I have elsewhere pointed out the absurdity of the com-
memoration theory. Why should people put themselves to all this
trouble without hope of benefit, and why should they expect to benefit by
commemorating the death of some ancient king ?

No one will deny that the ritual drama in Ancient Greece was of the
highest religious importance. The plays and fragments of plays which
have come down to us represent only a very small fraction of those that
were written, and probably there were thousands more which were never
written. These plays made up a large part of the religious life of the
Ancient Greeks, and there are survivals of them among the Greek peasantry
to this day. Now one of the leading incidents represented at the ritual
drama at Athens was the death of Agamemnon. Is there any conceivable
reason why the murder of a king of Mycenz should have been a leading
incident in the ritual drama at Athens? ‘There can be little doubt that
it was the dramatised version of a ritual of human sacrifice, a ritual once
practised all over Greece, by which the old king was ceremonially killed
by his successor. ‘The myth was localised, but the ritual was universal.
But while king-killing myths were localised all over Greece, we find no
battle and siege myths except those localised at Troy and Thebes. I
venture to conjecture that Troy was once the only place where the
war ritual was performed ; that all the Greeks used to assemble there
periodically for a great religious festival , and that later a similar festival
was established at Thebes for those of the peninsular Greeks who had
no ships.

But let us turn to Western Europe. In his Chances of Death Prof. Karl
Pearson showed what an important part was taken by the miracle or
mystery plays in the religious life of medizval Europe. In some cases
these plays covered all time from creation till doomsday, and took as long
as eight days to perform. ‘They took place in the churches, and while
heaven was represented by a gallery in which sat those who took the
parts of the Trinity and the angels, Satan and his host appeared from
below the main stage. Prof. Pearson concluded that these dramas replaced
heathen dramas of similar character. He says: ‘ That the old heathen
“religion was an essentially dramatic one can scarcely be doubted; we
“have proof enough not only in written statements, but in a vast number
* of folk-customs of dramatic origin. We find many cases in which heathen
“customs were introduced into Christian churches . . . both monks and
“nuns indulged in dances and masquerades directly connected with
“heathen festivals.’ 14

The facts which were noted by Prof. Pearson find confirmation and
amplification in The Culture of the Teutons, by a Danish writer, Vilhelm
Gronbech, who deals at length with the importance of the ritual drama in
the heathen religion, shows how the incidents of the dramas can be recon-
structed from the traditional narratives, and points out the absurdity of
trying to translate these narratives into terms of history.

18 Jocasta’s Crime, p. 44. 14 Op. cit., vol. ii, pp. 281-282.

156 SECTIONAL ADDRESSES

‘ The legends will not tell us what happened some year or other accord-
ing to chronology ; in our craving for a kernel of historical truth in the
myths, we naively insinuate that the myth makers ought to think in a
system unknown to them, for the benefit of our annalistic studies. . . .
‘Time is, in our experience, a stream of events descending from the
‘ unknown mists of beginning and running in a continuous flow down the
‘ future into the unknown ; to the men of the classical ages the actual life
‘is the result of a recurrent beginning and has its source in the religious
‘feast. The festival consists of a creation or new birth outside time,
‘ eternal it might be called if the word were not as misleading as all others
‘ and as inadequate to describe an experience of a totally alien character.
‘ When the priest or chieftain ploughs the ritual furrow, when the first
‘seed is sown while the story of the origin of corn is recited, when the
‘ warriors act the war game, they make history, do the real work, fight
‘ the real battle, and when the men sally forth with the plough or the seed
‘ or the weapons, they are only realising what was created in the ritual act.’ 1°

According to Gronbech, then, the myths and legends of the North have
their origin in the world of ritual drama, a world in which the terms of
history are quite meaningless. Other writers are moving in the same
direction. Mr. C, B. Lewis, in his Classical Mythology and Arthurian
Romance, seeks to show the ritual origin of the Arthurian legends, while
M. P. Saintyves, in his Les Contes de Perrault et les Récits Paralléles,
performs the same service for such tales as Cinderella and Bluebeard.
Prof. S. H. Hooke and his colleagues have recently traced the connection
between Myth and Ritual in Semitic lands.

It will be seen, then, what a variety of fortunes has befallen the ancient
ritual dramas. Some have been converted to Christianity ; some have
been rationalised into pseudo-history ; others have degenerated into fairy
tales. There are, however, some which survive, or survived till recently,
in something like their original form. Let us take, for example, the cycle
of Robin Hood, which forms the most important body of English and
Scottish traditional narrative. Attempts have of course been made to
turn him into an historical character, but he remains the god of the tree,
a figure of world-wide importance. Hd6d’s Oak is the name given in an
Anglo-Saxon charter to a place in Worcestershire, and he owns hills,
rocks, caves and wells in Yorkshire, Lancashire, Nottinghamshire,
Derbyshire, Shropshire and Somerset. His story has been localised in
Nottinghamshire, Yorkshire and Cumberland, as well as in Scotland, and
he has been supposed to have lived in the twelfth, thirteenth and fourteenth
centuries, and sometimes to have been earl and sometimes churl. But
wherever and whenever he lives, he always has his Maid Marian, his
Little John and his Will Scarlet, since it is the incidents of the ritual drama,
and not its setting, which matter. ‘That he was the hero of such a drama
there can be no doubt. We are told 1° that in the fifteenth century the
May celebration was called ‘ Robin Hood’s festival,’ and that he was ‘ one
* of the mythical characters whom the populace was fond of personating in
‘the semi-dramatic devices and morris-dances performed at that season.’
In Scotland he was as popular as in England, and in 1577 the Scottish Par-

15 Op. cit., vol. ii, pp. 226, 261. 16 D.N.B., s.v. Hood, Robin.

‘
‘
¢

H.—ANTHROPOLOGY 157

’

liament requested the King to prohibit plays of ‘ Robin Hood, King of May
onthe Sabbath. In France Robin des Bois and Marian are found in the
thirteenth century as characters in the Whitsuntide pastourelles—a fact
which rather suggests that the whole story came to England with the
Normans, more especially as in other northern lands this drama took the
somewhat different form which is familiar to us as the story of William
Tell. The latter was long believed to be an historical character, but the
story is now recognised as a widespread myth.

Before leaving this part of the subject I should like to touch on two
forms of the traditional narrative which are much relied upon by those
who believe in the historicity of tradition—the Icelandic saga and the
quasi-historical traditions of Polynesia. The most famous of the Ice-
landic sagas is probably that of Burnt Njal, and the central incident in it
is the burning of Njal and his sons in their house. When, however, we
come to examine this story, we find that it is merely a variant of the Irish
story of Naisi. Let us take one incident. When Skarphedinn and his
brothers are shut up in the burning house, Gunnar, a man whose relatives
Skarphedinn has slain, climbs up and looks over the wall ; Skarphedinn
throws a tooth at him, hitting him in the eye, and causing his eyeball to
fall out on to his cheek. Naisi and his brothers are shut up in a house,
and before Conchobar orders his men to set fire to it he sends Trendorn,
a man whose relatives Naisi has slain, ‘ to see whether her own shape
‘remained on Deidre.’ He peeps through a small upper window ; Naisi
throws a draughtsman at him and hits him in the eye, so that his eyeball
falls out on to his cheek. I have no douht that Naisi and Skarphedinn are
names for a northern variant of Heracles, whose adventures and death
formed part of the ritual drama.

For Polynesian traditions I shall rely on Mr. Percy Smith, and he,
though he firmly believes in the historicity of these traditions, nevertheless
gives us a number of hints that they are really accounts of ritual drama.
Thus he tells us that ‘ much of the old history of the Polynesians was
* regarded as sacred, and its communication to those who would make an
‘improper use of it would inevitably—in the belief of the old priests—
“bring down disaster on the heads of the reciters. . . . This teaching
“sc. of the tribal lore] was accompanied by many ceremonies, incanta-
“tions, invocations, etc. . . . There was a special sanctity attached to
“many things taught; deviation from the accepted doctrine, or history, was
“supposed to bring down on the offender the wrath of the gods.’17_ He
later tells us that ‘ there was a class of roving actors and players, who were
also the custodians of much of the historic traditions,’ and that ‘ the
“history of Onokura is a very remarkable one . . . the narrative is inter-
“spersed with songs and recitative, which would take many hours in
‘delivery. It is, in fact, a regular “‘ South Sea opera.” ’ 18

If these traditional narratives were really history, and if the teaching
of history followed the same course in this country as it is alleged to in
Polynesia, we should find professors imploring their pupils not to make an
improper use of the Constitutions of Clarendon ; boys learning the names
of Henry VIII’s wives with incantations and invocations ; people con-

1S. Percy Smith, Hawatki, pp. 14-15. 18 [bid., pp. 138, 222.

158 SECTIONAL ADDRESSES

victed of blasphemy for mixing up Thomas Cromwell with Oliver; and
the history of the Corn Laws related with vocal and instrumental accom-
paniment. These traditions are sacred, not because they contain historical
facts, which never are and never could be sacred, but because they are
ritual, which is always sacred.

FEATURES OF THE TRADITIONAL NARRATIVE.

I propose to conclude by referring to a number of features which are
found in traditional narratives of all descriptions, and which can be
explained, and in my view only explained, on the supposition that these
narratives are all accounts of ritual drama.

(1) The narrative is invariably dramatic. This is, of course, charac-
teristic of the drama, but not of history, which is seldom dramatic.

(2) Though the characters are often represented as coming from
different countries, they all speak the same language. In tradition, as on
the stage, interpreters are unknown.

(3) The action of the narrative is often carried on by means of songs
and rhymes ; this never happens in real life.

(4) The traditional narrative, unlike history, always contains a great
deal of conversation. If all the authentically recorded utterances of every
English king from the eleventh to the fifteenth centuries were put together,
they would not amount to the utterances of the meanest stage hero.

(5) In tradition the costume of the characters is often described in
detail. It is, of course, important that the leading characters in the ritual
drama should be correctly dressed, but we are very seldom told what
historical characters wore.

(6) Traditional narratives often have a conventional setting, such as the
gateway of a city, the doorway of a palace, or outside a hut in the forest.
In real life people seldom give out their secrets at such places, but in
tradition they make a practice of it. .

(7) In the traditional narrative the hero often spends what he supposes
to be a day in a cave or on an island, and finds on his return home that he
has been away a whole year. This does not occur in real life, but on the
stage a year often elapses between Act I and Act IT.

(8) The characters in the traditional narrative always remain the same age.
We see this clearly in Homer. Helen’s amorous adventures last for about
thirty years, but at the end she is still a young and beautiful girl. Nestor,
at the beginning of the siege of Troy, is a hale but very old man; at the
end of the siege he is still a hale but very old man, and he returns home
and goes on being a hale but very old man. In the same way Njal, when
we first meet him, is a wise old man to whom people go for advice ; forty
years later he is still a wise old man to whom people go for advice. An
old Helen, and a young Nestor or Njal, are as unthinkable as an old
Columbine or a young Pantaloon.

(9) Not only do the characters remain at the same age, but they are
all contemporaries. Prof. Gilbert Murray has noticed this ; he says :
‘ There is an extraordinary wealth of tradition about what we may call
‘the Heroic Age. Agamemnon, king of Mycenz and Argos, Priam,
‘ king of Troy, and the kings surrounding them, Achilles, Aias, Odysseus,

H.—ANTHROPOLOGY 159

‘Hector, Paris, these are all familiar household words throughout later
“history. They are among the best-known names of the world. But
“how suddenly that full tradition lapses into silence! The Epic Saga
“can tell us about the deaths of Hector, of Paris, of Priam ; in its later
* forms it can give us all the details of the last destruction of Troy. Then
“no more ; except a few dim hints, for instance about the descendants of
* Eneas.

“It is more strange in the case of Mycenz and Sparta. Agamemnon
“ goes home in the full blaze of legend ; he is murdered by Egisthus and
* Clytemnestra, and avenged by his son Orestes ; so far we have witnesses
“by the score. But then? What happened to Mycenz after the death
‘ of AXgisthus ? No one seems to know. There seems to be no Mycenz
“any more. What happened to Sparta after Menelaus and Helen had
“taken their departure to the islands of the blest ? There is no record,
‘no memory.

“. . . It is the same wherever we turn our eyes in the vast field of Greek
‘legend. The “ heroes ” who fought at Thebes and Troy are known ;
“their sons are just known by name or perhaps a little more ; Diomedes,
* Aias, Odysseus, Calchas, Nestor, how fully the tradition describes their
“doings, and how silent it becomes after their deaths ! ’ 19

We find the same phenomenon in many parts of the world, and the
explanation is, in my view, a simple one. When the drama is over, the
curtain goes down.

(10) ‘The fact has been noted by Prof. Chadwick that ‘ the religion
‘of the Heroic Ages is predominantly the worship of gods, while in his-
“toric Greece and Scandinavia, etc., forms of chthonic worship are more
“prominent, and survive for centuries.’ 2° Supernatural beings, to be
brought on to the stage, must of course be represented in human or
animal form,

(11) Among the commonest of the miraculous events which figure so
largely in traditional narrative is shape-changing. In the Vélsunga
Saga Freya puts on the gear of a crow and flies off. Sigmund puts on
a wolf-skin and becomes a wolf. These feats are easy on the stage, but
difficult in real life. Hartland notes that ‘ the dress (which transforms
“the heroine into a swan, etc.) when cast aside seems simply an article of
“human clothing, often nothing but a girdle, veil or apron ; and it is only
“when donned by the enchanted lady, or elf, that itis found to be . . . a
“complete plumage.’ #4 The stage properties of the ritual drama must
often have been few and simple.

(12) There are few traditional narratives which do not include a king
and queen. Prof. Pearson explained this by supposing that Europe was
once divided into a vast number of tiny kingdoms, but the real reason
is that the king and queen are the centre of all ritual, and must therefore
be represented in all ritual drama.

(13) A point which has been noticed by various writers is that the
battle in tradition is always a series of single combats. Prof. Chadwick
explains this ®? by saying that the possession of armour constituted an
19 Op. cit., pp. 52-55. 20 Op. cit., p. 424.
21 Op. cit., p. 301. 22 Op. cit., P. 339.

160 SECTIONAL ADDRESSES

overwhelming advantage, and that the object of the battle was to kill the
leaders, who were expected to distinguish themselves by personal bravery.
The same considerations, however, apply equally to feudal times, yet we
never find feudal monarchs engaging in single combat. |

The theory put forward by Ridgeway to account for this and similar
facts was that people who cannot write keep accurate historical records
which they transmit orally, but that instead of expressing themselves in
straightforward language they personify their own and neighbouring
tribes, and then represent collective activities in terms of individual
acts. ‘The theory seems to be that at a certain stage in our culture we
should have described the English conquest of Ireland by saying that
Britannia jumped a ditch into her neighbour’s garden, and the Battle of
Trafalgar by saying that Britannia quarrelled with Gallia, and threw her
bucket down the well.

In criticising this theory, Mr. A. Nutt asked : ‘ Is there such a thing as
‘ historic myth at all? Do men commemorate tribal wanderings, settle-
‘ ments, conquests, subjugations, acquisitions of new forms of culture,
‘ or any of the other incidents in the collective life of a people, in the form
‘ of stories about individual men and women? I do not for one moment
‘ deny the possibility of their doing so ; all I ask for is evidence of the fact.’
I cannot find that anyone has ever produced any evidence, yet the theory
is still widely held, and was much later put forward by Prof. Murray,
who tells us that he strongly suspects the lists of men slain by the heroes
of the Jiad to be tribal records, condensed, and, ‘ of course,’ transferred
from their original context. He has already given us an example of one
of these ‘ tribal records.’ In the Jad it is said that Phzstus was slain
by Idomeneus, and fell from his chariot with a crash. On this Prof.
Murray comments: ‘ Idomeneus is the king of Knossos in Crete, and
‘ Phestus is only known to history as the next most famous town in the
‘same island. ‘That is to say, Phestus zs the town, or the eponymous
‘hero of the town. So we have in this passage a record of a local battle
‘ or conquest in Crete, torn up from its surroundings and used by the poet
‘ to fill in some details of slaughter in a great battle before Troy.’

Even if we admitted the possibility of historic myth, it would be diffi-
cult to explain why a town should be represented as falling from a chariot.;
why an eponymous hero should be invented for one town but not for
the other ; and why the poet of the J/iad should have recourse to Cretan
records in order to fill in details of a battle before Troy, seeing that in
more important cases he makes use of ‘mythological changes and false
‘ identifications.’ 2> It is difficult to acquit Prof. Murray of treating
those portions of the dad which fit in with his theories as ‘ real history,’
and those which do not as ‘ the emptiest kind of fiction.’ *® Sir William
Ridgeway and Dr. Leaf rendered themselves liable to a similar charge.
The reason for the single combats in tradition is that the original ritual
combat was between the king and his challenger. It was this tradition
which induced Shakespeare, with his habitual disregard of historical
fact, to make Henry IV fight a single combat with Douglas.

23 Folklore, vol. Xii, p. 339. 24 Op. cit., pp. 232-234.
25 [bide 22955 (a 26 (P3253.

——_—---~ ~~~

H.—ANTHROPOLOGY 161

(14) Another feature of the traditional narrative is that prophecies
always come true ; that advice, except in certain special circumstances,
is always taken ; that people frequently embark on enterprises which they
well know will prove disastrous ; and that, as Prof. Chadwick notes, the
characters are always boasting of what they have done and what they
are going to do. ‘The reason is that all present at the ritual drama are
participants in the drama, and in order that they may add their share of
luck to the drama and draw their share of luck from it, it is essential that
they should fully realise what is going on. And this brings me to my
last point.

(15) In many forms of the traditional narrative there is a character who
takes the parts of prompter and stage manager. It is his business to tell
the actors what to do, and when necessary to tell the audience what is
being done. The heathen ritual drama consisted largely of acts which
were regarded by the Church as sinful, and in the gradual process of con-
verting these dramas to Christianity we find the prompter coming to be
identified with the Devil. It is clear in Faust, for example, that Mephis-
topheles is nothing more than the prompter ; without him there would
be no drama at all. Similarly, in that wonderful play The Miracle, in
which we are shown many of the features of the ritual drama, the Spielmann
plays the part of prompter and stage manager.

In the Vélsunga Saga the part is taken by Odin, who speaks the pro-
logue and epilogue, and intervenes at critical moments.to direct the action.
Odin, we are told, was represented as an old man with one eye and a
broad-brimmed hat ; where could he have been so represented except
onthe stage? In the Arthurian legends it is Merlin who is the prompter.
He is always telling the actors what to do and the audience what is going
to happen.

In the Homeric dramas there does not seem to have been an individual
prompter. ‘The gods apparently sat, like the Trinity of the miracle plays,
on a raised platform. ‘They announced what was going to be done, and
descended, when necessary, to direct the actors.

CONCLUSION.

Ridgeway assures us that unless we are prepared to maintain that both
Herodotus and Thucydides are utterly untrustworthy, we must ‘accept
what they tell us of Greek prehistory ; but we are in reality faced with no
such alternative. We may well believe that these writers, like Ridgeway
himself, were genuine seekers after truth, but that, also like him, their
methods were totally unscientific. He, and nearly all the other writers
whom I have quoted, not merely start by assuming what they wish to
prove—namely, that the I/iad is historical—but they rely almost entirely on
internal evidence. It would be possible to prove by this method the
historical truth of any novel. When Homer says that Ithaka is an island,
they give him full marks for geography. When he says that it is rich in
wheat, he does not lose any marks : they merely conclude—at least Dr. Leaf
did—that in Homer’s time some other island was called Ithaka. This kind
of thing is not science at all : it is merely a parlour game. Unfortunately,
however, anthropologists have been taught to take it seriously, and are now

G

162 SECTIONAL ADDRESSES

engaged, all over the world, in the hopeless attempt to extract history
and geography from the traditional narratives, instead of putting these to
their proper use, which is to act as a guide to the rites of the people con-
cerned, and so to their beliefs and ideas.

The only sure foundation for the edifice of science is the concrete of
ascertained fact, reinforced by the steel rods of universally tested theory.
The ground upon which the edifice of social anthropology had to be built
was encumbered not merely by the ruins of ancient superstitions, but also
by the jerry-buildings of pseudo-history and pseudo-psychology, and
many anthropologists have believed that these survivals could be in-
corporated in the new edifice. The result has been that social anthro-
pology has been allotted, very properly, a low place among the sciences.
It will never occupy what should be its proper place until a vast quantity
of pre-scientific and pseudo-scientific rubbish has been cleared from
its path, and if this address helps in the smallest degree to bring about
this clearance, it will have more than achieved its object.

SECTION 1—PHYSIOLOGY.

THE ACTIVITY OF NERVE CELLS

ADDRESS BY
PROF. E. D. ADRIAN, F.RS.,
PRESIDENT OF THE SECTION.

SINcE the biologist seeks to understand life, he cannot be accused of
lack of courage. But he can find out a great deal without approaching
too near the central problem. He can find out how the living cell develops
and how it behaves; he can follow many of the physical and chemical
changes which take place in it, and could follow more if cells were not so
inconveniently small. The immediate problems of the physiologist may
be still further removed from the problem of life. They may deal, for
instance, with the mechanics of the vascular system or with the physical
chemistry of blood pigments. But most of us aim at explaining the
working of the body in terms of its constituent cells, and feel that this
is a reasonable aim even though we must take the cell for granted. Is
it a reasonable aim when we are dealing with the working of the nervous
system? ‘That is the problem which I shall discuss this morning.
The nervous system is responsible for the behaviour of the organism
as a whole: in fact, it makes the organism. A frog is killed when its
brain and spinal cord are destroyed : its heart still beats and its muscles
can still be made to contract, all the cells of its body but those of the
brain and cord are as fully alive as they were before; but the frog is
dead and has become a bundle of living tissues with nothing to weld
them into a living animal. This integrative action of the nervous system,
to use Sherrington’s classical phrase, we may be able to explain in terms

of the reactions of the constituent nerve cells. We can at least discuss

the point as physiologists. But the human organism includes a mind
as well as a body. It may be best to follow Pawlow and to see how
far we can go without bringing in the mind, but if the reactions of our
nerve cells are to explain thought as well as action we must face the
prospect of becoming psychologists and metaphysicians as well.
Fortunately we need not yet go to such extremes. There are problems
enough on the physiological plane, and they are made all the more
interesting by this hint of mystery in the background.

_ The nervous system, the brain, spinal cord and peripheral nerves, is
made up of a large number of living cells which grow, maintain them-
selves by the metabolism of food-stuffs, and carry out all the complex
reactions of living protoplasm. In this there are enough problems for
anyone ; but we are concerned not with the general properties of living
cells but with those special properties which enable the cells of the

164 SECTIONAL ADDRESSES

nervous system to perform their functions. ‘Their function is to make
the organism respond rapidly and effectively to changes in its environ-
ment, and to achieve this they have developed a specialised structure,
and a complex arrangement in the body. ‘They send out long threads
of protoplasm which serve for the rapid transmission of signals, and
they are linked to one another by elaborate branching connections in the
brain and the spinal cord.

THE DEVELOPMENT OF THE NERVOUS SYSTEM.

The mapping of this network of paths was begun many years ago,
and was the first step in the analysis. No progress could have been
made without it, and its results are of vital importance to neurology.
We are now witnessing a fresh period of interest in the geography of
the central nervous system, but the problem is not how the nerve cells
and their fibres are arranged, but why they are arranged as they are.
R. G. Harrison in his recent Croonian Lecture recalled the time when
he first cultivated living nerve cells outside the body. ‘That experiment
made twenty-three years ago, marks the new epoch better than any
other, for, besides introducing the method of tissue culture, it settled a
long and bitter controversy as to the origin of nerve fibres. Nowadays
the most elaborate transplantation experiments are carried out by the
embryologists on amphibian larve. Animals are produced with super-
numerary limbs, eyes, noses, and even spinal cords. The growing nervous
system is faced with these unusual bodily arrangements, and by studying
the changes induced in it we can form some idea of the factors which
determine its normal structure. A review published this summer by
Detweiler gives a vivid impression of the plasticity of the developing
nervous system in the hands of the experimenter. As a rule it accepts
the extra limb or sense organ, links it by nerve fibres to the rest of the
organism and may develop more nerve cells to deal with it. ‘The forces
which mould the nervous system seem to come partly from within the
central mass of nerve cells and partly from the body outside. These
forces may be chemical or electrical gradients, and often the nerve fibres
seem to grow in particular directions because they cling mechanically
to structures already laid down, e.g. to the main arteries of the limbs.
It is unlikely that a simple formula will be found for such a complex
arrangement, but the fact remains that the arrangement can be pro-
foundly modified at the will of the experimenter. Its detail seems to
depend not so much on the innate properties of particular cells as on the
environment provided by the rest of the organism.

THE REACTIONS OF THE NEURONES.

This new embryological work supports the older in showing that the
nervous system is made up of ‘ neurones,’ cells with thread-like extensions,
and that they are the only active elements in it. ‘These elements are all
cast in the same mould, but are shaped differently by the forces of
development. To this we can now add the fact that all neurones seem
to do their work in much the same way. ‘The activity which they show
is in some respects remarkably simple. It is essentially rhythmic: a

I—PHYSIOLOGY 165

series of rapid alternations between the resting and the active state,
due probably to rapid breakdown and repair of the surface. ‘This at
least is a fair description of the way in which the nerve fibres carry out
their function of conducting messages, and we can detect the same
kind of pulsating activity in the nerve cells of the brain.

The evidence comes from the analysis of minute electric changes, for
cell activity sets up electrical eddies in the surrounding fluid, and these
can be measured with a minimum of interference. ‘The clearest results
are given by the peripheral nerve fibres which connect the central nervous
system to the sense organs and the muscles. The nerve fibres are
conveniently arranged in bundles to form the nerve trunks: each fibre
is an independent conducting path and there may be a thousand such
paths in a fair-sized nerve, but it is not a difficult matter to study what
takes place in the single fibre when it conducts a message. We may
begin with an external stimulus acting on a sense organ, a structure
which includes the sensitive ending of a nerve fibre as an essential part.
The ending is excited by the stimulus, the delicate equilibrium of its
surface is upset and the disturbance tends to spread along the fibre.
The spreading is an active process: it takes place because the fibre has
a store of energy ready to be liberated at a moment’s notice, and because
the changes which attend its liberation at one point upset the balance at
the next point and cause the same activity there. ‘The spread of a flame
along a fuse is a well-worn analogy. But the nerve fibre is so constituted
that a disturbance at any point is almost immediately cut short. The
change spreads along it as a momentary wave—a brief impulse followed
inevitably by a brief interval of rest and recovery. If the sense organ
remains excited a second impulse passes up the fibre, and then another
and another as long as the stimulus is effective. ‘The impulses in a given
nerve fibre are all alike in magnitude, rate of travel, etc., but the frequency at
which they recur depends on the intensity of the stimulus, rising sometimes
as high as 300 a second in each fibre, or falling as low as 10. All the
' nervous messages take this form ; the central nervous system is continually
bombarded by trains of such impulses passing along the slender threads of
protoplasm from the sense organs, and is continually sending out trains
of impulses to the muscles.

The conducting threads or nerve fibres are exceedingly insensitive to
changes in their environment: their endings in the sense organs are
exceedingly sensitive. ‘The sole function of the ending is to act as the
trigger mechanism for firing off the impulses, and the sole function of the
nerve fibre is to carry the message without distortion. Both are specialised
parts of the neurone with specialised reactions, but it is important to note
that these reactions are not peculiar to the nervous system. Muscle
fibres, developed from the mesoderm and specialised for contraction,
conduct impulses which seem to differ merely in their time relations
from those in nerve fibres, and they can also be made to behave like the
sensory endings by treatment with various salt solutions. In sodium
chloride, for instance, a series of impulses will be set up in a muscle
fibre when it is stretched, as they would be in one of the sense organs
whose sole duty is to act as ‘ stretch receptors.’ The muscle fibre makes

166 SECTIONAL ADDRESSES

a poor copy of the nervous mechanism, for it reacts jerkily and is often
damaged in the process, but the ground-plan of the mechanism is the
same.

Thus in the activities concerned in the rapid conduction and in the
setting up of rhythmic trains of impulses, it does not appear that the
cells of the nervous system have properties not shared in some degree
by other tissues.

So far we have only considered what happens in nerve fibres. We
can tap the messages which pass along the wires between the front line
and headquarters, but this does not tell us how they are elaborated there.
A great deal has been found out already by the analysis of reflexes—i.e. by
sending in a known combination of signals and finding what signals
come out to the muscles; indeed, the great part of Sherrington’s work on
the spinal reflexes and Pawlow’s on the brain has been carried out in
this way. An account of the central nervous system which does not
include a full discussion of such important work is like the tragedy of
Hamlet without the Prince of Denmark; but the results are so well known
that I shall deal instead with a recent line of attack of an entirely different
kind. This relies on the fact that nervous activity, in the central grey
matter as in the peripheral nerves, is accompanied by electric changes.
They seem to be a reliable index of the underlying activity, and by
recording them we come a step nearer to the main problem. The chief
difficulty is to interpret the records. In the cerebral cortex, for instance,
very large electric oscillations are constantly occurring, except in the
deepest anzsthesia, but they vary from moment to moment and from
place to place, and it is only in the visual cortex that they are under a
fair degree of experimental control. Here they can be produced by
shining a light in the eye (Fischer and Kornmiiller) or stimulating the
optic nerve (Bartley and Bishop), and the prospects of analysis are more
hopeful. But at the moment the most significant feature of these records
from the brain lies in the appearance of the waves. Whenever a group
of nerve cells is in action, in the cerebral cortex, the brain stem or the
retina, and whether the nerve cells in question belong to a vertebrate,
or an insect, the waves are alike in general form. Instead of the abrupt
spikes which appear in a record from a nerve fibre when a train of
impulses passes down it, we have more gradual potential changes which
form a series of waves of smooth contour. In the simpler structures
where most of the neurones are acting in unison the waves may have a
regular rhythm (5 to go or more a second), which rises and falls when
the stimulus changes in intensity. It is often possible to make out
both the abrupt nerve fibre impulses and the slower nerve cell waves,
and to show that they occur together. In the cerebral cortex of an
anzesthetised animal there is much more variety and less orderly repeti-
tion ; the waves usually occur at irregular intervals ; they vary in size and
duration, and some of them may last for half a second or even longer.

Nerve cell waves may be the wrong name, for they are probably due
to the branching dendrites and not to the cell body of the neurone ; but
there can be no doubt that they represent a characteristic activity of the
structures which make up the grey matter. They show that the same

I.—PHYSIOLOGY 167

kind of rhythmic breakdown and repair of the surface takes place in this
part of the neurone as in the nerve fibre, with the important difference
that the changes develop and subside much less abruptly. The surface
is not specialised for rapid conduction ; the forces which restore the
resting equilibrium are less powerful and there is more tendency to
spontaneous breakdown and to long periods of uninterrupted activity.
We know that the activity of the grey matter is far more readily influenced
by chemical changes than is that of the nerve fibre with its elaborate
fatty sheath and wrappings of connective tissue, and it seems probable
that both chemical and electric changes may be concerned in the spread
of activity from one neurone to another. How this spread takes place
is still uncertain, and it is admittedly the most important problem we
have to face. In spite of this we can claim to have some of the main
outlines of neurone activity. Our nervous system is built up of cells
with a specialised structure and reactions, but the reactions are of a
type to be found in many other cells. The rhythmic beat of the heart
is probably due to surface reactions not far different from those in
the group of nerve cells which produces the rhythmic movements of
breathing ; and the factors, nervous and chemical, which regulate the
heart beat are probably much the same as the factors which control the
discharge of the neurone. We have a store of energy, replenished con-
stantly by cell metabolism and liberated periodically by surface breakdown.
The electrical gradients at the active point cause a spread of the breakdown
to other regions, but sooner or later restoring forces come into play, the
membranes are healed and the cycle is ready to be repeated. It is a long.
step from the mechanical precision of an impulse discharge in a nerve
fibre to the irregularities of a record from the cerebral cortex, but there
are many intermediate cases which will bridge the gap.

THe Nervous SYSTEM AS A WHOLE.

As far as the units are concerned the prospect is encouraging. The
difficulties begin when we come to the work of the nervous system as
a whole. Many of its reactions are mechanical enough and can be
explained in terms of the activity of groups of neurones, but there is
much that resists this kind of treatment. It is perhaps encouraging
that the difficulties are greatest when the reactions depend on the cerebral
cortex, when they involve learning and memory, or, if you prefer it, habit
formation and conditioning. They have been clearly stated by Lashley,
and most of them can be reduced in the end to a simple formula, the
failure of anatomical models of the nervous system. ‘The revolt from the
anatomical model has been growing for many years, though it may be
doubted whether its sponsors ever believed in it as much as their critics
_ suppose. It gave us diagrams of nerve centres and pathways which
were valuable enough when they referred to known anatomical structure,
but not when they referred, as they often did, to hypothetical centres
and to pathways canalised by use. ‘These too may exist, but they are
not the whole explanation of cortical activity.

Clinical neurology is partly to blame for the emphasis laid on exact
localisation. The neurologist must locate brain tumours by analysing

168 SECTIONAL ADDRESSES

the disturbances they produce ; consequently he welcomes the slightest
evidence of localisation of function in the cortex, and finds the anatomical
model valuable for correlating his observations. Undoubtedly there are
well-defined nervous pathways, clear differences in cell structure and
localised activity in different parts of the brain. As a modern addition
to the evidence we have Foerster’s recent work on the electrical stimulation
of the human cortex, and his finding that stimulation of the temporal
lobe may cause sounds and words to arise in consciousness whilst stimu-
lation of the occipital lobe gives lights or images. Bard has given another
remarkable example of strict cortical localisation by his observations on
certain postural reactions in the cat. These depend on a small area in
the frontal region, are not affected by damage to other parts of the brain,
and are permanently lost if the frontal area is destroyed. The danger
nowadays is that we may pay too little attention to such facts ; but it is
true, nevertheless, that the localisation is a matter of areas rather than
of single neurones. This is shown by examination of habit formation,
and by the remarkable way in which the nervous system adapts itself to
injury. 3

It has often been pointed out that we learn to recognise shapes—the
letters of the alphabet, for instance—however they are presented to us.
The pattern of black and white made on our retina by the letter A need
not fall on a particular set of retinal endings connected with particular
cortical neurones. We have learnt to recognise a relation of lines and
angles, a pattern of activity in the cortex rather than an activity of specific
points. ‘This kind of reaction is not due to our superior intelligence.
Lashley finds it in the rat, and psychologists of the Gestalt school have
pointed out examples from all manner of animals. There is the same
neglect of specific neurones in the formation of motor habits, for if we
have once learnt to write the letter A with our right hand, we can make
a fair attempt to write it with any group of muscles which can control a
pencil.

The adaptations to injury present a different aspect of the same story.
An insect which has lost a leg will at once change its style of walking to
make up for the loss. This may involve a complete alteration of the
normal method, limbs which were advanced alternately being now
advanced simultaneously ; the activities of the nervous system are
directed to a definite end, the forward movement of the animal—it uses
whatever means are at its disposal and is not limited to particular pathways.

When the central nervous system is injured there is more evidence of
localised function, but the localisation is no hard-and-fast affair. A rat
uses its occipital cortex in the formation of certain visual habits. When
this part of the cortex is destroyed the habit is lost, but it can be re-learnt
just as rapidly as before with what remains of the brain. A monkey’s
arm is paralysed if the corresponding motor area of the cortex is destroyed,
but the paralysis soon passes away although there is no regeneration
of the motor cortex. What is more remarkable is that the recovered
functions are not associated with the development of a new visual region
or motor region in the brain. Though they were originally localised
there is no longer any one part of the cortex which is essential.

I.—PHYSIOLOGY 169

In reactions where there is no evidence of localisation (e.g. the learning
of maze habits in the rat), Lashley finds that the important factor is the
total mass of the cortex and not the presence of particular regions. ‘The
effect of an injury depends on its extent and not on its situation. It
depends, too, on the amount of grey matter (nerve cells and dendrites)
destroyed, and not on the cutting of connections between the different
parts of the cortex. ‘Thus the ability of the brain to form new associations,
and generally to control the behaviour of the animal, depends primarily
on the total area covered by the nerve cells of the cortex and their inter-
lacing dendrites. For certain reactions it depends to some extent on
the arrangement of pathways, but this arrangement is not essential.
There is more localisation of function in the large brain of man than in
the very small brain of the rat, for different cortical regions may be
completely equivalent when they are separated by 5 mm., but not when
they are separated by 100. But apart from this difference in scale it is
likely that the human cortex has the same mass effect and plasticity of
function.

How do the individual neurones combine to produce a system which
can recognise a triangle or direct the movements of the organism with
such disregard of detailed structure? If particular neurones or path-
ways are not tuned to triangularity, how can the whole mass be tuned to
it, and why should the tuning be more certain when the mass is greater ?
Our data may be at fault and the mass effect an illusion, but there is
certainly enough evidence for it to be taken seriously. ‘Though there
is no solution at the moment, I cannot believe that one will not be
found—a solution which need not go outside the conceptions of physiology.
It should be possible, for instance, to find out how many neurones must
be combined to give a system which reacts in this way and what kind of
structure they must form. ‘The nervous systems of insects may provide
the clue, for these may contain a few thousand nerve cells in place of the
ten thousand million in the human brain. It is possible also to study
the reactions of isolated parts of the central nervous system, to see how
far their behaviour can be explained in terms of the units which compose
them. The retina is an interesting example of this kind, for it contains
an elaborate structure of nerve cells and dendrite connections, and has
some of the reactions which we might expect from a mosaic of sensory
endings, and some which depend on interaction between the different
neurones. But even now we can form some idea of the way in which the
grey matter ‘can act as a whole. The electric oscillations in the cortex
and in the grey matter generally are often due to a large number of units
pulsating in unison. Sometimes there are several competing rhythms,
and sometimes the collective action breaks down altogether, to reappear
from time to time when some part of the system is stimulated to greater
activity. When these collective rhythms appear the neurones are already
acting as though they formed one unit. There is no need to regard the
dendrites as forming a continuous network, electric forces may well
bridge the gaps between them, but they may form a system in which
activity can -be transmitted more or less freely in all directions. The
patterns of activity in a system of this kind would be like the ripples on

G2

170 SECTIONAL ADDRESSES

the surface of a pond, with the difference that some of the ripples may
occur spontaneously, whilst others are due to incoming signals. Inter-
ference figures and nodes of vibration may then be all important. ‘They
would at least give a basis for the recognition of relations such as those
of triangularity or squareness without the need for an excitation of specific
points, and they might be formed with less distortion in a large pond
than in a small one.

This does not take us very far: in fact, the major problems of the
central nervous system are left in greater obscurity than ever. But no
one can observe these ceaseless electrical pulsations without realising
that they provide a fresh set of data and may give a fresh outlook on
the working of the brain. The facts are still too uncertain to be worth
treating in greater detail. But they accumulate rapidly, and several
lines of evidence seem to lead in the same direction. For the present
it is enough to state our problem, that of the organisation of neurones
into the nervous system. It is still a physiological problem, and I hope
that a solution will be found on physiological lines. If it cannot be found
it will be extremely interesting to see where the breakdown occurs, and
if it can it will be even more interesting to see what light it throws on
the relation of the nervous system to the mind.

SECTION J.—PSYCHOLOGY.

THE STATUS OF PSYCHOLOGY AS AN
EMPIRICAL SCIENCE

ADDRESS BY
PROF. F. AVELING,
PRESIDENT OF THE SECTION.

As a text for this address, I quote a statement made by a very distinguished
physicist. Sir Arthur Eddington writes: ‘ Mind is the first and most
direct thing in our experience ; all else is remote inference.’ Now this
statement may mean one of several things. It may mean either that we
directly apprehend the mind itself as an experiencing entity, or that we
know, and only know directly, phenomena, the objective mental contents
and subjective states which, as at one time it was widely held, constitute
our minds or consciousnesses. In this address I shall maintain that we
know both, the former as an existent in every act of experience, and the
latter as events within experience. And I shall maintain this for two
reasons : first, because I find it to be so on introspection ; and, secondly
(though this perhaps is not a psychological reason), because, unless we
grant the immediate awareness of the self as existent and active, as well
as phenomenal occurrences in experience, it is impossible, so it seems to
me, to account for our belief in an existing external world and for many
of the conceptual constructions by means of which the various sciences
attempt to explain it. I do not wish to prejudge the issue of the problem,
which, as you realise, is an epistemological as well as a psychological one,
by asserting anything whatever with regard to the nature of this self that
we experience directly ; but I do wish to assert the reality of the experi-
ence. For me at least it is as real as the sensory experience in which the
physical world, including my own body, is revealed to me.

INADEQUACY OF SENSORY EXPERIENCE.

There is, then, I maintain, more in ‘ mind ’ than the sensory experiences
which form the starting-point for physical science. This begins with the
phenomenological world, a world of objects so-appearing to us ; and, on
the basis of this experience, abstraction made from the fact that it is
experience, a physical universe of reference is built up in scientific thought.
It is thus apparent that physical science, omitting a great deal of experience
from its purview, makes a selection of experiences. Moreover, in con-
structing from these the physical universe, it makes use of concepts which
cannot be discovered among those particular selected experiences that
form its own peculiar subject-matter. What Eddington calls ‘ remote

172 SECTIONAL ADDRESSES

inferences ’ are only made possible by the occurrence of mental processes
which are also experienced, though not among the crude sensory data with
which physical science is primarily concerned. ‘Thus all the sciences of
Nature begin in sensory experience. ‘They abandon this experience for
conceptual construction. But they return once more to experience to
verify their constructive work. For it is not only the function of science
to theorise. If it did this alone, it might end in crazy hypotheses and wild
speculation. Its function is also to predict and control. And only in
the immediacy of experience can the accuracy of the predictions be tested,
or the competence of the controls be established.

EMPIRICISM.

I take it that an empirical science is either one which, as the term
implies, is supported by the evidence of the senses, or one which is built
up out of the elements of experience. Physical science, beginning and
ending in sensory phenomena, is an example of the first kind ; psychology
an example of the second. But the ordinary use of the term ‘ empirical ’
limits experience to that of a sensory nature. My plea is that this limita-
tion is an arbitrary one and due to a philosophical prejudice. There is
more in experience than sensory elements. Apart from the self and its
states, affective and volitional, to which allusion has already been made,
there are thought-things as well as sensed-things, relations as well a:
elements, correlates as well as original fundaments, in experience. The
universe of physical science, for example, consists of thought-things ;
it is a conceptual universe erected on the foundations of a sensed one.
The external world, as presented to us by contemporary science, possesses
none of the glamour and richness with which it is clothed in sensory
experience. It has no colour, nor sound, nor odour, nor warmth, nor
extension, nor shape, nor material substance. Yet the physicists would
tell us that they are dealing with ‘ reality’; and that ‘ reality ’ in itself is
not what we naively suppose it to be. The world that has successively
been conceived as a world of extended and solid objects, a world of atoms,
of electrons and protons, of wave motions, is more physically ‘ real ’ for
physics than the everyday world in which we consciously live. It must
be so, for indeed it is looked upon as the cause of our conscious world.
A secular controversy, not yet concluded, has been waged as to which of
these worlds is the more ‘ real’ ; for the setting of them over against each
other is at once as modern as mathematical physics and as ancient as
Greek philosophy. In calling attention, however, to the distinction, it
is not with a view to appraising their relative degrees of ‘ reality.’ It is
in order to point out that both thought-things and sensed-things do in
fact occur in our experience taken as a whole. A perfect mathematical
plane triangle when an object of thought, although created by us as the
result of a purely mental process, and never encountered in any sensory
fashion whatever, is an experience just as much as a seen or felt (and
mathematically imperfect) triangle cut out of wood or paper is. Each is
referred to ‘ some thing’; but both are experiences, whereas the ‘ some
things ’ are not.

J.—PSYCHOLOGY 173

EMPIRICAL AND EXacT SCIENCES.

In the same way as the sciences of Nature, concerning themselves with
sensed-things, make a selection from among our experiences, omit many,
and abstract from the fact that they are experiences of ours, so other
sciences, concerning themselves with thought-things, make another
selection of experiences, and consider them as if they also were independent
of us. The empirical sciences that begin with sensory material work
from this towards its explanation on conceptual lines. ‘Those sciences
like mathematics, on the other hand, that begin with abstract quantitative
concepts, work from these concepts and their relations towards a state-
ment of the implications that are contained within them. The former
sciences derive the force of conviction with which they impress us from
the fact that they are ultimately based upon the evidence of our senses—
‘Seeing is believing.’ The latter likewise convince us by their proofs,
because their conclusions evidently follow from their premisses— There
is no proof like a mathematical proof.’ The point to be stressed again,
however, is that both these kinds of science are selective of their material
and leave out of account much experience which, as such, is as good as any
other. If seeing is believing, and mathematical proof convincing, the
immediate living experience of myself knowing and feeling and willing is
most impressive of all. Though not a Cartesian, in this I agree with
Descartes that such experience is not merely believable or convincing,
but indubitable. I suggest that these neglected experiences are necessary
to explain the constructions of the empirical sciences of Nature, for we
need no longer concern ourselves with the deductive sciences. And
I further suggest that it is psychology, concerned with the totality of
experience, objective and subjective alike, of which we are or may be
conscious, and making no abstraction from the fact that it 7s experience,
which provides an account of the empirical origin of principles of systema-
tisation and explanatory concepts alike which are used in the other sciences.
Though these principles and concepts are abstract, and indeed vary in
degrees of abstraction, from qualities and their relations, through quan-
tities and their relations, to being and its relations, in a sort of hierarchical
order, they are and must be abstracted from something ; and if that
something is not the sensory material with which physical science deals,
then it must be discovered in some other region of experience. To
support this contention it is not necessary to have recourse to innate
ideas ; for it can be shown that observable mental processes, other than
the apprehension of sensory experience, can account for the facts. And
these processes are the apprehension and abstraction of relations between
any experiences, this term being taken in the broadest sense, the pro-
duction of correlates in respect of any experience, and the immediate
awareness of the self energising, or being in one way or another busy
with its objects. I summarise these considerations as follows. All
systematic principles and explanatory concepts are in some way derived
from experience. They are all mental products, the results of mental
processes. They differ in degree of abstraction. Psychology is concerned
with the totality of experience as such, and the processes, among others,

174 SECTIONAL ADDRESSES

by which systematic principles and explanatory concepts come to be
formed. And it is the most empirical of all the sciences, since the con-
cepts of which it makes use are drawn directly from within experience
itself, or, if inferences from it, are the least remote of all. I shall hope to
illustrate this by reference to several of the explanatory concepts actually
in use in physical and biological science and in psychology. But before
doing this it will be useful to recall and distinguish the several stages by
which science proceeds and in which such concepts are reached.

DATA OF SCIENCE.

The first step taken in any empirical science is to examine, describe, and
classify the objects, or aspects of objects, with which it deals; such
classification being made on the principle of similarity and difference,
which, it may be noted, does not involve inference, but depends upon the
immediate experience of relations. The first step in psychology will
accordingly be to observe, describe, and classify mental processes.as such.
Psychologists are fairly well agreed on the broad classification of these
processes under the three heads of cognition, affection and conation, or
knowing, feeling and willing, as aspects or actualisations of the self. But,
though I have used the terms synonymously, I may note that there appears
to me to be good evidence that conation (striving and doing) and willing
(resolving, intending, choosing) cannot be included in the same general
category ; and, accordingly, that there are at least four broadly irreducible
kinds of mental event, which will require four groups of concepts to explain
them. Classification, however, does not merely mean grouping together :
it means separation as well. ‘Thus cognitive processes separate into
sensory perception, conception, judgement, reasoning and remembering,
for each of which a different explanatory concept may be needed. Though
memory, for instance, may be involved in perception, we cannot explain
remembering and perceiving in the same way. Incidentally, the postu-
late of retentivity is a good example of the kind of inference made in
psychology. It is evidently an inference, for we do not experience
retentivity. But it is not a remote inference ; and does not become so
until we further postulate some such thing as persistent brain traces to
account for it. Similarly different concepts may be necessary to explain
the experiences of desire, resolution, impulse and striving, whether they
are classed under two heads or one, and no matter how closely one may
be involved in the other.

STRUCTURAL ANALYSIS.

The next step consists in the finer structural analysis, so far as this is
possible, of the phenomenological data. In psychology, this means the
further splitting up of the products of mental processes. On analogy
with the procedure of the chemist, who analyses a chemical compound
into its constituent elements, or of the anatomist, who dissects out the
fibres of a nerve trunk, the psychologist analyses a percept, memory,
emotion or will-act. The proverbial seen orange yields in such an
analysis sensory factors of an elementary kind—colour, odour, sapidity,
smoothness, and the like. It cannot be said, however, that these are all

J.—PSYCHOLOGY 175

actually seen, any more than the thinghood with which the orange is
invested in our thought. Apart from the shape and colour, all the rest
comes from other experience than visual. ‘The simplest case of visual
perception is illustrated by a coloured figure, in which (except for thing-
hood) the experience is wholly visual ; and here analysis gives shape and
colour as elements. It has been objected that such analysis destroys the
mental ‘ whole’ which is so analysed, just as chemical analysis destroys
the compound, or anatomical dissection the preparation ; and this would
be still more true did the anatomist separate living structures. He could
not, by merely bringing them together again, restore the organism, any
more than the chemist, by merely adding his elements together, could
recreate the compound. And, indeed, even though we are unable to
separate one sensation from another in a percept, and can only distin-
guish them in our thought, this objection holds good. For, if we think
the sensations separately, and then attempt to add them together con-
ceptually, we discover that the mere sum of sensations is not the equivalent
of the percept. This objection has been urged particularly against the
work of the introspectionist schools, as if they were concerned only to
find the mental elements out of which all consciousness was once supposed
to be compacted. But introspection has discovered more than the mere
sensations that have been distinguished. It has found relations which
obtain between the sensations, as well as relations obtaining between
abstract concepts, and between concepts and percepts also. This dis-
covery is one of the most fruitful of all the empirical observations of
psychology. A similar consideration might be developed in respect of
the psychology of volitional processes. The Louvain school, for instance,
like that of Wiirzburg, analyses the elements that enter into processes of
resolution and attainment, and of choice. But it would be a mistake to
think that these elements, so analysed, when conceptually put together
again, are the equivalents of the will-processes. Here also are discovered
relations which obtain between them; and among these is that most
important of all real relations, the relation, namely, of cause, which is so
closely identifiable with the self. It is in virtue of this relation that a
will-act from beginning to end is constituted as a temporal whole. If
one keeps in mind the fact that both in spatial and temporal ‘ wholes ’
neither the sensory and volitional elements nor the relations occur in
isolation, this procedure of structural analysis is fully justified.

FUNCTIONAL ANALYSIS.

A further step is to discover by functional analysis the conditions or
laws of occurrence of the various events with which the science is con-
cerned. In psychology, this has meant in the past the attempt to relate
physical stimuli and their intensities with psychological occurrences,
as in the case of Weber’s Law; or to relate physiological events with
psychological ones, as in the localisation of sensory and motor functions
in definite areas of the cortex, or conative and emotional changes with
the physiological disturbances indicated by the pneumograph, sphygmo-
graph or psychogalvanometer. ‘The establishing of such relations between
physical properties and physiological processes, on the one hand, and

176 SECTIONAL ADDRESSES

psychological processes, on the other, requires, however, that we shall
already have taken a step away from the empirical standpoint in the first
sense of the term ; for here we are trying to equate a sensory experience
with a thought-object, physical or physiological. My sensory impression
of the weight of a loaded can as greater or less than that of a previously
lifted can is measured against the ‘ real ’ weights of ‘ real ’ cans as indicated
by a balance. But what do I know of ‘ real’ weights and ‘ real ’ cans ?
I have kinesthetic experiences and can discriminate between them ;
I refer these to cans, and call them weights. I have likewise visual
experiences of coloured shapes (the balance and cans) altering their
spatial relations ; again I refer these to the cans, indeed to the same cans,
and say they are due to weight. So far as sensory experience alone goes,
I am equating amounts of felt effort with amounts of seen movement,
and arguing analogically from one to the other. But how is this possible,
since the two sets of experiences are not only different, but absolutely
irreducible ? Only, I suggest, because I have conceived something
which is contained neither in the experience of effort nor in that of visual
movement—namely, a physical can with physical properties affecting me
in these ways, a ‘ same thing ’ appearing under two (or more) irreducible
forms.1 But the kinzsthetic experience of weight does not always
correspond absolutely with the visual indication ; for the balance can
detect differences in weight better than I can, or so I believe. And
I believe this, not in virtue of the sensorial experiences alone, but because
of even more conceptual construction than has already been indicated.
In a similar manner, my experience of conation or emotion is equated
with the visual indications of the instruments I am using. I report more
or less of ‘ alertness’; I find the galvanometer deflections of greater or
less excursion ; and I take these to register more or less physiological
disturbance which is correlated with my experience. Again, there is a
vast amount of conceptual construction involved in my conclusions.

These conceptual and inferential procedures, however, are thoroughly
justified if we admit, as I think we must, that not only sensory experience
but all experience must be taken into account ; and then we must concede
a like right of citizenship to whatever we are able to discover within it.
As we have seen, we find thought-objects as well as sensed-objects and
relations both ideal and real. Above all, we find an active self busy with
all these mental objects and relations in the various ways of sensing,
thinking, feeling, willing, striving, and the like. It is in this complete,
unselected experience that we discover the experiential grounds for all
our inferences.

EXPLANATORY CONCEPTS.

The last step is to find the least number of suitable explanatory con-
cepts to cover all the data. Like the conditions and laws of occurrence—
for indeed they are reached by the same process of functional analysis—
these may be physical, physiological or psychological. In point of fact,
for the most part those that have been advanced have been physiological—

1 Incidentally, this difference between sensed-weight and thought-weight is,
I believe, an explanation of the size-weight illusion.

J.—PSYCHOLOGY 177

special sensory organs, local cortical areas, inhibition centres, association
fibres, resistance at synapses, drainage of neural energy, and so on.
There can be no doubt that some of these concepts are illuminating for
psychology, but again at the price of abandoning the purely empirical
standpoint in the first sense of the term, and borrowing from experience
other than sensory in order to make explanatory use of them. And indeed
the experience from which the loan is taken is precisely that for which
no physiological explanatory concepts are available. While we may
accept engrams as the physiological reading of retentiveness, association
fibres as correlated with the linkages between ideas, and the like, there
is no suggestion forthcoming from physiology as to what may be the
physiological bases of becoming aware of experience, abstracting relations,
producing correlates, the volitional control of mental process, or the
intimate and immediate awareness of self. Moreover, some of the
physiological concepts in question have in the first instance simply been
taken over from psychology, others are yet very speculative and uncertain,
while others again, plausible enough in hypothesis, would by most ortho-
dox physiologists themselves be rejected, as, for instance, those of the
Gestalt theoricians. Still the very fact that these last have been seriously
put forward shows how little definitely ascertained physiological knowledge
is as yet of use in explanation of mental events.

In any case, the physiological phenomena, like the physical ones, do not
contain the principles of their own explanation within themselves. When
we examine the segmentation of a cell under a microscope, we conceive of
it as a process going on in an existent, material and unitary thing. Whence
do those concepts of existence, matter, unity and thinghood, come? Cer-
tainly not, I suggest, from the observed visual phenomena. When we
stimulate the nerve of a nerve-muscle preparation and notice a contraction
of the muscle, we conceive of the event asacausalone. Whence did we
derive our notion of cause? Not, again I suggest, from the observed
sequence. When we measure the intake and output of a living organism,
we do so in terms of energy. From what experience is that concept of
energy taken? Again, not from any one, nor from the sum total of
observations involved in the measurements. All these and like beliefs
with regard to physiological processes, and in particular in respect of
their connection with mental events, are inferences from the phenomena,
made in virtue of experiences of another kind. Physiology, accordingly,
like physics, is an empirical science in the first sense because it concerns
itself with certain selected sensory data ; in so far as it is explanatory, it
is an inferential science. It is none the worse for that, however, even if
it must borrow some of its concepts from psychology. ‘The point is that,
generally without acknowledgment, it does so borrow from psychology
in order to establish the very constructions it offers to reloan to that
science as explanations of mental events.

PsYCHOLOGY AS SCIENCE OF EXPERIENCE.
We turn now to psychology, the most empirical of all the sciences in
the sense that it deals directly with experience as such, makes no partial
selection, but embraces all experiences alike indifferently, and at their

178 SECTIONAL ADDRESSES

face value. And here I wish to show how scientific explanatory concepts,
together with concepts which the physical and biological sciences other
than psychology usually reject, are all derived from immediate experience.

ANALYSIS OF CONCEPT OF CAUSALITY.

Perhaps one of the best ways of developing this thesis is to consider
first the historical evolution of the notion of causality, which was invoked
to account for movement or change in the physical universe. After the
two exceedingly significant though somewhat naive conjectures of love
and hatred, and of mind as causal principle in Nature, an analysis was
made by Aristotle, as a consequence of which five explanatory concepts
were considered necessary to show how any change or movement could
come about. There were the two intrinsic principles constituting the
thing to be changed. One of these—‘ matter "—was conceived to be an
indeterminate though determinable principle, which endures throughout
the process of change and is, before the alteration, specified in its particular
mode of being by a determining principle—‘ form.’ Change means that
a new form comes to actuate the matter ; and it involves also the negative
concept of ‘ privation,’ since before the change the alterable thing is
‘ deprived ’ of the mode of being it will exhibit after the alteration has taken
place. Further than this, there are the two concepts of the agent which
brings the change about, the ‘ efficient ’ cause extrinsic to the thing changed,
and the reason why the agent acts, the end, goal or ‘ final ’ cause, towards
the realisation of which the action is directed. Like the earlier attempts,
this exceedingly acute analysis of causation, applied as it was to events in
the external world, is an entirely anthropomorphic one. It reads into
physical phenomena, in a conceptual manner, experiences which are
wholly subjective. And this is at once apparent in all the examples that
are brought forward to substantiate it. For instance, I, the agent or
efficient cause, mould a thing, let us say wax, which is not now a sphere
but a cube, into a spherical form, because I wish to have a sphere. Or
I hew a formless block of marble into the shape of a statue. These are
goal situations, in which an end must be intentionally set up before any
action takes place ; something is consciously aimed at, or intended.

Dr-ANTHROPOMORPHISATION OF PHYSICAL SCIENCE,

Now, in the course of the development of scientific thought, first the
concept of finality was jettisoned as not applicable to events in the physical
universe : and certainly, though by analogy we can still apply that
concept, derived from our own immediate experience of volitional activity,
to the events of Nature, we are unable to discover it within the phenomena
themselves by which Nature and its events are displayed to us. In those
phenomena alone there is no indication of goal-seeking. The next con-
cept to be dropped was that of efficiency, in the sense that one thing
actually produces changes in others. And though, again by analogy,
we can apply this concept also to the realities we believe to be sensorially
presented to us, efficiency is in fact nowhere to be found in the phenomena.
We are left, then, with sequences of antecedent and consequent, conceived

:

J.—_PSYCHOLOGY 179

as equivalent in amount of energy. To be sure, temporal sequences, as
well as spatial relations, are to be observed in the phenomena themselves,
and even similarities that can be interpreted as equivalences ; but they do
not display energy, any more than teleology or efficiency. Most men of
science go no further than this in their rejection of the concepts originally
invoked to account for physical causality. ‘That of ‘ privation,’ perhaps
because too obvious, is seldom considered; while ‘ material’ and
‘formal’ principles linger on under other names, such as spatial con-
figuration or arrangement in stereochemistry, or in the physics of the
atom. Other men of science, more mathematically and philosophically
minded, substitute equations for equivalences, and causal indeterminism
for rigid determinism. The history of the successive modifications of
the theory of causality, thus briefly and inadequately outlined, is evidence
of the de-anthropomorphisation of physical science. At every step, how-
ever, in the refinement of the physical concept one fact emerges—namely,
that at no point is it possible to dispense with concepts derived from
experiences other than those actually to be explained. Aiming at ends,
efficient action, energy, equations, are not found in the phenomena in
question, any more than thinghood and unity which are necessarily
involved in any and every conception of causality. What, then, are
those other experiences in which we have the concrete facts from which
we abstract the concepts that we apply to the phenomena ?

ORIGIN OF SCIENTIFIC CONCEPTS: 'THINGHOOD, UNITY.

Beginning with the last concepts named, the notions of ‘ thing,’ ‘ same
thing,’ and of ‘ unity’ are derived, and can only be derived, from the
immediate awareness we have of ourselves as unitary, existent and self-
identical beings. When I see and handle any object, such as a book,
I have visual and tactile impressions which I refer to an extra-mental
thing, it matters not what it may be as a physical object. The visual
impression, however, is not the tactile one ; and neither, nor both to-
gether, is the book. Sensorially, I do not apprehend the book at all, but
only ‘ properties’ of the book. Why, then, do I think that there is a
book? I interpret the phenomena, analogically with my immediate
awareness of myself as affected by states, and posit a physical book with
physical properties to account for the phenomena. Only later do I refine
my notions of physical ‘ properties,’ and conceive them, together with the
book, not as like but as very unlike the original sensory data. The kind
of mental process that occurs here is even more strikingly illustrated by
another consideration. I put the book aside, and busy myself with
some other matter. ‘Then I pick it up again, and see and handle it afresh.
I believe it to be the same book. But on what grounds? On the grounds
of the similarity of the previous and present phenomena. ‘To apprehend
a relation of similarity between phenomena, however, is not to apprehend
identity either between the phenomena? or between the physical book

_ previously posited and again posited now. There is no sensorial way of
apprehending or of establishing identities. What happens is that again

2 Indeed, as mental occurrences they are absolutely different.

180 SECTIONAL ADDRESSES

I interpret the similar phenomena, on analogy with my immediate
(non-sensorial) experience of self-identity, and posit a selfsame physical
book enduring intime. Finally, my notion of unity also is derived from
the same source of immédiate, non-sensorial experience of myself, and
analogically applied to sensed-things and thought-things alike.

ORIGIN OF SCIENTIFIC CONCEPTS: ENERGY.

Passing next to the explanatory concept of energy, still in general use
in the sciences of Nature, we find that this also is not to be discovered
among the particular selected sensory phenomena with which they deal.
This concept of physical energy, kinetic and potential, refers to a postu-
lated persistent entity (‘ same thing ’), constant in amount, which may be
transformed from one state to another, and is capable of doing work in
bringing about physical movements. To what source in experience can
we trace this notion? Clearly it is not sensorially apprehended in the
physical phenomena observed. It might at first sight seem that it should
be traced to kinzsthetic experience, or the sense of effort in bodily
activity by which different kinds of work are done ; that we read this
analogically into the physical phenomena, and project the result into a
‘ physical’ world. But I do not think that this can be a true explanation,
for the reason that, like the properties of the book just considered, the
sense of effort, experienced in one case, is only similar to the sense of
effort experienced in another. It can in no sensory way be shown that
they are identical. Likewise, the body, in the same way as the book, in
any successive pulses of sensorial apprehension, displays no more than a
relation of likeness. Accordingly, I appeal again to my immediate non-
sensorial experience of self-identity, in which I discover an active self
energising in one way or another. It is true I do not find any perpetual
and unbroken continuity of self-consciousness ; but, whenever I am
conscious, notwithstanding all the changes that take place in the pheno-
menal world, including those of my own body, I am conscious of the same
unitary and self-identical I. Now, can we find the basis of the concept
of energy here? I maintain that we can, in the sense that this self does
actualise, or energise, in different ways, now perceiving, now judging,
now resolving, now enjoying, and the like. And from this I infer, though
the inference is by no means a remote one, that a self which does all
these things can do any one of them, even if it is not actually doing that
one at the moment. Here I find, in immediate living experience, the
source from which the abstract concepts of energy and dynamism are
drawn ; and these concepts, applied to the phenomena of motion or change,
become those of kinetic and potential energy, and are projected upon an
extra-mental world of things which we have conceived on analogy with
ourselves.

VALIDITY OF SCIENTIFIC CONCEPTS.
There are no doubt other lines of approach to the development of the

thesis I am maintaining than the one I have taken ; but I have chosen this _

because it most readily allows me to stress the point I wish to make. If
we begin with the principles and postulates of which the different sciences

J.—PSYCHOLOGY 181

make use in systematising and explaining their selected data, without a
previous examination of their source of origin, just taking them for
granted or as obvious, we are extremely likely to give them precedence
over all others, and to suppose that they possess a greater validity than
others, or even that they alone are valid. In this way, it would seem that
commonly accepted principles of physical science, such as those of deter-
minism or the conservation of energy, have come to be regarded not only
as of supreme validity in physics, but even as strictly applicable also to
psychological events, including those from which, by way of conceptual
construction, they have been derived. J am here in no way trying to argue
that these principles and postulates are not true. ‘There may be auniverse
of physical objects, in which energy is conserved, and all events rigidly
determined. What I am arguing is that these thought-things are in-
ferential constructions from sensory phenomena, which are possible only
because of experiences other than sensory and phenomenal, and that they
must not be permitted to displace or contradict those very experiences in
virtue of which they are built up. If we had worked backwards in the
history of the evolution of the notion of causality, instead of forwards as
we have done, we should have found that we were leaving the region of
remote inference for that of proximate inference, and this again for that of
experience pure and simple, until at last we reach the immediate experience
of the self as actively engaged with its mental objects. We should have
reached then the central core, so to speak, of all experience. And here
we find, not merely a concept nor a phenomenon, but an actual thing, or
active substance existing in itself, from which the notions of thinghood,
substance and activity are abstracted ; we find here an efficient cause
actually producing its effects, such as remembering a forgotten event or
altering the character of phenomena by willing to do so, and from this the
concept of efficiency is derived ; we find a substantial cause in multiform
relations with sensed-things and thought-things, among which is the goal
relation, whence the idea of finality or teleology arises.

PSYCHOLOGICAL PROCESSES OF CONCEPT FORMATION.

From such experiences as these, to which we apply relations likewise
experienced, we derive the proximate inferences such as those of reten-
tiveness or mental energy, to which allusion has already been made.
From them also, as well as from our immediate experiences of the appre-
hension of relations and the production of correlates, we infer the proxi-
mate principles of noetic eduction. And, lastly, from them again, by
further applications of relations to them, to phenomena, and to correlates
already produced in our thought, we reach the far more remote inferences
of which use is made in the sciences of Nature ; for here we refer our
experiences to transexperiential, extra-mental causes. But the grandiose
system of the natural sciences as a whole stands in virtue of these original
experiences ; and it would crumble away into less than dust did they not
guarantee it.

It is for this reason, provided the meaning of the term be not limited
to sensory experience only, but be extended to all and everything that may

182 SECTIONAL ADDRESSES

be experienced, that I maintain that psychology is the most empirical of all
the sciences.

Perhaps I may end with another quotation from the writings of the
same distinguished physicist from whom I quoted as a text: “ We have
found a strange footprint on the shores of the unknown. We have
devised profound theories, one after another, to account for its origin.
At last, we have succeeded in reconstructing the creature that made the
footprint. And lo! it is our own.’

SECTION K.—BOTANY.

THE TYPES OF ENTRANCE MECHAN-
ISMS OF THE TRAPS OF UTRICULARIA
(INCLUDING POLYPOMPHOLYX)

ADDRESS BY
PROF. FRANCIS ERNEST LLOYD, M.A., D.Sc.,

PRESIDENT OF THE SECTION,

Ir is an honour greatly appreciated atid wholly unexpected to have been
selected to preside over your Section of Botany on this occasion, the
Leicester Meeting of the British Association for the Advancement of
Science. To express my feelings in any plenary sense would take too
much of your time, better spent on the subject before us. I therefore
offer you my best thanks for your confidence. If the subject which I have
chosen is one as full of interest as it is devoid of practical importance (so
far as we can at present see), I may plead that I am following the example
of your illustrious Hooker, whose address at the Belfast Meeting in 1874
was in the same field and equally open to the criticism.

This subject * has the purpose of setting before you the variety and, so
far as I have compassed them, the minutiz of structure and behaviour of
the door, or valve (as Darwin called it), and its contactual parts, par-
ticularly the threshold, of some 75 species of the genus Utricularia. Such
a number out of the whole of some 250 known species may be taken as
sufficiently representative to allow us to obtain a fair picture of the lot.
That I have been able to examine this fairly adequate series has been due
to the helpfulness of correspondents in various parts of the world,
acknowledgments of which I have already made elsewhere. It must,
however, be added that the study of preserved material to any good purpose
would not have been possible without the foundation work of studying
such living material as has been available, including the following species :
U. vulgaris, U. intermedia, U. gibba, U. emarginata, U. capensis, U. reni-
formis, U. cornuta, U. longifolia, U. coerulea, etc. In this connection
I should not fail to add that I have had the able co-operation of Mrs. E. R.
Johnson, née Reed, of Perth, Western Australia, and of Mr. Allan
McIntyre and Mr. A. V. Giblin, of Hobart, Tasmania, in carrying out

1 The present paper may be considered a continuation of my presidential
address, entitled ‘The Carnivorous Plants—A Review with Contributions,’
delivered at the recent meeting of the Royal Society of Canada, May 18~20,
1933. A motion picture showing the action of Drosera and of Dion@a, exhibited
te eae occasion, is shown as part of the motion pictures as completed especially
or this.

184 SECTIONAL ADDRESSES

certain critical observations, which enable me to say with conviction
things relating to Australasian species which otherwise had not been avail-
able in the living form and whose peculiarities well-nigh defied analysis.
I refer to U. dichotoma and related species, and to Polypompholyx.

The species of Utricularia (I include Polypompholyx for the purpose of
description from now on) fall into two major ecological groups: the
submersed, floating forms, of which the familiar U. vulgaris and less
familiar U. purpurea are good examples, and the so-called terrestrial forms,
of which the frequently cultivated U. reniformis and U. cerulea may serve
as illustrations. ‘This statement leads me to emphasise the fact that the
structure of the bladders, or traps (as I prefer to call them), is far more
uniform, almost to monotony, within the submersed forms, while the
contrary is true of the terrestrial. ‘That this should be the case seems
natural, as the environment of the submersed kinds is more uniform.
But that the diversity of the remainder should be due to the lack of
uniformity of environment is not so clear, since the lack is, I imagine, more
apparent than real. ‘The terrestrial species are all confined to a very wet
substratum, and grow usually as much submersed as the floating forms ;
and the species which appear to be the least limited in their need of water
are those which, like U. reniformis, U. longifolia, etc., grow in wet moss as
epiphytes, etc., and in spite of this are most like the submersed U. vulgaris
or U. gibba. Whatever the explanation, it is my present purpose rather
to display the variety of the traps and to attempt to explain their workings.

In order to approach immediately to this purpose I shall clear the way
by summarising those properties which are common to all.

1. Nature of Action—The trap is a snap-action mechanism—that is, it
acts with extreme suddenness, much to the surprise of Darwin when he
examined U. vulgaris.2, So swift is it that the whole action falls within
the limits of ;'; second, and by means of superspeed cinephotomicro-
graphy, taking 160 pictures a second, I have found that the opening
phase of the door falls within ;4, second, while the closing phase is
completed in four pictures, or #7, second. All the species which I
have examined act similarly. During this brief moment the side walls
of the trap spring out, the shape of the periphery as seen in lateral view
alters correspondingly, the door opens fully and closes, falling into a
semi-relaxed position, during which a column of water, carrying with
it any luckless animals if small enough, rushes into the interior of
the trap. The closing movement of the door shuts off the water
before the walls have completely relaxed, so that, on closure being
completed, there remains still some degree of ‘ negative’ pressure. As
Merl (1922) showed, complete relaxation may be procured experimentally,
either by puncturing a wall of the trap or by holding the door open for
a moment, thus throwing it out of action. I have shown also that cutting
the velum has the same result.

2 The action of the trap in U. vulgaris, U. gibba and U. purpurea is demon-
strated by means of motion pictures. By means of animated diagrams the
particulars of behaviour of the door are shown for U. gibba, U. vulgaris, U. cornuta
and U. c@yulea. The rate of movement of the door of U. vulgaris is demon-

strated with superspeed motion picture taken at the rate of 160 frames per
second. The question of irritability has been dealt with by me elsewhere (1932).

K.—BOTANY 185

2. Resetting —After discharge the trap resets itself after a period of
from 15 to 30 minutes or more, in U. vulgaris, or as long as 2 hours, more
or less, in U. purpurea. In this operation water leaves the interior of the
trap by diffusion through the walls, until an equilibrium has been reached
and the walls have become concave so much as to press tightly on each
other (in U. purpurea), or at least to be closely approximated (U. vulgaris,
U. gibba, U. cornuta). In other words, the trap acts as a cell when sur-
rounded by a slightly hypertonic solution of a sugar or salt if harmless ;
but in the case of the trap this condition is not necessary, though with
sufficiently high solutions of sugar, etc., within, the trap will take up
water rather than lose it. Czaja (1924) has studied this aspect of the
physiology of the trap, and tells us that the walls are semi-permeable,
allowing water to pass but not solutes, but evidently this is not the whole
explanation. For our present purpose we need not discuss this problem,
merely recognising the fact that water passes out from the interior of the
trap, thus producing a reduced pressure within. As a result, the outer
water presses equally everywhere—on walls and door alike. When,
therefore, the door is shifted out of its position of equal resistance, the
water pressing thereon pushes the door in. Thus is furnished a part of
the energy required to actuate the trap. ‘The remainder (an amount not
measurable, or at least not yet measured) is supplied by the tensions of
the (living) walls themselves, which, with an even water pressure within
and without, still always take on an extreme convexity, when the trap can
be said to be completely relaxed. From this condition a sound, undamaged
trap will reset itself in a period considerably longer than that required
after normal actuation when it is only partially relaxed.

The energy required for the actuation of the trap is derived from the
water pressure plus the outward spring of the walls. From now on, this
will be understood and no further reference made to it.

3. Watertightness—Since the above is always true, it must also be that
the door is watertight.2 I have shown (1929) that this watertightness is
owing to the presence of a membrane, the velum (Figs. 21-25), which
arises as a cuticular development from the pavement epithelium of the
threshold, though in certain species other regions contribute to produce
an accessory velum (Fig. 15), as we shall see. All the living species
examined conform to these statements. How the door is engaged when
the trap is in unstable equilibrium is a particular question, along with
others, as to the extent and proportions of the threshold, origin and
extent of the velum, and the method of actuation. These points, there-
fore, are to be considered specifically in what follows. There is, however,
one underlying fact which may be mentioned at once in this connection
—namely, that the free edge of the door is always longer than the threshold
at its inner angles (Fig. 23). The latter can be readily understood when
the development of the trap is considered and, as Meierhofer (1920) has
cleared this up, it is not necessary to further amplify. It follows that the
door edge cannot lie smoothly along the surface of the threshold when

* When the adjective ‘ watertight ’ is used, I imagine that it must not be taken
too literally. As long as the inleakage is at a lower rate than the outward
diffusion through the walls, the trap will work.

186 SECTIONAL ADDRESSES

it is parallel with a component thereof; or, conversely, if it does lie
smoothly, it is always oblique to the threshold. If, as in the former case,
the edge is parallel to the threshold, there must be a region where, when
the door is opened, it buckles. In the normal action of the door the point
of buckling, which is necessary to its opening at all, is structurally pre-
determined as to its position. How in particular this is accomplished
will further appear.

4. Histology of the Door—The tissues of the door are of two kinds
(always of two courses of cells), hinge and middle piece. The former
occupies a zone around the sides of the door, the latter a more or less
extensive area at the middle of the lower edge and extending upward from
this to some distance. Hinge tissue has a course of deep cells backed by
a thin course (Figs. 3-8). It is extremely flexible, and can bend sharply
through an arc of 180 degrees without damage. ‘This results, in large
part at least, from the character of the deep cells, whose periclinal walls,
inner and outer, are in the form of bellows. The anticlinal walls of both
courses are reinforced by numerous cellulose props which prevent collapse
on bending (Lloyd, 1932). In the middle piece the two courses of cells
are of equal thickness, and while flexible the tissue has a certain rigid-
ity and resists flexure in both directions equally. ‘The walls are very richly
provided with cellulose props. The function of the hinge is to keep the
door flexed outwardly as far as possible. If this outward stress is met by
the threshold, the effect of the hinge is to exert a thrust of the middle
piece against the resisting surface (cornuta type). Aside from the above,
each type of trap requires special treatment.

5. Trichomes.—In all species there are glandular trichomes on both the
outer and inner surfaces of the trap. Those on the outer surface are
usually sessile, of three cells (basal, mid- and capital cell—the last often
doubled), the pattern of structure of all the glandular cells wherever
occurring. These are found scattered over the whole plant surface, and
are not peculiar to the traps, on whose interior surfaces occur trichomes
of similar basic structure, but the outer two to four cells forming the
capital are elongated or, if with a single-celled capital, there is a single
sausage-shaped terminal or capital cell. Some species, therefore, have
quadrifid and bifid trichomes (as Darwin called them) devoid of cuticle,
the latter in the vicinity of the threshold ; or bifid and single trichomes,
correspondingly placed. They may be few or very numerous, e.g. in
U. longiciliata but six; in U. Jateriflora, sixteen; in U. vulgaris,
hundreds. The form is very characteristic, but familiar to anyone who
has only cursorily examined the interior surface of the trap of any species.

The distribution of these trichomes is various. There is always
a segregation of single and bifid, or only bifid trichomes: (a) on the
inner surface of the threshold bolster, (b) on the surface above the inner
margin of the threshold, and (c) on the general surface of the interior,
which may be very thickly studded everywhere, or may be many fewer
and placed in rather definite positions, e.g. they are frequently absent
from the flanks and confined to the more peripheral, especially ventral
region, as viewed laterally. What these differences may mean is obscure ;
I am inclined to regard such as of no importance whatever.

K.—BOTANY 187

6. Appendages.—The trap is usually provided with appendages, though
there are a few exceptions, e.g. U. cornuta (Fig. 1), U. nana. In the
submersed, floating, or semi-terrestrial forms resembling U. vulgaris,
there are two antennz which are more cr less fringed with long bristles,
and similar bristles radiate from the sides and top edge of the entrance,
but these may be almost entirely absent. Or, instead of antennz, there
may be two (U. Jateriflora, Fig. 13) to about seventeen (U. Kirkit) rows of
bristling trichomes, forming a funnel-shaped lead to the entrance, which
may also be provided with a proboscis projecting from the upper
(U. albina) or from the lower lip of the entrance (U. longiciliata) ; or the
latter may occur in the absence of any other appendages (U. elephas).
On the surface of it, these appendages have been interpreted as guides to
the entrance, but in many instances it is difficult to regard them as of
any importance whatever. For our present purpose these may be dis-
regarded, except as they may have some bearing on the character of the
entrance.

In order to avoid confusion arising out of the great mass of material,
I shall choose types of various groups for special consideration.

Tue Type U. cornuta (Figs. 1-8).

I begin with U. cornuta because it is the simplest in structure, though
not by this token a primitive form. Schimper published in 1882 a descrip-
tion which was wrong in most particulars, so far as the structure of the
door and threshold are concerned. My own account (1931), brief and
very incomplete as it was, was offered before I had had the advantage of
studying living material, and it is wrong in regarding the relaxed position
of the door in the set position. I can now make amends for my
inaccuracies.

The trap in lateral view is rounded with a protruding beak beneath
which is the entrance, and a stalk. ‘The large traps are about 1 mm. in
diameter (Fig. 1). Viewed on edge, the sides are seen to be concave
when the trap is in the set condition, and convex after actuation. Owing
to the approximation of the stalk and beak, an edge view, showing the stalk,
does not display the entrance proper, but this I have shown in another
figure (Fig. 2). In this we see that the entrance is bounded by a lower
lip in the form of an inverted arch, not quite circular. Above the edge of
the lip we see some irregular cells projecting radially. ‘These are the
forward courses of cells of the pavement epithelium. Hanging down-
ward from the beak and extending inward is the door. This figure is
a thick section, beginning at f, and extending as far back as, say, d, Fig. 3.
By consulting this latter figure one sees that the arched entrance leads to
a curved platform (approximately semi-cylindrical) lined with the pave-
ment epithelium, made up of glandular cells of elongate form, being the
capital cells of a closely packed tissue of glandular trichomes. Schimper
recognised these trichomes as being of structure similar to the glands of
the outer surface, as also did Goebel, Hovelacque and others for other
Species. But, hitherto, students have supposed that the pavement
epithelium is uniform in structure, which indeed, when regarded super-
ficially, it seems to be. If we dissect away the adjacent parts, so_as to

188

Se
SI

SECTIONAL ADDRESSES

ALS

SS)

rO

Og

K.—BOTANY 189

PLATE I—REFERENCES.

‘Fics. 1-8. Utricularia cornuta. Side and front view of the trap. ‘The
broken lines indicate the set and relaxed conditions.

Fic. 2. Front view of the entrance.

Fic. 3. Sagittal section of the entrance showing the relations of door and
threshold. d,, door in the set position ; d,, door in the open position ;
d,, door in the normally relaxed position; d,, door when fully
relaxed ; d.h., door hinge ; d.t., downward thrust of the lateral hinge ;
o.t., direction of thrust of the door exerted by the overhang ; and the
resultant thrust (c) when the trap is set. On the right the lure gland.

Fic. 4. View of the door as from beneath. m.p., middle piece; /.A.,
lateral hinge ; w.h., upper hinge. Cells in lighter outline are those of
the inner course. m.r.d.e., middle reach of the door edge ; J.r., lateral
reaches.

Fic. 5. Threshold. 7.z., inner zone ; m.z., middle zone ; 0.2. (v.), outer
zone which bears the velum ; d.h., door hinge ; g., gland which may
act as a lure.

Fic. 6. Transverse section of door and adjacent structures: (1) in
the set position; (2) relaxed after actuation. This section is
approximately one through arrow e, Fig. 3.

Fic. 7. Transverse section (arrow d, Fig. 3) of the door through the
upper region of the middle piece. The broken lines indicate position
taken when the door is opening.

Fic. 8. Transverse section of the door near the free edge (arrow c,
Fig. 3). ¢., the heavy line indicates the inner edge of the threshold ;
d., dotted line indicates the lower surface of the door edge. The two
oblique arrows indicate the direction of thrust of the lateral hinges on
the middle piece (m.p.). When the door is opened the middle piece
bends along the sagittal line.

190 SECTIONAL ADDRESSES

free the threshold, and carefully spread it (which unavoidably tears it,
spreading the cells a little, but not enough to disturb our observations),
We may recognise three transverse zones, which I designate the outer
(o.z.), middle (m.z.) and inner (7.z.) zones, delimited in Fig. 5. These
zones can be identified with those in Fig. 3, where the threshold is cut
sagittally. ‘The component cells having the same fundamental structure
throughout, we find that those of the outer zone are loosely packed and
that their cuticles are raised up to form a great mass of loose membranes,
the velum, which, when the door is closed and the trap set, renders the
door watertight. ‘The middle zone cells, on the other hand, are smaller
and tightly packed (their outlines, therefore, angular), and their exposed
faces are flat. ‘This zone is narrowest at the middle and spreads out fan-
wise toward the lateral limits of the zone, which furnishes a smooth, firm
surface against which the face and edge of the door can press when the
trap is set. The inner zone is narrow and lunate, composed of loosely
packed cells, with more or less irregular contour. Their general surface
is slightly uptilted toward the outside of the trap. ‘The back edge of the
threshold is in the form of a roll of tissue, tapering toward the ends.
I once thought that this furnished a resistant face against which the door
edge rests, but I was mistaken (1931). This point was finally settled by
photographing the door and threshold through the wall of the trap while in
the living, set condition—optically a rather difficult task.

The door extends from the end of the beak inwardly, is nearly twice as
long as broad, and contracted at one point (Fig. 4). This point coincides
approximately with the forward end of the threshold, along the lateral
margins of which the sides of the door are attached to the wall (d.h.,
Fig. 3). ‘The extreme ends of the free door edge coincide with the
inner angles of the threshold, while its edge coincides, when the trap is set,
with the inner border of the middle zone of the threshold. The histology
of the door, which is composed of two cell courses, is very important if we
are to understand its effectiveness. The mapping shown in Fig. 4
indicates four regions. The outer two-thirds, articulating with the wall
of the trap in the beak, is of cells which have their longer axes transverse
in the outer course and longitudinal in the inner. All these cells have
their radial walls strengthened by cellulose props, but these are much
more numerous and larger in the walls of the inner course of cells. Both
anticlinal walls of these latter are folded, bellows-like. ‘The inner course,
as thus constituted, is capable of much expansion and compression.
Their own proper tendency is to expand, so that a freed door bends
sharply outwardly. They can bend inwardly in response to pressure on
the door, however, so that at once they keep the door pressed on the
threshold, but can be bent inwardly when the door is opened by the
pressure of water, only to spring the door back into position when that
pressure is released. Among the outer course cells there is a number of
gland cells, with oval capitals, which may act as a lure (Figs. 3, 4, 6),
together with the special oval gland just below the lip of the entrance
(Fig. 2). The side walls of the door are constituted quite as the forward
region above described. ‘They (Fig. 4, /.4.) press firmly in lying in con-
tact with the sides of the threshold (m.z., Fig. 5) and exert a downward

K.—BOTANY IQI

thrust on the middle piece of the door (m.z., Fig. 8), which has quite
a different structure, in that the two courses are of equal depth, the cells
small and very densely studded with cellulose props, which appear, in the
face view of the cells, as more or less regular transverse bands. These
have the same function as elsewhere, but here are more numerous, because
of the severe flexing which the middle piece is subjected to during initial
opening of the door. ‘The properties of the middle piece are stiffness
and capacity of flexure in either sense. When the door is closed, the
middle piece is held firmly against the middle reach of the middle zone of
the threshold (/.4., Fig. 5) by the downwardly thrusting lateral hinges
Fig. 8).

in sddition to the door proper, the beak wall cells also take part in the
flexures of the door, and further exert a longitudinal thrust on the door,
so that this is pushed backward and downward. The thrust of the door
edge is then in the direction indicated by arrow c, Fig. 3, and is down-
ward against the threshold middle zone. The thrust exerted by the beak
is referable to the total flexures of the trap when exhausted ; when the
trap has been sprung and is relaxed, the beak is not bent downward so
sharply (d;, Fig. 3).

By making photographic silhouettes of traps in the set, relaxed, and
totally relaxed conditions, the difference in shape of the curvatures can
be recorded. It has thus been possible to record the position of the door
under these conditions. In the set condition the door, as betrayed by
the longitudinal aspect, is bowed upward, and the transverse curvature at
e and f, Fig. 3, will be flatter (Fig. 6). This has the effect of a more
directly downward thrust of the door edge. After actuation the sil-
houette of the door is as shown by the broken line d;, Fig. 3 ; the beak
being less bent and the thrust due to the beak being eliminated. If total
relaxation is obtained (as by puncturing the wall of the trap), the door
takes the position d,—the dot-and-dash line in Fig. 3. These contours
of relaxation serve to emphasise the significance of the curvatures seen in
the set condition, when the lateral areas (/.h., Fig. 4) clamp the middle
piece firmly on the threshold (Fig. 8), and the upper region of the door is
under transverse tension, bowing the door longitudinally. The chink
between the door and threshold is now filled with the membranes of the
velum, making the whole watertight.

Actuation is procured experimentally by slight pressure of a needle
point (the operation must be without damage to the tissues) on the surface
of the door in the region e-f, Fig. 3. Sometimes a very light touch will
do the trick, but I get the impression that the mechanism is not so sensitive
as that of U. purpurea or U. vulgaris. The smallness of the trap makes
experimentation difficult. What happens in nature can only be inferred.
It is to be noticed that there is a total lack of appendages supposed to act
as guides and lures, the only equivalent being the gland below the
‘entrance and the glandular trichomes on the door surface, aggregated
chiefly in the region of actuation. But it is not difficult to make the
inference that a small animal (Schimper mentions rotifers, worms and

“ For a full discussion of the histology of the door, see my paper of 1932 in the
Canadian Journal of Research.

192 SECTIONAL ADDRESSES

crustaceans, and I have seen the same or similar forms), crawling about
the entrance, could enter far enough to touch and press inwardly, slightly
denting the surface of the door in that region. This would upset the
unstable equilibrium and the pressure of water would take advantage of
the initial flexure, which would then travel toward the door edge at the
middle of the middle piece (Fig. 7). ‘This, in turn, would nullify the
lateral thrusts of the sides of the door, and the water pressure would,
folding up the sides, open the door (Fig. 3). ‘To be noticed is the fact
that the structure of the door in the region of actuation is such that it
would give readily to local pressure, though the distributed water pressure
would be resisted (Fig. 6).

In summarising the case before us, we note that the threshold is broad
(ratio of breadth to length, 2: 1 approximately) ; that the door is long
and narrow and has no special tripping mechanism, an initial dent being
sufficient to upset the unstable equilibrium ; and that the velum is very
broad. The door is held in tight application to the threshold by the
thick lateral regions, these exerting a downward thrust on the middle
piece, which can bend longitudinally. ‘The end of the beak also con-
tributes to the door mechanism, and has inner course cells which are
strengthened by props. Although simple in appearance, the door
mechanism is elaborately endowed with suitable curvatures and cellular
structures which make its behaviour possible. It is a snap-action
mechanism, as determined by much careful observation.

U. cornuta is a New World type, and the few species have the identical
trap structure. A species (my No. 43) from the Aripo Savannah, Trini-
dad, collected in fluid by Professor R. B. Thomson in 1931, with spatulate
leaves (thereby distinguishing it from U. cornuta with linear leaves), and
U. juncea (Vahl) Barnh., collected by De la Cruz, 1543, in British Guiana
(my No. 108) and by Britton and Britton (29) in Porto Rico (my No. 110),
are the only other species I know. Of U. juncea I have seen only
herbarium material.

Tue Type U. CAPENSIS (Fig. 20).

I choose for the next type U. capensis, which I had the opportunity
to study in the living condition on the occasion of the meeting of the
British Association at Cape Town in 1929. For the use of the laboratory
and facilities J am indebted to Miss E. L. Stephens, who has continued
to help me in various ways. ‘The reason for the choice of this type is
the similarity in the general proportions and curvatures of the mechanism
we are considering to those of U. cornuta, though it differs in having no
beak, in the sense we have used the term for that species, nor is the
posture of the door quite the same.

The trap (1 mm. long) has a thick, and in front, surrounding the
entrance, massive structure. It is one with a considerable number of
species in which the front is provided with a number of radiating rows
of long trichomes, graduated in size, forming guides to the entrance,
as we may suppose. These trichomes are glandular and have the typical
three-celled structure, the basal cell being much enlarged and often sub-
divided. The number and arrangement are such as to lend to the trap

K.—BOTANY 193

a rather horrific appearance. Above the entrance the massive wall
protrudes as an overhang, and from the under side of this the door rises
abruptly and not, as in U. cornuta, as an extension of the wall; and we
have no reason for supposing that the overhang in U. capensis contributes
to the action of the door, as in U. cornuta, in raising the angular divergence
with the threshold, contributing to the thrust of the door edge. To
compensate for this the inner zone region of the threshold has an upward
slope, thus offering a resistant surface of sufficient angle to afford a
resting-place for the door edge, while in the door itself there is a set
transverse bend above the middle piece.

The door, viewed as a flat object, has a rounded upper region, which
is, as seen in the longitudinal sagittal section, relatively thin, with a much
thinner outer course of cells than inner in its upper half and the reverse
in its lower half. This is correlated with the set transverse flexure, the
effect of which is to tilt the lower half of the door (the middle piece) with
respect to the threshold, enlarging the angle of divergence. The lower
region is differentiated into a large middle piece, whose cell courses are
of nearly equal thickness, with thicker lateral regions having the same
structure as the upper hinge region, i.e. thin outer course and thick inner
course cells. As in U. cornuta, the lateral regions exert a thrust on the
middle piece. Other features peculiar to U. capensis are, first, a tuft
of rather large, clavate glands arising from the door upper region and,
second, arising from the middle point of the upper limit of the middle
piece, a single, curiously shaped, glandular trichome, which I have called
the kriss trichome, as well describing the shape of the terminal cell.
Its stalk (basal cell) is curved gracefully backward ; the mid-cell is short
and oblique, holding the terminal cell in a backward-reaching position
between the middle piece and the threshold. If this structure has any
function, we do not know what it is. The absence of cuticle from the
terminal cell suggests that, in common with the glandular trichomes,
mucilage is excreted, but this does not throw light on the peculiar form,
nor does it help us to know that in another species, U. puberula (New
World), the door and general structure are similar in every detail but the
absence of the kriss trichome, there being substituted therefor a pair of
large, sessile, globular gland (capital) cells. Another species (Old World),
U. Welwitschit, has, like U. capensis, a kriss cell, but it is more sharply
curved, scimitar fashion.

The actuation of the trap seems to be initiated by the contact of the prey
with the short trichomes on the upper convex portion of the door surface.
As in U. cornuta, the initial flexure thus caused is transmitted longi-
tudinally to the middle piece, which, flexing along its midline, releases
itself from the thrust of the lateral hinges and so the door opens before
the moving water column.

Almost identical in structure, as far as the entrance mechanism is
concerned, is a group of species, the members of which have an elaborate
guide complex; but here the radiating rows of glandular trichomes
arise from a funnel-form elaboration of the front of the trap, while the
upper sector of this funnel is drawn out into a long rostrum, as first
described by Goebel (1891). The species, as far as known to me, are

H

194 SECTIONAL ADDRESSES

U. albina, U. nivea, U. rosea and U. Warburgit, the last two having been
described in general terms by Goebel. Three other collections, sent
me by Mr. N. D. Simpson (his Nos. 9579, 9857, 9871) from Ceylon,
though possibly differing specifically or varietally, have the same general
structure. They are all Indian (with Ceylon) and found nowhere else,
so far as known. In all these the glandular armature of the door is as
in U. capensis, except for the absence of the kriss or other similarly placed
trichome. The mechanics of the door and threshold are doubtless the
same.

Another small group of species (only two, so far as known) of minute
plants with the habit of U. capensis harmonises with the above in regard
to the entrance structures. The one is a Tasmanian, U. Jateriflora,
briefly and inadequately described by Kamienski, the other a Ceylonese
species (Figs. 13, 14), collected by Mr. N. D. Simpson (9482) and sent
to me (my No. 131). It seems to be undescribed. My Jateriflora
material has two derivations : one lot transmitted by Dr. Merl, but col-
lected long ago by Rodway in Tasmania (my No. 85); the other, a well-
preserved lot from Mr. Allan McIntyre, of Hobart (my No. 157).

U. lateriflora has a very small trap (including the proboscis, 0-65 mm.
long—a large one) with a huge conical downward-turned proboscis and
with two short rows of glandular trichomes extending outward and
obliquely downward from the lower angles of the entrance, increasing
in size, the smallest at the entrance. They thus form two oblique shelves
leading to the entrance, which is blocked in front by the proboscis. The
capital cells of these trichomes are globose. ‘The door is quite like that
of cornuta, but the armature of sessile glands is aggregated into a patch
on the convex surface of the upper part. The articulation of the door
with the wall is, however, like that in U. capensis. The external glands
are sessile globose.

The Ceylon plant (Figs. 13, 14) has a trap which, at a casual glance,
is quite similar to the foregoing. It has, however, a second pair of rows
of protuberances on each side and above the level of the entrance opening,
but these are not glandular (Fig. 13). The basal cells of the other rows
of trichomes are double-celled. The proboscis is smaller and may
project straight forward or be more or less bent downward—in this
there is no constancy. The threshold is composed of fewer and rela-
tively larger cells, but is clearly zonate, the outer, middle and inner zone
being readily recognisable. The glands of the outer surface have elongated
capital cells.

On the interior surface of the trap there are single, bifid and quadrifid
absorbing trichomes, but these are very few in number and relatively
large. In U. Jateriflora there are fourteen bifids in five rows on the
inner flank of the threshold; six quadrifids above the inner entrance,
three on each side; and two to six quadrifids in the interior, making
about twenty-six in all.

THe Type U. c@RuLea (Figs. 9, 11, 12).

The mechanical principles prevailing in all the foregoing prevail also
in a number of species, of which U. caerulea may be taken as a type.

K.—BOTANY 195

Because of this, my raising U. caerulea to separate dignity has a
secondary purpose, namely, to point out that the general form of the
trap assimilates it to the trap of the type under which U. reniformis,
U. vulgaris, etc., may be subsumed. A mere examination of the form
of the trap would readily lead one to suppose that U. cerulea and U.
reniformis are alike. ‘The former has single and bifid absorbing trichomes,
the latter quadrifid.

The trap in U. cewrulea is rounded in lateral view, and the slightly
protruding curved overhang is provided with two rather long, curved
antennz. ‘The threshold is broad and its inner region is uptilted, in
some species in a marked degree. In sagittal section, the curvatures
of the threshold are singularly graceful. ‘The door, also as seen in sagittal
section, curves downward and backward, the edge resting on the middle
zone of the threshold, in front of the uptilted inner zone. The upper
outer surface of the door is beset with a good number of clavate trichomes,
somewhat longer above than below, and differing only slightly in form
from those of U. capensis, etc., and doubtless serving the same function—
probably contributing to the attraction of prey or facilitating the actuation
of the trap, which, without doubt, consists in causing an initial dent in
the upper region of the door, the pressure of water taking advantage of
the failure of resistance thus started. In structure, the upper part of
the door has a thin outer course and a thick inner course of cells, the same
structure extending round the sides as far as the door edge. This is
the outer hinge area. The middle piece is thicker and is of cell courses
of equal thickness, with thick outer walls. This is compressed downward
on the threshold by the lateral hinge areas, as in U. cornuta.

Plants with traps of this type seem to be confined to the Old World.
They range from very small delicate plants to rather large ones—e.g.
U. equiseticaulis Blatter and McCann has leaves up to 9 cm. long; U.
prehensilis has long twining scapes bearing its yellow flowers. They are
all ‘ terrestrial,’ the typical habitat being wet, often muddy, places, the
plants forming dense green mats. The leaves scarcely rise above the
surface ; when large they lie on the mud, the under surface of the leaves
bearing traps, often plugged full of the fine sediment and rendered
incapable of action.

Of the species fitting the type U. cwrulea, there are known to me
U. Gibbsie, U. albo-cerulea, U. affinis, U. uliginosa, U. bifida and U.
reticulata, several Ceylonese species only tentatively named (Simpson
9484, 9487, 9492, 9517, 9580, 9581, 9856, 9971, 9972) kindly sent
me by Mr. Simpson. I am further indebted to Mr. R. E. Holttum,
Mr. 'T. Ekambaram, and Mr. E, Blatter for Malayan and Indian collections.
The structure of the door is much as in U. cornuta, being as follows:
the upper half and lateral hinges are composed of a thin outer and
thicker inner course of cells, the whole effecting outward bending but
capable of inward swing ; and, surrounded by the lateral areas, is the
middle piece, appearing as the lower half of the door in sagittal section.
It is thicker and more rigid and is of cell courses of equal thickness and
with thick outer walls (cf. Figs. 6-8).

The pressures inherent in the door itself become apparent when a

196

SECTIONAL ADDRESSES

K —BOTANY 197

PLATE JI—REFERENCES.

Fic. 9. Sagittal section of U. cerulea.
Fic. 10. Sagittal section of U. globulariefolia.

Fic. 11. Sagittal optical section of an entire trap of U. cerulea showing
the posture of the door and the profile of the entire trap when in the
set condition (1), and after actuation (2). Inset: longitudinal view
(diagrammatic) to show the form of the trap as thus seen before (1)
and after actuation (2).

Fic. 12. The posture of the door with respect to the threshold in the
U. vulgaris type (above), and in the U. cornuta type (below). p.d.,
the plane of the door axis; p.t., the plane of the threshold axis.
(Compare Figs. 5 and 23 for a better idea of the proportions of the
threshold, narrow in the vulgaris type, broad in the cornuta type.)

Fics. 13 AND 14. An unnamed species from Ceylon, closely allied to

U. lateriflora. Fig. 13, the entire trap; Fig. 14, the same in sagittal
section.

198 SECTIONAL ADDRESSES

trap is completely relaxed. Then the door becomes quite convex, the
lower part of the door resting on the threshold for a long distance (Fig. rr).
In the set condition, the posture is reversed. The door, as viewed
laterally, becomes distinctly concave, and only a relatively narrow strip
along the door edge rests on the middle zone of the threshold, the edge
abutting on the raised-up inner zone. It will be seen that this exactly
parallels the case of U. cornuta. The profile of the trap as a whole shows
similar changes, from which it is seen (Fig. 11) that the overhang above
the entrance shares in the flexures which bring the door into the position
of efficiency in the set condition. These observations rest on a careful
examination of living material, using the same technique as in the case
of other species, photographing the living trap before and after actuation,
and thus obtaining profiles of the door and neighbouring parts.

As compared with U. vulgaris, U. ceerulea is not so easily actuated,
nor does it engulf air with the same readiness (Fig. 12). The entrance
is narrow and the water film does not enter so readily, so that the trap
may be exposed to air a long time before anything happens, if at all.
While I have seen traps with air in them, I have not succeeded in seeing
the spontaneous act.

Tue Type U. MONANTHOS.

The species of this type, which has never been seen elsewhere (volubzits,
Menziesii, dichotoma, monanthos, violacea and Hookeri are known to me),
are all Australasian. I am indebted to my genial correspondents, Mrs.
Eileen R. Johnson, Mr. Allan McIntyre and Mr. A. V. Giblin, for excellent
material.

In form, the trap is peculiar and very distinctive, either almost circular
in lateral view, or oval; but the distinction arises in the combination
of form with two pairs of wing-like appendages, one pair running from
the stalk to the lower angles of the entrance, the other on the shoulders
of the trap leading to the upper angles of the entrance. Overhanging
the entrance is a proboscis, downwardly curved over the front of the
entrance. Specific differences are to be found in the greater or less
amount of laciniation of the wings, etc.

The approach to the entrance has, below it, a large patch of globose
glandular trichomes, to act presumably as a lure. The entrance opening
is circular, or nearly so, and is guarded by a thick, circular velum, some-
what less ample above, arising from sessile trichomes lining the inner
surface of the wall of the approach to the threshold proper. This circular
velum is altogether peculiar to this group of species. The upper part of
the door is so placed that it rests in contact with the circular velum,? its
patch of low glands being exposed at the opening. The threshold is
very deep and bends downward toward its inner border ; there is here no
upturned surface to resist the thrust of the door edge. Indeed, the inner
end of the door bends down over the ridge of the threshold. From inner
angle to inner angle of the threshold the door, therefore, has a sharp
permanent downward bend, the effect of which is to increase resistance

5 I have, of course, not seen living material. It would take adequate study
to be certain of the exact door posture in the living trap.

K.—BOTANY 199

to longitudinal flexure of the door upon actuation. The upper part of
the door is wider than the lower part, forming a large convex surface,
easily flexed by contact through the circular port formed by the velum.
When this has been caused by the movement of some animal, the pressure
of water continues the flexure till it reaches the transverse bend near the
door edge. The sudden reversal of this bend results, in my opinion, in
the snap action, which has been observed, following my suggestions, by
Mrs. Johnson. She assures me that such snap action occurs, the changes
in contour of the lateral walls and the engulfing of air having been observed
by her, as also by Mr. McIntyre.

The door is peculiar in shape in having an extensive upper region,
wider than in the lower region, and thin. Near its attachment to the wall
of the trap, and where the maximum bending occurs when the door
opens, the outer course of cells is thin. Elsewhere the two courses are
approximately equal in thickness, except in the lateral reaches of the
lower region, where these areas exert downward thrust on the middle
piece. ‘The transverse curvature of the door in this region is not as sharp
as in such forms as U. capensis, but this is compensated for by the trans-
verse flexure of the door in bending down over the back part of the
threshold. In order to understand how important this flexure is we must
appreciate that it is not a straight flexure, as a bend in a piece of flat paper,
but a curved one, like the bend between the rim and crown of a bowler
hat. The overcoming of the thrusts afforded by this arrangement is the
peculiar feature of the action of this type of door. The effectiveness of
the watertightness in view of the extensive outwardly bowed upper region
of the door is procured by the extensive velum, supplemented by the
adjunctive or secondary velum arising from the trichomes on all sides of
the entrance in front of the threshold. The whole arrangement must be
of a high degree of efficiency, and the in-pull of water great, as the sides of
the trap are thicker than elsewhere, whereas in the other types the walls
are of equal thickness on the flanks, with the exception of Polypompholyx,
as we shall shortly see.

The actuation of this trap appears to be of the same manner as the
previous forms described—namely, pressure on a thinner area of the
door, occupied by a group of sessile glands on the surface and so placed
as to fall nicely within the hole formed by the ring-shaped velum. This
rather definitely points to the function of the sessile trichomes on the
upper part of the door, no less for the previous groups of species described
than for this—namely, as an area of contact by entering prey, possibly
attracted thereto.

POLYPOMPHOLYX.

In spite of the presence of most of the usual structural stigmata (for
I failed to find the velum), in my previous publication (1932) I leaned
toward the view that the door of this plant (of which two species, much
alike, exist) acts as a simple valve, in the sense meant by Darwin for
Utricularia. At my request Mrs. Johnson was kind enough to make
careful observation of the living traps. Her notes, accompanied by
sketches, leave no room for doubt that snap action occurs. I have made

200 SECTIONAL ADDRESSES

another attempt to determine the presence or absence of a velum with
material which had been preserved in weak formalin, in which the delicate
membranes of the velum are not at all well preserved, as I have noticed
repeatedly in other species, but I have found sufficient indications of the
velum in the form of very mucilaginous and swollen, as it were semi-
hydrolysed, remains of the membranes. It is not clear whether the
velum arises solely from the threshold or also from the glandular trichomes
just beyond the front of the threshold, and until I obtain well-preserved
material (in alcohol) the point cannot be settled.

The threshold is approached, not from in front, but from the sides, as
the projecting rostrum, the end of it resting on the enlarged stalk, obstructs
direct approach. There is thus formed, as I have explained elsewhere,
a sort of atrium, lined with great numbers of long, whip-like, glandular
trichomes, the same sort occurring on the door itself, which forms the
roof of the atrium. The capital cell of these trichomes is very long and
slender, each secreting at its tip a droplet of mucilage. It may be that
in the living condition these trichomes fill the atrium and act as a con-
tributory velum. The actual entrance over the threshold is relatively very
small and hedged about inside with up-jutting trichomes arising from the
curved tissue shelf, in the front part of which is the pavement epithelium.
This occupies a narrow strip on both sides of an angular ridge forming
the front edge of the shelf. This ridge continues laterally to a point
about half-way up the slope of the threshold, where the threshold pave-
ment is very narrow. From this point it widens, fanwise, to the articula-
tion of the door with the threshold, affording a wider out-sloping surface
of application of the door thereto. The outer and inner zones are broader
at the middle and narrower at the sides of the threshold.

The door, as seen en face, differs a good deal from the previous species
examined, in that it is nearly circular in shape, save for the segment cut
off by the door edge, making it rather more than semicircular. The upper
region is very thick, the inner course of cells being very deep and richly
supplied with props, and capable of much compression. The middle
piece gradually thins and is curved, and just above it is a weak, thinner
region, marked by the presence of a number of small, sessile glands.
This region lies between the upper region of the door, which is covered
with a dense mass of the aforesaid whip-shaped, glandular trichomes,
and a narrow strip above the door edge, which engages the threshold.
The manner of this recalls the condition which is described above for the
monanthos type—that is, the lower edge of the door is applied to a ridge
in the threshold, over which it is bent; but the dimensions of the parts
are different and the condition is not so striking. ‘The lateral reaches of
the door are applied to the fan-shaped, outwardly sloping surfaces of the
ends of the threshold.

The actuation of this trap must be regarded (in the absence of actual
observation) as being in the same manner as that of U. dichotoma, etc.
The middle piece is held tightly against the ridge in the middle reach of
the threshold by the thick lateral portions of the door, which exert
a strong downward thrust. As a matter of observation, the lateral por-
tions of the door are thick, in this being commensurate with its thick

K.—BOTANY 20t

dimensions, as seen in the sagittal section. The very great thickness of
the hinge region of the door gives the impression of the need of an adequate
and unusually large amount of available energy for actuation, and in this
connection we recall that the trap is triangular in form (regarded trans-
versely), and that the walls of four courses of cells are very thick. The
roofing wall, as well as the lateral walls, were observed by Mrs. Johnson
to be concave in the set condition of the trap. It may be argued that,
roughly speaking, there is available rather more than 33 per cent. more
energy than in a trap with only side walls. The trap is certainly a much
more stalwart structure than usual, and can be compared in this only with
the type of trap represented by U. globulariafolia.

Tue Type U. GLOBULARIZFOLIA (Fig. 10).

With this are several species having traps very much alike—namely,
U. amethystina, U. tridentata, U. modesta, and U. Roraimense, and,
according to Merl’s (1915) notes, U. bicolor, all New World, neotropical
probably.

The general form of this type of trap was described by Merl. It is
a thick-walled and, in lateral view, well-rounded structure, with the stalk
and entrance approximated. From the stalk leading up to the lower lip
of the entrance there is a narrow but deep ramp, clothed along its ridge
with long, backwardly curved, glandular trichomes in several rows. The
overhang, which is massive, is forked, forming two strong antennz, also
clothed with the same kind of trichomes in rows. All these rows of
trichomes converge at the door, against which the innermost trichomes
lie, forming a thick circle and, it would seem, an accessory velum at the
door surface (somewhat as in U. monanthos), and a long, funnel-formed
guide to lead prey to the middle region of the door, which is there clothed
with sessile trichomes.

The door is relatively small and nearly semicircular in outline, and is
of nearly equal thickness from insertion to edge, though the inner course
of cells is thicker toward the insertion. In some species, along the inner
aspect of the free edge, runs a strip of beading in the form of three or four
sharp ridges, which may serve to engage the edge of the door against the
threshold. Its entire absence, however, in some species, throws doubt
on such an interpretation. The angular divergence of the door and
threshold is here much greater than in preceding forms, and the thrust of
the former on the latter is very direct, the water pressure on the door
having the effect of increasing the angular divergence and thus procuring
a still more up-and-down thrust.

The threshold is rather narrow and is supported on a deeply reaching
shelf of peculiar and graceful form. The outer and middle zones are
flat, the inner having a velum. The middle zone is very compact. The
inner zone slopes away, facing inwardly. Its capital cells become more
rounded and more loosely packed and always bear remains of enlarged
cuticles, these cells having been subject to the general inflation of the
cuticular investment giving rise to the velum. Whether the peculiar form
of the tissue shelf which bears the threshold plays any part in the adjust-

H2

202 SECTIONAL ADDRESSES

ments which take place during the setting of the trap after actuation is
a question which may well be asked, but there is no sure answer ; yet it
may be recalled that Brocher (1911) entertained some such idea in regard
to U. vulgaris, but I think without objective justification. I think the
bolster of tissue in such forms as U. vulgaris is capable of resisting changes
of shape, but if this is the case it does not preclude the possibility from
other forms.

The histology of the door deserves remark. The inner course cells of
the middle piece, or rather the region of the middle piece and the area
above it, where the sessile glands on the outer face of the door are situated,
are of long cells, running longitudinally to the edge of the door, as far
as the beading. These cells are, moreover, very richly provided with
folds and props, indicating great flexibility in precisely that region, the
middle piece, where in other forms there is a tendency in the other
direction, namely, of rigidity. This condition is to be met with also in
the cells of the central hinge in U. vulgaris and similar forms, a point
where great flexibility in various directions is present (Lloyd, 1932).
In the globulariefolia type, the degree of complexity arising from folds or
corrugations in all directions is very great indeed. The effectiveness of
the application of the door edge on the threshold lies in part in the con-
siderable curvature of the door edge, so that the line of contact is itself
nearly the arc of a circle.

With this type we conclude our remarks concerning these foregoing
types which may be collectively subsumed under one generalisation—
namely, that they are all forms in which the actuation of the trap is pro-
cured by the inbending of a more flexible area of the door, thus upsetting
the unstable equilibrium set up. by the physiological activity of the walls
in expelling water, a state of reduced water pressure within being preserved
by the somehow engaged door rendered watertight by a velum.

In this type, however, we have departed from those in which there is
a small angle to one in which that angle is quite wide, and the application
of the door to the threshold is along its edge. In this, the trap is like that
of U. vulgaris, but is otherwise quite of its own kind. Not in this type
is the pose of the door surface against the threshold insured by the down-
thrust of its lateral regions. This thrust is now oblique with relation to
the threshold, pushing the door edge forward to engage the front of the
middle zone. The rigidity of the door in its efficient closed position is
assured by the slope of the sides of the threshold, which faces outward ;
thus the threshold is a short half-funnel into which the door (being
longer along its edge than the threshold) is cramped, so that the greater
the water pressure the tighter the contact of the lateral regions of the door
against the resisting threshold.

We pass on to consider another series of types, contrasting with the
foregoing by having a special tripping mechanism, consisting of long
bristles or glandular hairs protruding from some point of the door
surface and correlated with the structure of the door itself. We shall
consider first a curious Asiatic species which appears to stand in a position
intermediate between those which we have already considered and those
which are distinctly typical, e.g. U. vulgaris.

K.—BOTANY 203

THE Type U. orBICULATA (Figs. 15, 16, 18).

If a bizarre structure warrants using this species as a type, the choice is
justified. The plant was first described from the point of view of the
morphologist by Goebel in 1891. I have been able to include Goebel’s
Ceylon collection in my studies and I have regarded this material as the
typical U. orbiculata Wall. It is curious that no other collections sent to
me from India and Ceylon have yielded species with the characteristic
tubers of the Goebel material, which he described. All the other
species sent me are very closely akin to the one before us and, at all
events, the traps are alike. The trap is pear-shaped in lateral view, with
the stalk affixed just in front of the middle point of the ventral side.
Above the oblique entrance there is a short rostrum, giving rise to two
thick downwardly and outwardly curved antennz, bearing numerous
uniseriate branches or cilia, each ending in a rather large, globose,
glandular capital cell. The aspect of this apparatus distinguishes this
species and its related ones indisputably. ‘The trap is small, scarcely
ever longer than 1 mm., exclusive of the antennz.

When the sagittal section of the entrance is examined, it resembles
closely that of U. capensis, but on study certain important differences
appear. The threshold, as in U. cerulea, is sharply uptilted near its
inner border, and has an unusually deep sulcus running transversely ; in
this the door edge rests along the edge of the middle piece, which is narrow.
The door edges along the lateral reaches slope up on either side to the
inner angles of the threshold. ‘There is a velum supplied by the cells of
the outer zone of the threshold, this being the primary velum, homologous
with that found in other types. In front of the threshold the forecourt
leading thereto is lined, as in U. capensis, with a clothing of stalked
trichomes, graded in length, the shorter the nearer the threshold, in such
fashion as to continue the general surface of the latter, thus forming
a narrow channel leading from the outside to the threshold. These
trichomes produce long, expanded cuticles which form a secondary velum,
supplementing the primary (Fig. 15). ‘The membranes are voluminous
and entirely fill the space fronting the door as far as its middle point.
We have seen that a secondary velum is thus produced in the U. monanthus
type, except that in U. orbiculata there is no secondary velum above the
entrance, but merely for the stretch of the three-quarters cylindrical
forecourt. Only in U. monanthos, etc., the trichomes supplying the
secondary velum are scarcely distinguishable from those of the threshold
proper.

But it is the door which furnishes the bizarre feature. In general
proportions it resembles that of U. cerulea ; it is not long and narrow,
hor is it semicircular, but something between these extremes (Fig. 18).
As seen in the sagittal section, its posture is oblique with reference to
the threshold, and correspondingly the lateral hinge regions are extensive
and well developed, and exert a downward thrust which applies the
middle piece tightly to the middle zone of the threshold. The middle
piece is laterally not extensive and is composed of smaller cells than those
of the hinge regions on either side ; nor is it sharply differentiated from

204 SECTIONAL ADDRESSES

Fic.
Fic.
Fic.

Fic.

K.—BOTANY 205

PLATE IIJ—REFERENCES.

15. U. aff. orbiculata. Sagittal section of the entrance structures.
16. The same. View looking into the mouth of the trap.

17. Sagittal section of U. Kirkit.

18. U. aff. orbiculata, The door en face. u.h., upper, and Lh.,

lateral hinge ; m.p., middle piece.

Fic.

19. Transverse section through a, b, c and d, Fig. 17.

Fic. 20. Sagittal section of entrance of U. capensis.

206 SECTIONAL ADDRESSES

the tissues above, as far as nearly the mid-point of the door. This whole
stretch is rather massive, however, up as far as a middle region which
forms a small oval or rounded area occupying a space just above the mid-
point, and which is slightly convex, especially on the inner surface. ‘This
spot bears a group of, for the most part, short, clavate trichomes, but
among them are three very peculiarly constructed trichomes. ‘These
are larger and stand out boldly, and are of two kinds. A single one is
in the form of a large club with a slightly oblique head, the capital cell.
This stands at the apex of an isosceles triangle, with the base above, and
at the angles formed by the sides and base stand the two other trichomes
which have the following structure. The basal cell is large and oblique
and set deeply in the door, so that the inner course of cells beneath is
very shallow. ‘The basal cell is capped by a large mid-cell which in
turn bears the capital cell, the cuticle of which in its definitive condition
is shaped like the cowl of a ship’s ventilator (hence called by me the cowl
trichome). Within the cowl is a rounded, thick cellulose wall, from one
side of which, beneath the upper limb of the cowl, extends a long, tapering
mass of jelly-like material, which is so transparent that it is difficult to
see. In order to photograph it I have stained it with ruthenium red.
Its inner end is cupped, indicating, by its interior surface, where it was
applied to the rounded cell wall remaining within the cowl. The jelly-
like mass, except when torn or otherwise damaged, has always a tapering,
horn-like form, curved much as a cow’s horn, and it stands out in front
of the entrance, pointing forward and downward.® If one faces the
entrance, looking into it, one sees the two gelatinous horns pointing
forward, and behind them the single club-shaped trichome, the whole
blocking the space left by the radiating trichomes which supply the
secondary velum (Fig. 16).

The region of the door above the trichomatous patch is usual hinge
tissue, the outer course being thin, reversing the relation of the courses in
the former, the structure of which indicates easy bending and can be
regarded as a sort of central hinge, such as we shall find in U. purpurea,
movement of which, on the contact of prey with the protruding three
trichomes described, can be procured sufficiently to upset the unstable
equilibrium of the system. Yet to what complexity has the apparatus in
this type been developed as compared with that in U. cornuta or even
U. ceerulea—and, it would seem, to no better end, no more efficiency
gained. It may help to regard the gelatinous horns as a lure, but we
cannot be sure that they are. Their soft and yielding nature does not
recommend them as a releasing mechanism to assist in actuating the
door ; only that we do not know even how yielding or otherwise they are
relatively to the movements of small prey. That not only small but
relatively large prey can be caught there is no doubt. I have seen a worm
twice as long as the trap itself lying coiled up inside, which had evidently
been caught at a gulp, since if they are caught by the pinching of the
door they usually stay in the position caught.

® My earlier description of the gelatinous horns (1932) is faulty.

K.—BOTANY 207

Tue Type U. vuccaris (Figs. 21-24).

Of the members of the genus, no species has been more under
examination than U. vulgaris. F. Cohn and Darwin were the leading
students of an earlier day (previous to 1882): it was then accepted that
the door was a simple, inwardly moveable valve, which the prey opened
easily by pushing against it. Its recurrence to its original position pre-
vented escape. We need not recount at length the views that the bladders
were floats, about which there was a lot of discussion finally closed by
Goebel (1889). It was not till Brocher (1910) made the important
observations that the bladders engulf air when a plant is raised from the
water, and was led to see that only when the trap is set, that is, when it
is in a condition of unstable equilibrium brought about by the exhaustion
of the water content, that it can do so, he appreciated that the trap is
watertight, but thought it merely plugged with mucilage, and that the
trap could act but once. Merl (1921) found that the action of entrapping
prey could be repeated, and determined the time necessary for the renewal
of that condition of unstable equilibrium, namely, 15 to 30 minutes—
observations which were made also by Czaja at nearly the same time.
It was not quite certain to Merl that the whole action (aside from the
exhaustion of the water from the interior of the trap) is purely mechanical,
but Czaja took this position definitely. Recently M. Kruck (1931) has
resuscitated the view, never very firmly held, that the action of the door is
a sequel of the transmission therethrough of the stimulus from the protuber-
ant, stiff,‘ irritable’ hairs : but this has nothing to support it. It isa curious
fact that none of the above-mentioned observers, nor any others, had
observed accurately the position of the door and its mode of contact with
the threshold, nor had anyone save Withycombe suspected the inadequacy
of Brocher’s idea of the way in which the watertightness of the door is
procured. For my part, I have shown that this is due to the presence of the
velum, that the contact of the door and threshold is a delicate adjustment
involving a tripping mechanism, and that the whole action is mechanical
and depends for its efficiency on the physical properties and adjustments
of the various parts. What these are may now be briefly summarised.

The door may be a continuation of the upper wall above the entrance
(Fig. 24), or it may arise from a projecting overhang, e.g. U. gibba
(Fig. 21). This produces no observable difference in the sensitivity of
the mechanism. In any event, the door is very delicately constructed, in
some species surprisingly thin, e.g. my No. 27 from Tropical Africa—
a U. gibba-like form. The shape is nearly that of a quarter-spherical
surface, one edge being attached to the walls of the trap, the other con-
stituting the free edge of the door, the convex surface being turned out-
wardly. A wide outer zone is flexed in front (that is to say, in the middle
third of the door), so that it is here concave and may be regarded as
a hinge, or, at all events, a region where the maximum bending can occur,
as when the door is opened. ‘The outer course of cells is very thin ; the
inner, thick and richly provided with transverse corrugations supported
on the ends of props (observed by Meierhofer, 1902) in the radial walls
(Lloyd, 1932). These cells are elongated radially in the door and, in

SECTIONAL ADDRESSES

208

209

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210 SECTIONAL ADDRESSES

the middle area thereof, fade into a somewhat different form of cell, in
which the corrugations are very prominent and regular and have given
rise to some misrepresentation. The corrugations are continuous from
cell to cell, and are very regularly concentric, giving the impression that
they are the walls of isodiametric cells. The centre thus indicated lies
just at a point where the door is at its thinnest, the central hinge, and
immediately below this thin spot issue four (sometimes abnormally more)
gracefully curved and pointed, stiff, three-celled trichomes. These are
the tripping hairs, and constitute mechanically a latch lever. At their
bases they are inserted close together in the upper part of a thickened mass
of tissue, with courses of cells of equal thickness, the middle piece. This
is slightly thinner along its middle line, that is, in the sagittal plane.
When the door is opened the middle piece folds inwardly along this line.
It acts as a mechanical unit with the latch lever, any movement of which
disturbs the edge of the door one way or another, in any case effecting its
release from a slightly outwardly turned surface of the threshold against
which it rests. On either side the middle piece merges quickly into the
outer hinge tissue.

The threshold, supported on a strong, upturned bolster of tissue, is
nearly circular in axial view, its arc length being shorter by about 10 per
cent. than the edge of the door (Lloyd, 1932). Since it is the door edge
which lies in contact with the threshold, its curve lies obliquely from its
point of attachment—the inner angle of the threshold—to a point in the
middle in front of the middle zone. This is raised slightly, affording
a resting-place for the door edge, resisting its inswing. At the sides the
front surface of the door rests on triangular areas of the threshold at each
end, these areas facing obliquely outwardly, so that the door under the
pressure of the outer water is tightly cramped into place. The outer
zone, wider at the sides than in the middle, carries a velum, consisting of
several rows of bladdery cuticles, to which is attached a loose membrane
arising from the cells of the middle zone and, to some extent, of the outer
zone. ‘The total threshold surface is shaped in correlation with the
emplacement of the door edge. Important is the angle of divergence
between the plane of the door and that of the threshold, which approaches
go degrees, whereas in the series previously considered (U. globulariefolia
excepted) that angle is a narrow one (Fig. 12). That is, (a) the position
of the surface of resistance for the emplacement of the door edge is in
front of the threshold when the angle of divergence is great and in the
back when that angle is small ; (6) in the latter case also the thrust of the
sides of the door is directly down on to the threshold, while, when the angle
of divergence is large, this thrust is directed obliquely forward, toward
the middle point of the door edge ; (c) the outer zone is wide, furnishing ©
a very wide and ample velum when the angle of divergence is small, or
narrow when large.

Actuation of the door occurs when the latch lever is touched in any
direction. Many trials have failed to convince me that the sensitivity of
the mechanism is greater for one direction than another. This can be
understood when one sees that an upward swing of the middle piece frees
it from the resisting threshold ridge, while a downward swing releases

K.—BOTANY 211

short lengths of the door edge on either side of the middle piece. In
either event the result is the same. The inward movement of the door
under the pressure of a column of water consists first in a longitudinal
flexure of the middle piece, which, as the reversal of door curvatures
advances, becomes curved inwardly. The flexures then move into the
lateral hinge areas together with the outer hinge, reversing the curvature
of the whole door. At the top of its swing the door edge is simply curved
in the arc of a circle (approximately), and the opening, as seen by the
observer stationed so that he may look into the trap along its axis, appears
circular, or nearly so, the threshold forming the lower arc, the door edge
the upper. I have satisfied myself that this is a correct record of the
movement, by taking motion pictures at high speed (160 frames per
second), which I shall have the pleasure of showing you. This seems to
be a simple enough matter, but, as it has been described otherwise, it is
not superfluous to have spent some effort in getting at the facts.

It is an interesting cell structure which allows such free movement,
which is at the same time completely reversible, so that the door springs
at once into its original position on the slacking of the water column. The
whole movement occupies 4; second. Furthermore, one may play with the
door with a not too sharp needle point or with a minute glassbead, moving
the door hither and yon, with no harmful effect. ‘There is an admirable
elasticity and flexibility of the tissues which fit its needs (Lloyd, 1932).

U. resupinata-—In describing the above I have erred to a purpose in
regarding all the species of the type U. vulgaris as submersed, freely
floating forms. There are some exceptions, all (?) American species.
U. resupinata will serve to illustrate a small group of species which are
terrestrial to the extent that they grow anchored in the bottom of ponds
where the water is shallow, or in similar situations (wet sand, etc.). In
U. resupinata the traps are dimorphic, larger ones growing on the terete
green leaves, and supplied with the vulgaris type of appendages (branched
antennz and lateral bristles), and small ones on the underground parts,
with appendages much reduced or absent. The middle piece of the
door is somewhat more massive than in vulgaris, but, aside from this, there
is no notable difference.

Another exceedingly curious plant is U. neottioides, belonging to
Kamienski’s segregate Avesicaria—a poor name for a plant with abundant
traps. The plant grows in running water, attached to more or less solid
substrata. The stolons in contact with hard surfaces grow and appear
after the fashion of Podostemon. From these arise free stolons with
linear, leaf-like branches, and near the axils occur the traps, which are
peculiar in having the entrance and stalk at opposite ends. One may
imagine this to be correlated with the movement of water, the trap being
stream-lined and the entrance where the back-swirl occurs. The structure
of the door and threshold is practically identical with that of U. gibba.
The antennz are very small and bear one or two short branches.” The

7 It would be gratifying to see good material of U. rigida, another species
growing in ‘ swift-running water’ and attached to the substrata. It is said to
be devoid of traps (Stapf, Flova of Tropical Africa). Later: the material has
been seen at Kew, but no traps were found.

212 SECTIONAL ADDRESSES |

actuation of the trap is accordingly by pressure on the bristles, not seen
by von Luetzelburg, who gave a good description of the plant as a whole.

U. RENIFORMIS.

This plant, well known in cultivation in our greenhouses, is a large,
orchid-like species from the American tropics. Its habitat is in the
wet moss and other compact epiphytic growth on stems of big grasses,
trees, etc. The stolons are thick and white, and bear, for an Utricu-
laria, very large reniform leaves, long flowering scapes with large,
purplish flowers, and a lot of very minute traps, smaller than the traps of
minute species, e.g. U. gibba. With this as typical are associated an array
of species, severa of which are similarly large or, at any rate, of impres-
sive size, such as U. longifolia, U. montana, U. Lundu, U. Endresu,
U. Gliickii, with some much smaller, even diminutive, species, of which
I have examined U. Dusenii, also seen in cultivation. They are all neo-
tropical, none of the type occurring in the Old World.

Except as to minutiz of structure, there is really very little to say in
comparison with the vulgaris type. Instead of the elaborately branching
antennz of the floating forms, in the terrestrial forms we are considering
the antennz are merely tapering horns, curved backwards or forwards,
from an overhang curved downwards over the entrance. In this respect
they ally themselves with gibba rather than with vulgaris. The stalk of
the trap, which in lateral view is well rounded, is usually closely approx-
imated to the entrance. The door is like that of U. vulgaris, but has
a more massive middle piece, more so in some species than in others.
Whether this difference indicates anything as to the delicacy of action or
not it is difficult to say. The traps of U. reniformis do not seem to engulf
air by any means as readily as those of the floating forms, and this may
advantage them, growing as they do merely in a very wet environment
and not submersed. In all cases actuation of the trap is achieved by
contact with four latch-lever bristles. I have already pointed out that in
form the trap of U. caerulea looks like that of the reniformis type, the differ-
ence being revealed in the absence of the door bristles and in the possession
of bifid trichomes instead, as in the American species, of quadrifids.

The threshold is so placed that the face of it is directed obliquely
outwardly, giving a very characteristic form to the bolster of tissue which
bears it. This position suggests that the trap is less easily actuated.

Three peculiar American and one African species can naturally be
mentioned in this connection, all sufficiently peculiar to deserve specific
examination. These are U. Lloydiit, U. nana, U. longiciliata, and U.
Kirku.

U. Lloydii Merl in MS. is a small plant of terrestrial habit, bearing
traps which resemble the globulariefolia type in the possession of a steep
ramp leading up to the entrance from the level of the stalk. The traps
are dimorphic, the two forms being, in certain details of structure,
very strikingly different. This dimorphism was first noticed by Merl, —
who drew my attention to it before I had examined the plant at all.
There can be no doubt of the dimorphism, which, in lack of conclusive

K.—BOTANY 213

evidence, would certainly obtrude itself. The two kinds of traps may be
found on the same stolon, close together.

In the one form the door resembles that of the reniformis type, save
that the middle piece is not so highly specialised. ‘There is, however,
but a single tripping bristle, straight, tapering and pointed. The basal
cell and the next cell to it form a special stiff, hinge-like base. ‘There are
a few short, clavate trichomes on the upper part of the door surface.
Over the general surface, both on the ramp and elsewhere, are scattered
globular, sessile trichomes. In the other form there is no tripping bristle
at all. The door carries numerous long clavate trichomes, and similar
still longer ones are found along the ridge of the ramp and under the
antennz, which here resemble those of the globulariefolia type. ‘Thus one
form of trap resembles reniformis and the other globulariefolia. Neither
Merl nor I have been able to correlate surely the distribution of the two
kinds of traps with position on the plant.

The second species of the American triad, U. nana, also resembles
reniformis, but is lacking antennz, and for this reason recalls cornuta.
We need not particularise further than merely to point out that, instead
of there being only one tripping bristle, as in one form of trap in
U. Lloydit, or four, as in reniformis, there are just two, standing side by
side. Their basal cells are somewhat enlarged, but show no striking
form such as noted in U. Lioydit. The structure of the door is, however,
precisely like that in U. Lloydii.

The third species, U. longiciliata, was examined by Merl, who observed
(1915) that there arises from the middle of the door, just above a massive
middle piece, a single glandular trichome, consisting of a slender, cylin-
drical basal cell, a short mid-cell, and an ovate capital cell. In view of
the massive character of the middle piece and the smallness of the
trichome, it is not easy to believe that the door is actuated by contact
with the trichome. The form of this trichome allies the trap with that of
our last type, U. purpurea. The likeness is perhaps rendered still more
striking by the fact that there is below the entrance a strong protuberance
bearing two widely spreading branches. A single protuberance is to be
seen in some of the allies of U. purpurea, though none in others. There is,
moreover, also a small rostrum above the entrance, somewhat as in an
Old World species described above (my No. 131, unnamed). Though
the general type of trap, aside from the curious appendages, allies
U. longiciliata with the vulgaris type, I am inclined to look upon it as
indicating an alliance with U. purpurea on account of the door trichome.

Finally, here we must place a most intriguing type which I collected
in Africa at the Victoria Falls, namely, U. Kirkit (Figs. 17, 19), identified
for me by Dr. Rendle ; and in this connection | recall the kindness of
Dr. Saunders, who supplied me with vials for my collection, having been the
more provident. U. Kirkii is a small, blue-flowered plant of terrestrial
habit, growing in ground where there was abundant seepage, with a trap
looking to be almost identical with that of U. capensis, but that the rows
of the more slender peristomal trichomes below the entrance are raised
somewhat on a collar, as in U. albina. Like capensis, too, it has a broad
threshold, the lateral thrust of the door being downwards.

214 SECTIONAL ADDRESSES

The upper moiety of the door, as seen in sagittal section, is uniform in
thickness, with the outer course of cells thin, but somewhat thinner
toward its lower limit, where it meets the middle piece. The character
of its tissues marks the upper region as hinge. This hinge extends
around the sides, forming much thicker lateral hinges. It is evidently
convex (at least in the relaxed position), and is clothed rather densely with
short, clavate trichomes. Just at the lower limit and close to the middle
point (here the door is thin) there are two stiff bristles arising out of the
outer course of cells. ‘These extend downward and forward. The
middle piece is quite thin along its sagittal line, just below the upper part
of the door, but on each side there is a large bulbous protuberance. The
two masses become thinner toward the door edge, to which they extend,
and appear to be stiffening agents, giving rigidity to the middle piece in
one direction without limiting its flexibility in the other. They are
derived entirely from the inner course of cells (Fig. 19, 5), merely by
enlargement without additional cell-divisions, in the fashion in which
the knob of the door of U. purpurea is formed (here from the outer cell
course) (Fig. 25). It is evident that the thin line of door tissue between
the bulbous masses is a longitudinal hinge.

The threshold is like that of U. orbiculata, with a deep transverse
depression which receives the middle piece edge. ‘The precise posture of
the door when the trap is in the set position still eludes us, as the material
could not be studied at the time of collection. It may be suspected that
the posture represented in the diagram, while probably correct for the
relaxed posture, should, for the set condition, be less convex, giving the
middle piece a larger angle of contact with the threshold. We may be
sure that this occurs, but precisely to what extent we do not know. In
the relaxed position the tripping bristles appear to lie in the trichomatous
clothing of the approach to the threshold. Less convexity of the door
would result in bringing them up into a position which would seem to
be a better one for their functioning. But in any event it seems fairly
certain that their position is such that the prey should press down on
them in approaching the door, their downward swing resulting in prying
up the upper part of the longitudinal hinge.

As in the case of U. orbiculata, U. Kirkit combines some of the mechanical
features of the cornuta type with those of vulgaris.

In view of the anatomical facts displayed, it would seem that actuation
of the trap takes place as follows : Pressure on the two juxtaposed trichomes,
inserted just above the two protuberances and so placed that impact will
usually be from above, will push the upper part of the middle piece
inwards along the middle thin line between the protuberances. This
initial flexure allows the water pressure to act in the usual manner. The
flexure travels upward along the middle of the upper region, where the
door is relatively thin, and backward to the door edge.

THE Type U. PURPUREA (Figs. 25, 26).
We have come to the last type to be considered, wholly American and
chiefly confined to the tropics, or at least to South America. North
America has the one species of which I have been able to study living

K.—BOTANY 215

material, found growing in the vicinity of Montreal. It is well adapted
to motion picture photography, and I show you some results.

Irrespective of species, the plant body consists of a main axis with
verticillate lateral axes, each member of which normally bears a terminal
trap. In some species the trap is wholly devoid of appendages ; in others
a proboscis-like upturning extension of the lower lip of the entrance is
to be found, e.g. U. elephas Luetz. The walls are thin and bear three
kinds of trichomes on the outer surface (Lloyd, 1933), one of which secretes
a fatty oil. The interior surface bears numerous quadrifids and a dense
row of bifids on the inner flank of the threshold bolster.

From our present point of view the point of interest is the form and
functioning of the door and threshold. These are, in structural detail,
very different from the foregoing. The most readily observable differ-
ence is the presence of a radiating group of tripping trichomes, arising
from a knob-like protuberance placed a trifle above the middle point of
the door at the upper limit of the middle piece, which is here very large
but fundamentally like that of vulgaris. The trichomes are of two kinds
in U. purpurea, of only one kind in U. elephas, U. cucullata, etc. Each
trichome consists of a long, tapering, terminally expanded cell bearing
a short, disc-shaped mid-cell, this bearing a spherical capitai cell with
a much enlarged cuticle ; or, in other species, the end cell may be fusiform
(Goebel, 1891). At the periphery of the tubercle the end cell is much
smaller, as is the expanded outer end of the stalk cell. This difference
has probably no significance. ‘These are the only trichomes on the door
in U. purpurea ; in cucullata there is in addition a patch of short, clavate
trichomes forming an oval group below the tubercle.

The door consists of two chief regions, the middle piece below the
tubercle and the sigmoid (the outer) hinge. The relative thickness of the
two courses of cells changes as we proceed from the outer edge to the
tubercle, so that the maximum flexure can occur where the outer cells
are the thinnest, namely, just above the cuticle. It is here that the door
chiefly bends on being opened. The lateral region is similar in structure
to the outer hinge. The middle piece is massive, the cells being of equal
thickness. The edge of the door is beaded with a three-quarters bead of
some thickness, the bead being turned outward. When the trap is set this
bead rests along the middle zone of the threshold, the velum resting against
the door edge, over the beading.

The threshold is narrow in the middle, widening fanwise toward the
sides, where the door is attached to it. In its narrower middle part the
outer zone bears an ample velum, consisting chiefly of the ballooned
cuticles of the component cells, the middle zone cells contributing little,
contrary to the case of vulgaris. ‘The middle zone is narrow, of small and
compact cells, and is slightly dished to receive the door edge. The outer
zone is unique in having the cuticles enlarged and filled with a stiff
mucilage (a hydrolysed cellulose probably), forming a resisting ridge
against which the door rests when the trap is set. The emplacement of
the door otherwise is as in vulgaris, the lateral reaches lying against the
broader lateral reaches of the threshold, where a broader zone of velum
cells occurs.

216 SECTIONAL ADDRESSES

Actuation of the trap can be caused by touching the glandular door-
trichomes, when the trap is exhausted of water; in these species,
owing to the thinness of the walls, it proceeds till the two walls are in close
contact with each other. This is well shown if a trap which has swal-
lowed a bubble of air is allowed to reset itself—a process which occupies
about two hours in this species, four to eight times as long as in vulgaris.
During this period the bubble changes shape in adapting itself to the
changing contours of the interior, and this is well shown in the motion
pictures. In whatever direction the trichomes are touched—the traps
are not all equally (mechanically) sensitive—the actuation takes place.
The explanation lies in the rotatory movement of the tubercle, and it is
so poised that in whichever way it is moved, up or down, the effect is to
raise the door edge a very slight amount, but sufficiently to upset the
equilibrium.

SUMMARY.

The foregoing account is based on the study of about 75 species of
Utricularia (including Biovularia and Polypompholyx).

The bladders (called here the traps) appear in a great variety of form.
The types selected to represent these forms illustrate the whole range of
variety, so far as known.

The study of living material of a number of species shows that certain
properties of the trap heretofore known to us from the study of chiefly
U. vulgaris are possessed by all. These are, briefly, a watertight door,
snap action on actuation accompanied by the inrush of a column of water
carrying with it the prey responsible for the actuation, the immediate
return of the door to its original position, and the subsequent exhaustion
of water from the lumen of the trap resulting in resetting it. ‘This reset-
ting consists in the close adjustment of the door at all points with the
threshold. The resulting posture of the door enables it to resist the even,
if considerable, pressure of outside water on it, the watertightness being
achieved by the sealing along the door edge by the velum. The effective-
ness of the door posture depends on the shape of the threshold, which is
always slightly funnel-shaped, the sides converging inwardly. In addition,
there is a more markedly outfacing ridge or surface against which the
middle reach of the door edge finds application, resisting the inswing of
the door.

The structure of the door is correlated with the function of its various
regions. It is composed of two courses of cells, the relative depths of which
vary according to the function. While the whole is remarkable in its
capacity for bending, we can recognise areas which can bend very freely
and through a large arc. This is hinge tissue, in which one course of
cells is thin, the other thick. The thick course always takes the maximum
compression. The upper part of the door and the regions around the
sides are hinge tissue. The capacity of compression and extension of the
deep cells depends on their bellows structure, their periclinal walls being
corrugated, each corrugation being supported by stiffening rods in the
anticlinal walls. The occurrence of props in the anticlinal walls is general
throughout the door tissues, so that the chief characteristic of hinge tissue

K.—BOTANY 217

is the corrugation of the periclinal walls (inner and outer). The middle
portion of the lower half (more or less) of the door has cell courses of
equal thickness very strongly supported by large, numerous rods. The
cells themselves become exceedingly small, especially as they approach
the door edge. The structure is such as to give some and equal pliability
in either direction, combined with considerable rigidity. This is the
part of the door which has to remain in a rigid condition to give the
door its footing on the threshold. The extent of these parts of the
door varies with the species and peculiarities of shape of the entrance
structures.

There are two general classes of trap :

(a) Those in which the threshold is broad (from back to front), the

outer zone bearing a broad velum, the middle zone being broad also, and
the inner zone narrow. The door in such cases is longer than broad, and
is so placed that when the trap is set the door edge is held in position by
the downthrust of the lateral hinge, contributing with longitudinal thrust
to the firm application of the door edge to a more or less upturned surface
near the inner limit of the threshold. The angle made by the plane of
the door with that of the threshold is a small one. The door is devoid
of special organs for actuation, unless sessile or short trichomes scattered
on the upper convex surface of the door may be so regarded. At all
events, actuation follows only on the application of sufficient pressure by
prey trying to enter to make an initial dent in the surface. ‘This allows
the outside water to exert its pressure in folding the door lengthwise.
The fold, travelling to the door edge, releases it from the downward
thrust of the sides, and the door is opened. The action is by no means
as vigorous as in the other kind presently described, nor as easily procured.
But procured it can be, and is vigorous enough to carry in the intruding
prey.
(6) Those in which the threshold is narrow. The outer zone is
relatively broad, and bears an ample velum ; the middle zone is narrow in
the middle, widening toward the sides relatively more than in the class (a),
and with an inner zone which is broader. The surface of application of
the door edge is at the front of the middle zone along the middle reach ;
along the lateral reaches the surface of the door is applied to broader,
fan-shaped extensions of the middle zone facing outwards, procuring the
funnel-like shape of the entrance, into which the door is cramped under
pressure of water. Here the velum also is broader and deeper. The
door stands at a large angle to the plane of the threshold. It is provided
with trichomes which constitute a latch lever for the actuation of the trap.
Contact therewith disturbs the door edge sufficiently to allow the pressure
of water against it to become effective in opening the trap and engulfing
the prey.

One cannot boast that all the species fit nicely into one or the other of
the above two categories. Beyond the general statement as made, each
kind of trap demands its own description. One is impressed by the
epigrammatic saying of the Italian botanist, Caruel, which was brought to
my attention by Goebel in conversation about this very question, to wit :
“La pianta cresce crascuna alla sua idiosyncrasia.’

218 SECTIONAL ADDRESSES

BIBLIOGRAPHY.

Brocuer, F.: ‘ Le probléme de l’utriculaire,’ Ann. biol. lacustre, 5, 33-46 (1911).

Coun, F.: ‘ Ueber die Function der Blasen von Aldvovanda und Utricularia,’
Beitr. Biol. Pflanzen, 1 (3), 71-92 (1875).

CROUAN FRERES: ‘ Observations sur un mode particulier de propagation des
Utricularia,’ Bull. soc. botan. France, 5, 27-29 (1858).

Czaja, A. T.: ‘ Die Fangvorrichtung der Utriculaviablase,’ Z. Botan., 14, 705—
729 (1922).

—— ‘Ein allseitig geschlossenes, selektivpermeables System,’ Ber. deut. botan.
Ges., 40, 381-385 (1922).

—— ‘ Physikalisch-chemische Eigenschaften der Membran der Utrviculariablase,’
Arch. ges. Physiol. (Pfluger’s), 206, 554-613 (1924).

Darwin, C.: Insectivorous Plants, New York, 1875.

GoEBEL, K.: Pflanzenbiologische Schilderungen (Marburg), Part I, 1889; Part II,
r8o1.

—— ‘ Morphologische und Biologische Studien. V. Utricularia.’ Ann. Jard. Bot.
Buit., 9, 41-119 (1891).

Krucx, M.: ‘ Physiologische und cytologische Studien tiber die Utricularia-
blasen,’ Botan. Archiv., 88, 257-309 (1931).

Lioyp, F. E.: ‘The mechanism of the water-tight door of the Utricularia
trap,’ Plant Physiol., 4, 87-102 (1929). ‘

— ‘ The range of structural and functional variation in the traps of Utricularia,’

Flova, 125, 260-276 (1931).

‘ The range of structural and functional variety in the traps of Utricularia

and Polypompholyx,’ Flora, 126, 303-328 (1932).

—-— ‘Is the door of Utricularia an irritable mechanism ?’ Canadian Journ.
Res., ‘7, 386-425 (1932).

—— ‘The structure and behaviour of Utviculavia purpurea,’ Canadian Journ.
Res., 8, 234-252 (1933).

—— ‘ The Carnivorous Plants. A Review with Contributions,’ Tvans. Roy. Soc.
Canada, Third Series, 27, App. A, 1-67, 16 pl. (1933).

LUETZELBURG, P. von: ‘ Beitrage zur Kenntnis der Utricularia,’ Flora, 100,
145-212 (1910).

MEIERHOFER, H.: ‘ Beitrage zur Anatomie und Entwickelungsgeschichte der
Utriculariablasen,’ Flora, 90, 84-113 (1902).

Mert, E. M.: ‘ Biologische Studien iiber die Utviculariablase,’ Flora, 115, 59-74

(1921).

— ‘ Beitrage zur Kenntnis der Utviculavien und Genliseen,’ Flora, 108, 127-
200 (1915).

Scuimper, A. F. W.: ‘ Notizen iiber insectenfressenden Pflanzen,’ Bot. Zeitschr.,

40, 225-234, 241-247 (1882).
Sxutcu, A. F.: ‘ The capture of prey by the bladderwort. A review of the
physiology of the bladder,’ New Phytologist, 27, 261-297 (1928).
WitHYcoMBE, C. L.: ‘ On the function of the bladders in Utricularia vulgaris,’
Journ, Linn. Soc. Bot., 46, 401-413 (1924). $

SECTION L.—EDUCATIONAL SCIENCE.

THE DEVELOPMENT OF THE
NATIONAL SYSTEM OF EDUCATION

ADDRESS BY
J. L. HOLLAND, B.A.
PRESIDENT OF THE SECTION.

I puRPOsE this morning to follow the sound example of those of my
_ predecessors who have confined their addresses for the most part to matters
of which they have had first hand experience. My own experience during
the last thirty years has been that of an administrator in a humble way,
and I have therefore chosen as my subject ‘ The Development of the
National System of Education.’ I hasten to assure you, however, that
I do not design to discuss more than one or two phases of that develop-
ment. The title is comprehensive enough to enable me to bring under it
all the things I wish to say, but an inclusive treatment of it would
require more time than is at your disposal to-day, and a more competent
exponent than I can claim to be.

It is vividly present to the mind of every educationist that he is
serving a society which is disturbed by great private and public anxieties.
The causes are world-wide. We see the foundations of social order and
well-being shaking in country after country and we wonder how long our
own land will be spared. Insuch times of unsettlement that man is hap-
piest who, with a small thing to do, sees itand does it, who takes short views
and lives a day at a time, like the caretaker of whom one read recently
dusting the benches in the Parliament House while revolution was being
made in the streets without. But the minds of thinking men are quickened
by the turmoil and must work, and if at times they are depressed by a sense
of helplessness, that is not the dominant note. It must needs be that
changes come. By taking thought with their fellows, men can, it may be,
help to determine the direction and extent of the changes. There pro-
bably never was a time when every department of social and economic
life was more vigorously canvassed than it is to-day. Large conventions,
which in normal circumstances men accept as the price of being allowed
to get on with their work, are the subject of ceaseless debate ; the quiet
corners which usually escape notice are ruthlessly being turned out, and
proposals for reform come from every quarter.

Education does not sue to be excused from the general re-valuation.
True that in one aspect it is a great institution with a membership of
thousands of men and women, concerned like all institutions with the
effects reform may have on the lives and fortunes of its members. True

220 SECTIONAL ADDRESSES

also that the need for re-construction has notoriously been made a pretext
for paying off private grudges against individuals and whole classes in
society. ‘Teachers—some teachers—are apprehensive of similar treat-
ment, and are naturally stirred to take preventive action. Yet an educa-
tional system does not consist alone of schools, however numerous and
well articulated one with the other, nor of teachers, however highly
qualified : it requires to be informed by an understanding on the part of
the community at large of the purpose of the schools and the aims of the
teachers. In the first Presidential Address of this Section, more than
thirty years ago now, Sir John Gorst defined the task of the British
Association as the ‘ inculcation of a scientific view of things in every
department of life.’

Education is such a department of life and it cannot function ade-
quately and healthily unless the nation applies to it that trained organised
common sense in which, as Huxley said, science consists. On this view
it is the increasing manifestation of public concern for education which

enables us to have an educational system at all, and if there are gaps, it is ,

because our public have not yet learned steadily to regard the whole, but
concentrate now on one part of the field and now on another like an
infantry company advancing by irregular rushes. Out of the inquisition
then to which education is being subjected, in common with other social
services, will assuredly come a summons to advance which mere in-
difference can never give.

But the educationist and the teacher should not adopt a passive
attitude toward the great debate, leaving it to go forward while he immerses
himself in professional duties. He owes it to the service for which he is
enrolled to think out his own position, to look before and after, so that
where he hears education attacked or misrepresented he may be ready to
explain and defend it. He will not be long in any company without
having the opportunity. Teachers are often criticised, whether justly
or not let them judge for themselves, for living wholly in an immature
world of their own as a caste apart, different from other men. Exaggerated
devotion of that kind in any sphere leads to unpopularity and loss of
influence. There is a time to put off the gown: men are flesh and blood
and apprehensive, and the teacher does right to meet them in the ways of
the world as a man and not as a schoolmaster. I recall some words of
Dr. Arnold’s, written at the time when he was actively engaged with the
establishment of the new London University and was writing his History
of Rome. ‘I hold,’ he wrote, ‘ with Algernon Sidney, that there are but
two things of vital importance—those which he calls Religion and Politics,
but which I would rather call our duties and affections towards God and
our duties and feelings towards men: science and literature are but a
poor make up for the want of these.’

Nor are his pupils likely to suffer by this suggested diffusion of the
teacher’s interest. I have seen it said that Thomas Arnold found that his
work with the Sixth at Rugby never went better than during that
strenuous time. Routine, like a strangling weed, is only too ready to
creep over any school with deadening effect, unless conscious efforts are
made to keep it under. But where the teacher himself is a link between

L.—EDUCATIONAL SCIENCE 221

the school and the world outside there is a freshness and rich actuality
about his teaching compared with which mere formal or traditional
routine is a feeble thing.

The development of an educational system in a democratic country
such as ours is a difficult and complicated enterprise. Consider by way
of contrast what is happening in certain other and ultra-modern states.
You are struck at once by the dominance of a single leading idea, to which
there is little that corresponds in our own society. In soviet Russia it
is being said that the one purpose of education is to create active workers
for the construction of a socialistic state. Of Germany much the same
can be said. The Nazi Minister of the Interior only the other day
declared that the time had come for abandoning liberal notions of
free individual development. The child must be reared for complete
absorption in and subservience to the corporative state. Whatever else
we may think of it, this concentration on a single aim undoubtedly
simplifies and speeds up the work of educational construction or re-
construction. But for us such an immense simplification is out of the
question. Our system of education has to meet, and if it may to adjust,
many differing demands: the demand of the parent, of the community,
of industry, of the state, demands which are not quite the same to-day
as they were yesterday, and will not be constant to-morrow. And all
these demands have to be reconciled with the demand that the child or
young person shall be assisted freely to develop his individual character
and ability. In the familiar words, ‘ adequate provision must be made
in order to secure that children and young persons shall not be debarred
from receiving the benefits of any form of education by which they are
capable of profiting.’ It is in this assertion of the rights of the individual
that the English system of education differs fundamentally from those of
our neighbours who are obsessed, as we think, with the notion of the
omnipotent state. And it is because of this principle that the educa-
tionist disappoints many would-be reformers in our own country who
wish to re-construct our education in the interest of early occupational
competence.

Not that the educationist and those who hold with him are blind to
social and economic necessities, but their concern is for the future
Education cannot dispose of present emergencies any more than a tree
can grow ripe fruit overnight. It takes a generation for its policies to
come into full bearing. ‘The men and women of to-day must deal with
their own difficulties. ‘The one thing of which we can be certain in these
rapidly-changing times is that to-morrow will be different. It is, there-
fore, no mere theory but the soundest possible practice that we should
develop the powers of youth that they may face emergencies, the nature
of which we cannot predict, with moral courage, adaptability, and re-
sourcefulness. But

If we draw a circle premature,

Heedless of far gain,

Greedy for quick returns of profit, sure,
Bad is our bargain.

222 SECTIONAL ADDRESSES

The birth of this Section at Glasgow in 1901 came just between the
passing of the two Acts which laid the foundation of our present educa-
tional system. The Board of Education Act of 1899, as its title implied,
set up a State Department under a Minister for the superintendence of
matters relating to education in England and Wales. It brought together
two previously existing departments, namely, the Education Department
in Whitehall, which since 1870 had been developing and systematising
elementary education, and the Science and Art Department in South
Kensington, which independently administered the Government grants
for schools of art and science and generally promoted what we now call
technical education. ‘The Act passed with little public notice, for very
few people outside the service saw it for the prelude that it was.

It was far otherwise with the Education Act of 1902, the second great
statutory landmark in the development of our educational system—Forster’s
Act of 1870 being the first and Mr. Fisher’s Act of 1918 the third and
latest. ‘The feature of this Act which attracted most attention, giving
rise to bitter public controversy at the time, was that which enabled the
voluntary schools, previously only state-aided, to receive assistance from
local rates. ‘The Church schools were put upon the rates, in return for
some concessions to public control. Although the old controversy has
died down, it flames up here and there and now and then as smouldering
fires will in disconcerting fashion. Many attempts have been made since
to settle the issue once for all; they have all broken down. I do not
propose to discuss the consequences of this dual system at any length,
for the subject was dealt with ably and faithfully in a recent Presidential
Address to this Section.

But three things perhaps I may suggest. Firstly, no settlement is
likely to prove permanent which does not give the local authority the right
to insist that the best qualified applicants shall be appointed to teach in
in the non-provided schools, and secondly does not allow of the employ-
ment of any teacher who holds the State certificate in any public element-
ary school. And thirdly, the present arrangement occasions serious waste
of teaching power and of public funds, which last, at any rate, is of great
moment in the present state of national finances. It is, I think, un-
fortunate that the recent Act, enabling the closing of schools which are
educationally unnecessary, is crippled by insistence that duality must be
maintained as a condition precedent.

But the fundamental change which the Act of 1902 made was the crea-
tion of local education authorities charged with responsibility for all
forms of education in their areas, namely, the councils in the adminis-
trative counties and the county borough councils. In the county boroughs
the Act replaced one popularly elected authority by another, though with
widely extended powers, for in almost all the county boroughs there had
been school boards responsible for a provision of elementary education
adequate for the needs of the area, so far as those were not met by the
voluntary schools. In the county areas, however, the position was very
different. For though the counties have a long administrative history,
the popularly elected County Council was a very young body and had
hardly got into its stride before these new duties were thrust upon. it.

L.—EDUCATIONAL SCIENCE 223

Moreover, and apart from certain powers which the councils exercised
under the Technical Instruction Acts, to which I shall refer again, the
only previously established education authorities in the county areas were
the school boards, which had been let in under Mr. Forster’s Act where
the voluntary schools were unable to supply sufficient elementary educa-
tion. These authorities were scattered irregularly in pockets, usually
small, over the county areas. Their suppression was locally unpopular.
Their members, who generally represented what there was of enlightened
educational opinion in their several localities, had to be conciliated, for
they were inclined to go into opposition to the new county authority, and
beyond that, the County Education Committee and its officers had a
sufficiently heavy task in bringing home to the rate-payers that they were
now members of a large education area, and in stimulating and focussing
appreciation of the educational needs of the area as a whole.

An administrative area for education purposes is not created merely
by tying together a number of smaller education authorities, or even by
clothing an authority existing for other purposes with educational powers.
For effective functioning a common outlook has to be achieved and the
will to organise and work together for common purposes must be evoked.
It is a slow process which cannot yet be said to be fully accomplished,
certainly not in many areas as regards education beyond the secondary
stage. ‘This weak position in which the counties were in contrast to the
county boroughs, was in part reponsible for a serious departure in the
Act from the principle that education is one and that educational adminis-
tration must be single. I refer, of course, to the Part III authorities
responsible for elementary education only. Of these there are about
one hundred and seventy boroughs and urban districts—islands for the
most part in the areas of the sixty-two English and Welsh counties, and
containing not quite a third of the total county populations—islands of
all sorts and sizes from little towns of 9,000 and 10,000 to the urban areas
round London with populations nearing the second hundred thousand.
Many of them are beyond doubt very efficient within their statutory
limitations. ‘They have a civic pride in their schools which is not com-
mon in the county areas. On the other hand, most of them are too small
to form satisfactory administrative units even for elementary education,
and generally they are a clog on the development of the national system.
The central authority cannot forget them in framing its regulations and
settling its administrative precedents, yet reasonable treatment for Little
Pedlington may be merely annoying when meted out to a large county or
county borough. They cut across county schemes of organisation, and

while it is only fair to admit that they desire as a whole to co-operate, they
complicate, and therefore add to the expense of administration. More-
over, officers and teachers tend to move to the larger areas, and in the
long run the quality of the local education service is injuriously affected.
_ But the principal reason for removing the anomaly of the Part III
authority is that with its existence is bound up the preservation of the
Statutory distinction between elementary and higher education. It was
inevitable that, on the transfer of organised elementary education from the
school boards to the new local authorities, the whole apparatus of parlia-
}

|

224 SECTIONAL ADDRESSES

mentary enactment and departmental regulation, including separate
rating, should go over into the new régime. There were no beginnings
even of organisation in higher education out of which a unified system
could be constructed. The distinction, however, always was unreal.
Higher education is by statute education other than elementary, which in
the absence of a definition of elementary education gets us nowhere.
There is no definition of elementary education in any statute, but an
elementary school is defined as a school in which the principal part of
the instruction is elementary, which recognises the possibility of some-
thing more than elementary instruction being given in it. At one time
indeed the old Science and Art Department impartially aided the teaching
of science in both elementary and secondary schools.

In actual practice, higher and elementary institutions have always
overlapped, both as regards the ages of the pupils attending them and
as regards the details of the curricula followed. The distinction is purely
administrative, serving no useful educational purpose, and the modern
development of the division between primary and post-primary has made
it not merely useless, but absurd. It is also a nuisance, for it involves
debatable apportionments of common expenditure, separate accounting,
and other duplicate arrangements. Economy will be promoted in more
than one direction by its abolition.

The tide of opinion is setting towards the effacement of the Part III
authorities—witness the recent Act which forbade the creation of any
more of them as the result of the re-arrangement of local areas under the
Local Government Act of 1929. There is already a clause in the Educa-

tion Act which allows them to surrender their powers to the county —

council. Need I say that the instances of such surrender are few. If
local authorities, educational and other, have a common characteristic,
it is the pertinacity with which they cling to the powers they possess.
‘What we have we hold’ is their motto. Some of the Part III’s should
be absorbed into the adjacent county area, the larger of them should be
vested with full powers. No authorities should be allowed to survive
which are unable to support a reasonable number and variety of schools at
least to the end of the secondary stage ; on which principle some county
and possibly some county borough authorities ought to lose their present
powers.

The relative positions of the central and the local authorities are very
different in the two spheres of elementary and higher education. The
Act of 1870 was extremely regulative. The powers, the duties, and the
procedure of the school boards were prescribed with great particularity,
and the control of the central authority was secured through its minutes,
the well-known Code of Regulations for Public Elementary Schools,
which, after confirmation by Parliament—an almost nominal proceeding—
become the conditions of the payment of parliamentary grant. And the
Code was even more detailed than the Statute. There were 130 articles,
many of them with sub-sections, in the first Code under the Act of 1902.
The school board and their successors were to enter the field of elementary
education, but there must be no walking on the grass. It reminds me of a
one-time open path which I used to take through beautiful country, but

L.—EDUCATIONAL SCIENCE 225

I go that way no more, for now galvanised netting is high on either hand
for a mile or so, and one arrives at the end in a state of exasperated longing
for a pair of wire cutters. Some of you may know that walk and the
educational institution which at vast expense has put such a slight on our
common ability to behave ourselves.

There are still stretches of the old statutory fencing in the Education
Act, although nominally it was all taken down in 1918. ‘The Code of
Regulations, however, is far less detailed than it used to be. The 130
articles with sub-sections have shrunk to a reasonable 27. For this
comparative freedom local authorities have to thank another predecessor
of mine in this Chair, Lord Eustace Percy. Lord Eustace claimed that
the Code, as revised in his time at the Board, gives the authorities a wider
field for the exercise of their discretion, and the claim can be freely allowed.
‘ The limit of useful State control is to be found at the point where it
ceases to be an expanding and stimulating force and tends to fetter or
sterilise.’ Those words are quoted from Sir Robert Morant, the archi-
tect—if any one man can be so styled—of our present educational system.
For fifty years from the time of Robert Lowe’s Code of 1862, elementary
education moved in fetters, and the marks of that servitude are still upon
it; only gradually is it recovering the vigour, the elasticity, and variety of
which a too restrictive control deprived it.

On the other hand, the local authority was given full power from the
beginning to supply or aid the supply of higher education as it thought fit
after considering the needs of its area and consulting the Board of Educa-
tion. In theory, the central authority is here a friendly adviser, and can
exercise no control so long as the local authority is prepared to finance its
own schemes entirely. ‘The friendly adviser, however, in this case is
usually ready to back the advice with offers of financial assistance, and
although at first in a number of instances authorities were willing to pay
_ the piper for a tune they preferred, there are not many higher institutions
left—I do not myself know of any—under local authorities, which the Board
does not aid. At the same time, this power the local authorities have of
resuming their independence is very real and colours all their relations
with the Board. I wish to avoid all suggestion of a reluctance on the part
of the Board to give the local authorities their due, or of serious differences
of opinion between them, for in fact consultation between the Board and
the authorities is frequent and close, and the differences which do occur
are in matters of detail rather than of principle. But the position is that
of two parties in a negotiation which either of them can break off, one
perhaps more easily than the other, and for which each of them desires a
successful conclusion.

The administration of the Exchequer grants under regulations framed
by the Board is the greatest factor in the relations of the central with the
local authorities. By most people these grants are regarded merely as
subventions in aid of local expenditure. They are that, but they are also
a powerful instrument for the furtherance of national policies and a precise
technique has been worked out for so using them. ‘There is not time to
develop this point, but an example will illustrate my meaning. I select
one which at the present time is agitating the county authorities—an

I

226 SECTIONAL ADDRESSES

example of misuse of the instrument. ‘'T'wo of the elements in the formula
under which the grants for purposes of elementary education are assessed
are the expenditure of the authority on teachers’ salaries, of which fifty
per cent. is met by grant and administrative expenses, of which the
Exchequer finds twenty per cent.

Reorganisation in county areas involves the provision of senior schools
at nodal points to which the older children of the surrounding district are
transported. ‘The process is attended by some saving in salaries, and
within certain limits the larger the school the more economically can it be
run. Not only so, the larger school can combine variety in the curriculum
with greater uniformity in the classification of the pupils, and in the end
should prove the better school. But a larger school means a wider
gathering ground and a heavier transport cost. Yet the Board appro-
priate half the saving in teachers’ salaries and leave the authority to bear
four-fifths of the heavy cost of transport. The effect of the grant regu-
lations is therefore to dissuade the authorities from plans which are
nationally economical and educationally desirable and to reinforce the
understandable preference of the countryside for the small and less
efficient school near at hand.

This method of giving grants in proportion to expenditure, and at rates
varying with the type of service aided, was brought into full operation in
education by Mr. Fisher’s Act of 1918. Obviously it is designed to
encourage expansion and to stimulate authorities to the more adequate
discharge of their duties. The argument that the Board bears part of
the cost can be very convincing. Though not simple in administration
it keeps pace with the growth of institutions, and through the provision
of an overriding minimum grant it recognises the importance of the local
organisation of schools. Notwithstanding its occasional misuse education
committees generally approve it, though perhaps some of them who are
chary of expansion and have no wish to be stimulated still hanker after
the old method of separate grants on a per capita basis for individual
institutions.

In the discussions which are raging round education and everything
else the method of the percentage grant is challenged on the ground that
it lends itself to extravagance and involves a meticulous interference with
the business of the authorities, objections which you will observe tend to
cancel out, and it is suggested that block grants assessed over an authority’s
expenditure during a standard year and fixed for a term of years, three,
five, or even seven, should be given instead. A block grant has none of
that flexibility which enables the percentage grant to be administered in
immediate conformity with Governmental policy, out of which no local
authority can expect to be allowed to contract itself. Nor can I see why
a central department or sub-department, with a policy of its own, should
be less disposed to encourage expenditure on the part of a local authority
under a block system grant, which defers the day of reckoning, than under
a system which automatically obliges it to share the cost. ‘The last report
of the Estimates Committee of the House of Commons comes to the
support of my contention, for the Committee therein publicly censures
the Board of Control for pressing local authorities to incur unnecessary

L.—EDUCATIONAL SCIENCE 227

expenditure and the Board is a department of the Ministry of Health,
where the block grant system obtains. Can you even imagine the Board
of Education nowadays risking any such rebuke ?

The task to which the new local authorities of 1902 were principally
called was the development and organisation of an adequate system of
secondary education. It was not a virgin field of which they took posses-
sion. ‘There were the endowed grammar schools, mostly of pre-Reforma-
tion foundation, individually independent, usually small and struggling
to make ends meet on very inadequate resources, some of them too dis-
heartened’ even to struggle—mere class alternatives to the ordinary
elementary school. ‘There were the schools of the companies, and of the
religious bodies, not quite so hard pressed, frequently with ends to serve
other than those which a public system must ensure. There were the
organised science schools—the categories are not mutually exclusive,
taking grants from the old Science and Art Department for the teaching
of specific subjects. ‘There were the centres for the training and education
of pupil teachers provided by the old School Boards, and there were the
private schools, good and bad, demanding to be taken into account.
Rightly indeed were the authorities enjoined to a careful consideration
of the needs of their area before attempting to bring order into this
chaos.

The story of the last thirty years in secondary education is absorbing for
those of us who lived in it. By strenuous and persistent effort the local
authorities have transformed the face of this department of national
education in a generation. It would be difficult to instance another
movement which achieved as much in as short a time and with so little of
that wasteful effervescence which characterises and sometimes mars great
outbursts of activity on a national scale. The story cannot be told now ;
I can do no more here than mark the line and pace of the development by
way of giving substance to the high claim I have made for the authorities.

The Board of Education lost no time in giving a lead. Local authori-
ties might be sceptical about the need for more secondary schools, but they
knew that at least the elementary schools must be staffed and that they
had to find the teachers. In 1903 new Regulations for the Instruction
and Training of Pupil Teachers were issued, in which it was indicated that
up to sixteen years of age the intending pupil teacher should be educated
in a secondary school. That meant that every boy or girl in the public
secondary schools of some areas would be needed for the teaching pro-
fession, and the question of increasing facilities was at once brought out
of the realm of theory.

A year later came the first Regulations for Secondary Schools, with a
definition of the term, very general in form, which has not yet been super-
seded. In the regulations the length of the course, the subjects of study,
even the minimum of time to be devoted to each subject, were all pre-
cisely stated. You will look in vain for this last requirement in the
regulations of to-day.

Of these two sets of regulations it can, I think, be said that, while in
form they were prescriptive, laying down conditions which must be
complied with if the Parliamentary grant was to be taken, the underlying

228 SECTIONAL ADDRESSES

intention was that they should be educative, in the one case formulating
for the first time a conception of the secondary school for the guidance of
authorities and teachers, in the other suggesting that the function of
the secondary school passes beyond the education of the single pupil to
the service of the community.

The only other set of regulations which require mention before we
consider the evidence of progress in the development of the secondary
school system, are the Regulations of 1907, in which the greater part of
the 1904 Regulations were included, but which were also further pre-
scriptive in two important respects. In the first place, no new schools
could be placed upon the grant list unless the representatives of elected
authorities formed the majority of the governing body. This was no
doubt intended to be the first step towards bringing all the schools aided
by Government grants under local popular control. So far, however, as
the local education authorities are concerned, the effect has not been
quite what appears to have been expected. ‘The representatives of the
popularly elected authorities keep up a useful contact between the aiding
authority and the aided school, but in my experience they count for very
little in the control which the aiding authority exercises, for they are
prone to put the interest of the school they serve first, and the authority
which appoints them receives but secondary consideration—a very
English and, on the whole, a healthy habit.

The other prescription of the 1907 regulations was of much more
consequence. Provision was to be made for the admission in the normal
case of 25 per cent. of the new pupils in any year from the public
elementary school, free of all school fees, but in every other respect on
the same footing as the fee-paying pupils. ‘The percentage stood as an
obligatory minimum until the new Special Place Regulations took effect
a month or so ago, but as a permissive figure it has been raised first to
40 per cent. and three years ago to 50 per cent.

I shall have something to say in a moment about the practical effect of
this regulation. The older among us will remember with what doubt
and hesitation it was received by the schools, for as Sir Robert Morant
expressed it in another of his early reports, the idea that elementary and
secondary schools represent not successive stages of education but
alternative kinds of education, meant for different social classes, was deeply
rooted. Those doubts vanished long ago: for the free place holder,
with few exceptions, readily took on the colour of his new school ; on the
whole he remained longer and stayed the course better than his fee-paying
fellow.

Until the Board and the authorities got down to work it had been
commonly assumed that their task would be in the main to bring the
existing unorganised and sporadically created secondary schools into an
efficient ‘system. The field appeared to be full of resources: what was
necessary, was in the words of the Bryce Commission, ‘ to correlate and
harmonise the forces and agencies already at work.’ The local authori-
ties very soon discovered gaps which needed filling, but what was not
generally foreseen was the tremendous drive for secondary education
which an awakened public opinion was about to motive. It was, for

L.—EDUCATIONAL SCIENCE 229

example, at first taken for granted that the new free places would be filled
without competition, indeed that they might even go unfilled for lack of
qualified applicants.

Let us see what has actually happened. In 1902 the number of schools
receiving State aid through the Board was under 300, and the number of
pupils taking an approved course under 32,000. ‘Three years later the
number of schools had risen to 600 and the pupils to 100,000. By rg11,
the last year of Sir Robert Morant’s term at the Board, the number of
grant-aided schools was 862 and the number of pupils had passed the
150,000 mark, if we include those in schools recognised as efficient but
not in receipt of grant.

The first year of the War came and found 205,000 children in the
schools. Down to that point the rising tide of numbers from 100,000
to 205,000 in ten years had encouraged authorities and administrators to
lay their plans with confidence. The flow was steady as well as strong ;
there was no falling off in demand to warn us that high water was nearly
reached. Was the War that warning? Had we come to the turn?
The answer soon came in a thrust for secondary education the like of
which this country had never seen before—is hardly likely to see again.
In the five years 1915 to 1920 the school numbers leaped with accelerating
speed by 113,000. ‘The thrust was not due, as the cynics suggested, to
easy money which enabled parents to pay school fees without feeling
them much, for in the next year, the year of the first economy wave, there
was a further leap of 32,000 and, save for a slight fall of less than
1,000 in 1924, the advance has continued until in 1932 there were
452,000 children, nearly 10°5 per 1,000 of our total population, receiving
secondary education in nearly 1,600 schools recognised as efficient, of
which the local authorities provide not quite half.

In the discussion of educational problems the layman probably gets
less help from the professional than, as paymaster, he is entitled to, not by
reason of undue reticence on the part of the professional, for we are a
talkative profession, but so much of the talk is about temporalities—pay
and pensions, status and prospects—and argument at the top of the
voice, in other words shouting one’s opponent down, is very fatiguing to
the listener. So the layman is driven to reason from his own youthful
experiences until he renews his contact with the schools through his
children. It is not surprising that the idea that the secondary school is
a Class school should still linger on. Is there anything in it? Rapid as
the growth of the schools has been, the free place holders have increased
even more rapidly. In the first year of the century there were about
5,500 children from public elementary schools attending the secondary
schools with the help of public funds. By 1906, the year before the
Free Place Regulations were made, there were 23,500. Within four years
of the passage of the Regulations there were over 49,000 free place
holders, and nearly a third of the total numbers in the schools were in
this category. At that time one out of every twenty-two elementary school
leavers in England went to a secondary school, and one out of every forty-
six received free education there. This process of social interfusion has
gone on without a check during the twenty years which have since elapsed,

230 SECTIONAL ADDRESSES

until last year the ex-elementary school child constituted 71 per cent. of
the English secondary school population and one in eight of elementary
school leavers made his or her way to the secondary school, every other
one with a free place. Such figures speak for themselves.

The story of secondary education hitherto, as we have seen, has been
one of uninterrupted expansion, but we are at the end of a generation and
there are indications that the national impulse behind the movement is
faltering, or perhaps making ready to find another channel. The
example of Wales, which even now has half as many more children in
proportion in its secondary schools as there are in the English schools,
stands as a warning to would-be prophets. Nevertheless, I doubt
whether many more schools of the secondary type will be founded, and
when the population ‘ bulge’ of the first two post-war years ceases to
have effect, the tide of numbers may be expected definitely to ebb. What
becomes, what has become, of these thousands of pupils, old and new?
The parallel extension of State control over, and interference with, the
lives and business of its citizens, the creation of new departments of
State, the great increase in the Civil Service, both central and local,
before the War accounted for many of them. They staff the teaching
profession. About sixteen per cent. of them go to the universities and
other institutions of higher education. Nearly two-fifths of them enter
the minor professions, or become clerks or go into business. Less than
fifteen per cent., rather more than a tenth of the whole, enter any kind of
industry. But the Civil Services have ceased to multiply, the teaching
profession is over-full, and the clerk is being replaced by machines of
every sort. The schools have been remarkably faithful throughout to
the conception of an education mainly literary, given through a balanced
curriculum of subjects mainly traditional. They have turned their
pupils almost exclusively in the direction of the academic, the professional,
the ‘ black-coated ’ occupations.

They are staffed from the academic group in the nation, and while it
has ensured high intellectual standards, that fact has enabled them to
tolerate the adaptation of their curriculum to the requirements of the
universities, until recently, with no sense of discomfort. They are academi-
cally controlled, not only in the advanced work which is the prelude to
university study for the small fraction of abler pupils, but also through
the certificate examinations which are the goal of the average. The
irruption of the free place holder has made little difference. ‘The social
ideals which underlie the schools’ practice are congenial, if anything too
congenial, to the poor child and his parents, ambitious that he shall
escape the drudgery which they have had to undergo. To them a
secondary education stands for advancement in life and the promise has
hitherto been realised.

But, as I have already pointed out, the prospects of advancement along
the customary lines are not so bright as they were. And another factor
needs to be reckoned with. For five-and-twenty years we have been
transferring picked boys and girls from the elementary schools to the
atmosphere of the secondary school. No wonder industry complains
that it is being robbed of its best recruits. The thoughtful employer

L.—EDUCATIONAL SCIENCE 231

agrees that his junior employees are better mannered, more self-respecting,
more amenable than those of pre-war days, but he does not find in them
the alertness, the resourcefulness, the desire for responsibility which a
sufficiently high proportion of their fathers displayed. Yet British
industry was probably never more in need of these qualities in its workers
than it is to-day.

Is it the business of the secondary school to meet that n>ed of industry ?
We have in our organisation proceeded on a theory which, nakedly
expressed, appears to be this. We will choose as well as we may, at about
the age of eleven, those children who can undergo a further five years of
full-time education with profit to the community and to themselves ;
they shall go to the secondary school ; the rest shall complete the compul-
sory elementary school course, and as for any education beyond that, it
shall be a voluntary part-time affair. On that theory the secondary
school is the common full-time school for adolescents. Can we say that
it is performing so comprehensive a service satisfactorily ? Not unless
we have the hardihood to maintain that full-time study, extending over the
period of adolescence, is only necessary for those who are to enter the
academic or professional classes or the public service, or the managerial
ranks in industry.

The schools are now finding themselves obliged to go further afield in
the search for suitable openings for their pupils, and the contacts they
are making in this way will in time react healthily upon their work. There
will be a broadening of the curriculum and maybe a less scholastic
approach to the more traditional subjects, especially when the grip of the
School Certificate examinations is relaxed. But anything in the nature
of a general turn over to the American high school type is to be depre-
cated, though one would like to see that alternative tried out in some
of the larger urban areas. The average secondary school is perhaps
fortunately lacking in the capacity for so great a change, and were the
change forced upon it by authority much that is honourably distinctive
would be lost. The high intellectual standards, on which are based not
merely the after competence of the professional classes, but the whole
leadership of the nation, would certainly be impaired. If, however, the
secondary school is to be left unaltered, save for developments from within,
to continue its present contribution to the national life, there will need to
be a reduction in the number of its pupils for at least two reasons.

We are admitting to the schools to-day children who are unequal to
the curriculum, and whose motive for attempting it is mainly social
ambition. As Sir Michael Sadler, another former President of this
Section, pointed out years ago, ‘it is possible to over-stimulate the
intellectual susceptibility of people of mediocre talent without adding
much to the sound stock of critical or practical judgment possessed by
the nation "—a form of waste, he went on to add, ‘ which we are distinctly
in danger of incurring ’ : a form of waste which we must confess is actually
being incurred. There are also children of another type in the secondary
schools, not necessarily inferior, who would be better suited by a less
academic and more practical curriculum. If these two groups are to be
turned back, the senior school, the modern school of the Hadow Report,

232 SECTIONAL ADDRESSES

will have to receive them for the present. About the part these modern
schools will play in English education, I hope to say something later. I
believe that they will very shortly attract in large measure that public
interest and support without which no type of school can grow freely in
our soil. Whether they will develop to any large extent courses for
industry and commerce, between say the ages of fifteen and eighteen, and
at the end of the general course, or whether these courses will be provided
in association with the technical schools as a kind of high school accom-
modated in technical institute buildings, as some of the old organised
science schools used to be, is a question for the future. I shall have to
point out presently that outside the secondary school there is very little
evidence of a demand for voluntary full-time education after the com-
pulsory age is reached, so that any development of such education towards
industry and commerce is bound to be gradual.

The inquirer approaching the subject of instruction for industry a
commerce cannot fail to be struck by the unsystematic—almost hap-
hazard—manner in which facilities appear to be disposed. It is only in
a few large and highly industrialised areas that one finds evidence of
constructive planning. Over a large part of the country the field is
occupied, though not covered, by a medley of institutions which often
have little relation one to another. The local school of art will probably
have no connection with the technical college : as likely as not the com-
mercial school or department will be quite independent of the industrial
departments of the college ; yet surely design has an important place in
industry, and what is commerce essentially but the exchange of the
products of industry? Again, the institutions themselves overlap to a
surprising extent. The official titles—technical school, technical college,
evening institute, and so on—afford no certain clue to the range and
standard of the instruction which is given in them.

This state of affairs is partly an inheritance from the early nineties of
last century, when the nation was aroused chiefly by the extraordinary
expansion of German trade, though the reports of Commissions and
Committees played their part in the awakening, to the need for more
and better commercial and technical training, and insisted that something
must be done. Under the national impetus technical instruction made
a fresh start. The municipalities and the counties were constituted
authorities by the Technical Instruction Act of 1889, with rating powers,
and were encouraged to get to work by Exchequer grants of nearly a
million pounds out of the Local Taxation (Customs and Excise) Account,
popularly known as the whiskey money, which were applied to this purpose
as an afterthought on the part of Parliament. Many of the municipalities
hastened to erect technical colleges, sometimes with no very precise ideas
about the character and extent of the instruction which they were going
to provide, enthusiasm usurping the place of a careful survey of existing
provision and of local needs.

The present confusing position is also in part a consequence of the
lines on which our educational system is organised. In most continental
countries technical instruction is a function of the State, and can be
planned on a national basis, or at least on the basis of large provinces

L.—EDUCATIONAL SCIENCE 233

whose inhabitants earn their livelihood in groups of connected industries.
But in this country the local education authorities are primarily responsible
for providing technical and other forms of instruction. There are a few
instances of localised industries whose boundaries coincide, or nearly so,
with local authority areas, and in those areas systematic planning has led
to satisfactory results. But industry as a rule has no respect for adminis-
trative boundaries. In consequence, the attempt to provide for the needs
of an area without reference to what neighbouring authorities are doing
usually involves some waste of resources, as well as a loss of efficiency,
particularly in the higher branches of instruction, by which only a select
few have the capacity to profit.

The situation calls for regional planning as the next step in the organisa-
tion of higher technical education. A beginning has been made by
groups of authorities, notably in the West Riding of Yorkshire and in
south Lancashire. In others progress is impeded by causes which I
have mentioned earlier in this address. It will not be easy gradually
to transform the local authority colleges into groups of co-ordinated
regional institutions. In some of the regions the Board of Education
will probably in the end have to give a strong official lead, instead of
depending, as they appear to do at present, upon the tactful and unofficial
ministrations of their inspectors and other servants.

The public interest displayed in the late eighties and nineties in the
new movement for technical instruction soon waned, for the early results
were disappointing. It had to be realised that technical education is not
self-sufficient, and cannot be successfully provided in the air, so to speak.
To be of value to the individual and to the community it must build on
a sound foundation of general education, and the successful completion
of the elementary school course, gravely deficient as it then was in the ele-
ment of science, was not sucha foundation. When this was understood,
the more thoughtful authorities began to give attention and to divert
some of their funds to the encouragement of the teaching of science and
other subjects which were more cultural than technical, and to the
transfer of the brighter elementary school scholars to the secondary
schools. Their activities in these directions paved the way to some
extent for the renascence of secondary education which I have already
discussed. It was not until the Great War was over that industry and
commerce began to ask on any considerable scale, and apart from isolated
instances, for the help of the schools in meeting the great changes brought
about by the application of new scientific discoveries to manufacturing
processes, and by the invasions of the machine in every department of
work. Industry and commerce are still busily discussing their require-
ments and endeavouring to formulate their demands upon the schools.
As regards industry, at least, the discussions can hardly yet be said to
have issued in any very clear conclusions. To borrow the language of
the theatre, what the educationist hears for the most part are ‘ confused
noises without.’ So long as industry is obliged to make its comments
* off stage ’ one can hardly expect anything else.

At this time of day it is unnecessary to stress the argument for a close
association between the industrialist and the educationist in the business

12

234 SECTIONAL ADDRESSES

of technical instruction. The need is admitted, though there is here and
there some lingering reluctance to set about devising methods for meeting
it. The method officially favoured is the advisory committee of manu-
facturers and employees. My own experience in connection with the
boot and shoe industry, however, leads me to advocate the direct repre-
sentation of the manufacturing interest on the management committee of
the institution or department. ‘There is the same time-lag in the manu-
‘facturer’s notion of what the schools are doing, the existence of which
in the mind of the general public I have already referred to. That time-
lag is quickly recovered where there is immediate contact with the institu-
tion itself. Not only does responsibility put a keener edge on service of
any kind, but advice is tendered more carefully and is generally more
practicable where that responsibility exists. The typical manufacturer
is accustomed to see to the carrying out of his own ideas ; he does not
take kindly to sitting in another room and framing recommendations
which a committee of management can ignore if it chooses, and is some-
times even disposed to regard as critical of its own action, or more usually
inaction. For there is a type of public man which has a great capacity for
deluding itself into the belief that popular election at once endows the
elected representative with knowledge adequate for the performance of
any public duty. Therefore let the manufacturers and employees have
their representation on the governing body of the technical school or
college, sharing in the give and take of its discussions, and in its responsi-
bility for the conduct of the school. The ultimate power of the purse
can easily be retained for the local authority by requiring an annual
estimate of expenditure classified under appropriate headings, which
when approved, must not be exceeded without going through the process
of the supplementary estimate.

Technical education in this country rests upon a voluntary basis. As I
have shown, it owes little to suggestion or consistent stimulation from
above. ‘The old term ‘ further education ’ would be a better description
of it, for the desire to ‘ get on’ and prosper is only part of the story.
Its chief motive force still is the craving of the individual for self-im-
provement. ‘The youth of ordinary elementary education, on whom it
dawns at about eighteen or nineteen years of age that his prospects of
economic advancement are small, bestirs himself to take advantage of it.
But there are numbers of students who want to develop particular studies
for their own sake, and again others who are not content to accept the
riddle of this unintelligible world, which every man becomes aware of
sooner or later, without making an effort to unravel it. ‘These conditions
explain why further education is so largely part-time education. They
also explain the great number of students to be found in the part-time
classes and institutions of all kinds. There are now about a million of
these students, of whom perhaps 50,000 are studying in their employers’
time, or partly so, during the day, and the rest are attending night schools
in their own time. Contrast that figure of a million with the number
of those who are engaged in pre-employment full-time vocational courses.
There are hardly more than 30,000 of them. If we examine the position
at the critical age of fifteen to sixteen years we find that there are no more

L._EDUCATIONAL SCIENCE 235

than 1,000 in full-time technical college courses and day technical classes,
and another 1,000 in full-time art courses, junior and senior, while there
are about 6,500 in junior technical schools. Finally, bring into the com-
parison the 63,500 adolescents of the same age in the secondary schools
and the remnant of 16,500 who are in the elementary schools. Even
when allowance is made for the fact that practically all the elementary
school remnant, and rather more than 7,000 of the secondary pupils aged
fifteen to sixteen, will eventually find their way into industry, the volume
of full-time pre-employment education of any kind for industry appears
painfully small.

The administrator or the teacher can do very little to make good the
deficiency. As Mr. Ramsbotham said the other day, ‘the course of
education is primarily governed by its social surroundings, by the thoughts
and actions, the needs and aspirations of adult society, and not by the
desires or ideals of educationists.’ The regional co-ordination of schools,
even the association of industrialists with their work, will not of them-
selves create a demand. What is lacking is a conviction on the part of
adult society that this form of instruction is a necessary element of our
national well being. ‘The nation must will to have it so, and as yet there
are few signs, apart from the vociferation of interested parties, that the
nation is not quite content to have it otherwise.

In our development of technical education on a part-time basis for those
already in employment we differ from continental countries, where in
the main technical instruction is conceived to be a full time pre-employ-
ment training. We differ from them also in another important respect.
While we recognise that there must be grades of employees, workmen,
charge hands, foremen, departmental managers and so on, neither the
educationist nor the typical industrialist agrees that you can conclusively
predict beforehand the grade in which the recruit will ultimately come to
rest. There are too many examples of men in high position who owe
their success to their character, their temperament, and their capacity,
rather than to any specialised training they have picked up on the way, for
us easily to accept the theory of the stratification of labour which lies behind
the graded schools of the Continent. It has been said that the process
of horizontal stratification into classes which will leave the individual
little opportunity for advancement has begun in this country, and that
the division of the nation’s youth into those who are and those who
are not to receive a secondary education is a new social phenomenon
whose consequences will be very far-reaching. But there are, and for a
long time to come there probably will be, many ways of obtaining a
secondary education without passing through the gate of the annual schools
examination.

It is repugnant to our national thought and practice that an insuperable
line should be drawn through Society at any age. So it comes about
that at every stage in our educational system we busy ourselves on behalf
of those who have not followed the orthodox routes, that they may have
an opportunity of making up what they have lost. We even play with
the idea that loss may be converted into gain, the competitors turning up
at the starting post for the next stage of the race with certain advantages

236 SECTIONAL ADDRESSES

derived from the very independence of the line they have taken to get
there. We may yet come to the drawing of lines and the erection of
fences dividing the people, but if we do the educationist, I fancy, will be
the last person whom the community will choose for the job.

I have already indicated that the number of young people who
voluntarily avail themselves of the evening institutes and other forms of
part-time education reaches a substantial total, but for every one who
does so there are at least three whose official education ceases when they
leave the elementary school at fourteen. It is often suggested that this
is a point at which the principle of compulsion should be introduced into
a hitherto voluntary system. The compulsory continuation school
clauses of the Fisher Act have been on the statute books for fifteen years.
They would secure that every employed young person received in-
struction in the employer’s time for the equivalent of one day a week
between the ages of fourteen and sixteen and later between sixteen and
eighteen. Why not put them into force? For a short time they were
applied in London, but the enforcement broke down because London
draws so much of its juvenile labour from contiguous areas to which the
clauses were not applied. There is still one day continuation school
under Mr. Fisher’s scheme which owes its success largely to the con-
sistent support of the local employers. For the rest the clauses are a
dead letter. They are, I fear, destined to remain so for a long time to
come. Their general enforcement would be a very costly matter. It was
calculated in 1919 that a complete system would require at the end of the
third year no less than 32,000 teachers. Enforcement by areas would
only be less costly on the assumption that some areas would not enforce,
and the London experience goes to show that enforcement on that assump-
tion is impracticable. For enforcement by industries, which is a
conceivable alternative in some industries, Mr. Fisher’s Act did not
provide.

We are told that the nation is already spending upon the social services
the utmost it can afford under present conditions. It may be so, though
apparently the indulgence of a taste for expensive town halls is of no
social service and is, therefore, permissible. At any rate in a time in
which education is only allowed to expand at the price of making counter-
vailing economies elsewhere, on the principle of the Irishman’s blanket,
which you remember he lengthened by cutting a piece off the bottom
and sewing it on the top, the day continuation school can be no more than
a day dream. Moreover, when funds again become available, the raising
of the school age has the first clam. We are too far committed to that
by the adoption of the Hadow policy of senior schools to draw back.
We may regret that it should be so and that the case for the continuation
schools has never been properly put to the nation for decision. Indis-
putably the transition from school to industry is the most critical operation
in adolescent life. Is it not far more important for society that so
bewildering a change of outlook and environment should be explained
and related to the adolescent’s previous experience, that he should be
guided and steadied through the first years of independence by teachers
who themselves have a knowledge of industrial conditions, than that the

L.—EDUCATIONAL SCIENCE 237

transition should be deferred in favour of one more year of full-time
schooling ?

But if we cannot have what we would like, let us try to make the best
of what we have. It is a solid gain that the young employee’s efforts to
improve himself in the evening school are no longer regarded by em-
ployers in general as entirely his own affair. Fees are paid by employers,
prizes are offered, reports are called for, and are sometimes allowed to
influence wages and promotion ; and interest is shown in many other
ways: These are all good in themselves, but a time-off system, such as
already obtains, for example, in the large engineering centres, would be
better than all of them put together. Is it treating education seriously
to relegate it, as we do, to the hours which should be hours of leisure
after the day’s work is done ? The youth of lively and independent mind
is repelled by such an arrangement. The standard and quality of the
work are alike depressed. It is notorious that irregularities of attendance
occur which no other educational institution would condone. Better
work is done in the evenings than we have any right to expect, for youth
will be served whatever the conditions. But until the classes can be held
in the day, the employer finding his share of the time required, there is
no prospect of any further large development of part-time education.

The nearest approach which has been made in this country to the type
of school with a strictly vocational outlook, but so far comparable in other
respects with the secondary school that it can reasonably be regarded as
alternative to it, is the junior technical school, which has been officially
recognised for about twenty years, though there was much earlier experi-
ment. At the present time there are about 170 of these schools, with
about 20,000 pupils between them. They recruit these students at
thirteen or fourteen years of age for a three or four years’ course of full-
time education, with the object of preparing them for entry into industry.
Sometimes they prepare for a single local trade, but usually for a group
of allied trades. ‘Their success—and they have been very successful—
is conditioned by their ability to place their students advantageously at
the end of the course, for enrolment is voluntary, and parents and pupils
naturally expect some return for the deferment of employment which
the course involves, ‘Their association with industry is, therefore, bound
to be close, and for the same reason they have individually no latent
possibility of indefinite expansion. They are ill suited to the conditions
of recruitment and employment in some industries—for example, agri-
culture and the iron and steel industry. There should, however, be room
for a carefully prepared increase in the number in areas where industries
predominate, to which the junior technical school is an appropriate
introduction.

Their position in the educational system is a little anomalous, for the
.age of entry does not synchronise with the leaving age in the elementary
schools, and falling as it does in the middle of the secondary school course,
they tend to lose the children who are recruited by the secondary schools
a year or two earlier, for some of whom the junior technical course would
be more suitable. To overcome this difficulty it has been proposed that
the junior technical school should be made a complete alternative to the

238 SECTIONAL ADDRESSES

secondary school, recruiting its students at eleven for a five or six years’
course, the first two years of which would be devoted to their general
education. I doubt, however, whether this would advantage the schools.
With the choice between the secondary school and the technical school
before them, most parents would elect for the secondary school, and not
for social reasons only. It is too early to decide at eleven years of age
that a boy or girl is to enter one of a group of trades at sixteen or seven-
teen. Even if the object were realised, one would anticipate a large
increase later on in the number of misfits, and some weakening of the
vocational purpose, confused, as it would be, by the need to give a general
course to the younger pupils.

Meanwhile, the schools are experiencing no difficulty in getting pupils:
rather they are threatened with a different danger, for they have been so
successful that in many of them recruitment becomes a matter of selection
among applicants, and is decided by competitive tests, which as at present
conducted are no certain guide to the comparative ability of the applicants
to profit by the instruction given. On the other hand, self-selection by
the pupil is no certain guide either.

I can offer no solution of this very interesting little problem. It is
interesting because we are here within sight of one of the fundamental
difficulties which the fashionable modern doctrine of the planned society
encounters. By whom in such a society, and on what principles, are the
allocations of man-power to be made, and how, if at all, can they be
reconciled with the preservation of that freedom to strive for advance-
ment which I have already spoken of as one of the ideals of democracy ?
Hitherto we have not been much troubled in education with this aspect
of planning, for the junior technical school is unique among our institu-
tions in the deliberate equation of supply to demand. But we are likely
to hear a good deal more about it in the immediate future unless economic
conditions alter substantially for the better. Although we may not believe
that education can be reorganised on the quota system, so many and
no more being trained to be clerks, so many to be machinists, and so on,
yet I think this feature of the junior technical school is well worth re-
taining for the sake of the light which will be thrown on the bigger
question by the working out of the equation on a small scale.

This discussion of the organisation of pre-employment vocational
education, fragmentary though it is, should not conclude without some
reference to the effects which the reorganisation of elementary education
at the age of eleven into primary and post-primary stages is likely to have.
This reorganisation is well on the way to accomplishment in the urban
areas. In the country areas there are special difficulties, due in the main
to sparseness of population, which it will take years to overcome.

While it is too early to speak positively of the results of reorganisation,
certain tendencies can already be discerned. It is much that we are getting |
rid of the confusion of aim between primary and post-primary, to which
was traceable the general feebleness and failure to grip the minds of their
pupils, which was found in many of the old mixed schools. The junior
school can now apply itself unhindered to the business of the primary
stage—development of the ability to communicate with others through

L.—EDUCATIONAL SCIENCE 239

reading, writing and speech : the active exploration of the material environ-
ment, including drawing and handwork: the formation of ideas of
magnitudes of all kinds and the application of the ideas of number to their
expression. The little country junior school, in particular, freed from
the incubus of the handful of older scholars who could be such a nuisance
to themselves and their teachers, is going to be a happier and more
efficient place. Singleness of purpose promotes earlier accomplishment ;
there is good reason to hope that in this respect a year at least of school
life may be saved, and that the curriculum on which not so very long ago the
elementary school child was released at thirteen years of age may be
effectively completed by the average child of eleven to twelve.

In the new senior school, taking children of eleven to fourteen and
fifteen, the most conspicuous feature is the break with the old bookish
tradition of elementary education. From a third to a half of the school
time is given over to practical work—science, experimentally studied,
including domestic science, woodwork and metal work, and many handi-
crafts. It is commonly postulated that there shall be no vocational bias
in this practical work, not even in the later years. At the same time, the
children, in the words of the Hadow Report, are to be ‘ encouraged to
take an interest in local industries and occupations, and illustrations for
teaching in the several branches of the curriculum should be drawn, where
possible, from local examples.’

Allow me for a moment to follow the argument whither it leads. In
what way that is educationally profitable, and not merely superficial, can
we interest the older children in local industries and occupations? In
the case of the modern mass industry, I suggest that at least one way is to
explain to them the fundamental process or processes on which the industry
depends, and to allow them where possible to try their hand at them.
For example, the boot and shoe industry, which is staple in the area in
which we meet and the area from which I come, is a mass-production
industry.

In shoemaking the fundamental process is the attachment of the upper
to the sole, in the case of the welted shoe by means of stitching mediated
by the welt and the insole. If that is explained to the children as a process
of development in time which is not yet completed, and if they are allowed,
under expert guidance, to try their hand in simple materials at this and the
immediately connected operations of the original handsewn work as
practised before the days of machinery, an intelligent interest in that
particular local industry will have been aroused, and the educational
effect will extend beyond those of them who know that this is the industry
which they will take up when they leave school. But what you will in
fact have done is to put the children through the first lessons which the
lad who is entering the industry takes in the department of boot and shoe
technology at the local technical college or in the monotechnic. Teachers
are prone to be too gingerly in the use they make of vocation in the schools.
Academically minded people with no personal experience of industry or
commerce assume an opposition between education through vocation and
general education: the one they say tends to dwarf the growing mind
and to narrow the outlook, as against the liberalising, expanding influences

240 SECTIONAL ADDRESSES

of the other. In practice, as my example, I hope, has indicated, there
need be no sharp opposition: indeed all education should have its
vocational side, for if on the other hand it seeks to create in the pupil an
understanding of his surroundings, on the other it endeavours to give
him the appropriate power of using them for his own purposes. The
real trouble is that we are very short of teachers of the right kind, by which
I mean persons trained to teach who also have an industrial vocation in
their fingers.

Vocational bias or no, the senior schools bid fair to endow their pupils
with a craft skill, besides other things, for which later they will demand an
outlet. In the nature of the case they will find that outlet in local industry.
While I am far from wishing to suggest that these practical developments
in the senior school will dispense us from the necessity of establishing
junior technical schools, where conditions are suitable, I do draw the
conclusion that if, by the interaction of the junior and senior schools,
the general level of intelligence is being raised—and it is—and if in the
senior school the skill of the individual is being trained to a high pitch—
and again it is—the senior school will make a very substantial direct con-
tribution toward the training of the rank and file of our industries. As
one Trade Union leader expressed it, ‘ Industry to-day is worthy of a
better workman.’ Many industries are going to get him, chiefly through
the agency of these senior schools.

Practically all the students in the technical classes and institutions of
every kind are either in employment or are reasonably assured of employ-
ment when they are ready for it. But for a large section of the juvenile
population no such comforting prediction can be made. The national
conscience is troubled about the problem of adult unemployment. It is
no longer enough that the State should provide the unemployed with
the bare wherewithal to keep body and soul together. Voluntary agencies
are springing up to help the unemployed men and women to maintain
their self-respect and to keep healthy in mind and body. But the nation
is not yet fully alive to the magnitude of the problem of juvenile unem-
ployment and to its terrible consequences. Is there any worse example
of social waste than that the young boy and girl should be carefully
nurtured for good citizenship and then plunged without warning into a
world in which they find they are not wanted, in which their instinct to
be independent is thwarted and the opportunity of honest useful work is
denied them? Could they have any experience more destructive of
mental and moral fibre—in a word, more decivilising ? Yet this is the
daily experience of thousands of them.

According to the latest figures which are available (May, 1933), 108,000
young people between the ages of fourteen and eighteen were registered
with the Ministry of Labour as unemployed though desiring employment.
Bad as they are these figures do not tell the worst. Registration at the
Employment Exchange is voluntary between the ages of fourteen and
sixteen, and if allowance be made on that account there are probably
not less than 160,000 young people unemployed. The number has more
than doubled in the last quinquennium, and it is likely to increase, for
owing to the high birth-rate of the two post-war years there will be an

L.—EDUCATIONAL SCIENCE 241

increase in the number of boys and girls leaving the elementary schools
next year of something like 50 per cent. over the number who have left,
or are leaving, during 1933, and for the same reason the number of juven-
iles between fourteen and eighteen years of age available for employment
will continue to grow for another five years.. The Churches, the juvenile
organisations, and other agencies are making great efforts to cope with
the evils resulting from this mass of unemployment. The contribution
of the State, however, is so small as to verge on the insignificant. The
Minister of Labour took credit recently for an increase from £110,000
last year to {150,000 this year in his expenditure upon courses of instruc-
tion for unemployed juveniles. Even so, the percentage of the registered
and insured unemployed juveniles who were regularly in attendance at
these courses was less than twenty-three, and the percentage of those
registered and uninsured was only ten.

This state of things increases one’s regret that the Continuation School
Clauses of Mr. Fisher’s Act have not been put into force. The Unem-
ployment Insurance Act of 1930 empowered the Minister for Labour,
after consultation with the Board of Education, and subject to regulations
approved by the Treasury, to arrange with local education authorities for
the provision of courses of instruction for insured contributors under the
age of eighteen, and to require attendance at such courses, where they
are available, as a condition of the payment of unemployment benefit to
any young person. These are the courses which I have just mentioned.
As there are less than one hundred of them, however, in the whole of
Great Britain, a very large fraction of the juvenile unemployed are beyond
their reach. There are in addition arrangements whereby the juvenile
unemployed can be sent to the ordinary evening institutes. In May,
which, of course, is not a typical month in this respect, less then 200
juveniles had that advantage.

It is not easy to suggest even the lines of a comprehensive scheme for
bringing these young people under official educational guidance, for the
incidence of the condition varies greatly from area to area. In some
areas the numbers are such that separate centres are economically feasible :
in others, juvenile unemployment is almost non-existent. But some steps
could be taken, given the support of public opinion.

In the first place, boys and girls should be encouraged, subject to
reasonable age limits, to remain at school until situations can be found
for them.

In the second place, the recommendation of the recent Royal Com-
mission that the age of entry into unemployment insurance be lowered to
fourteen should be enacted, subject to credit being given against the
Unemployment Fund in respect of voluntary attendance at school beyond
that age. This proposal has in the past encountered the opposition of
teachers and administrators who fear the effect that the possibility of
entry into employment with insurance may have upon school attendance
beyond the minimum insurable age. But under the safeguard mentioned,
the inclination to seek employment at the earliest possible age will be
weakened, and in any case the position is, I submit, too serious to warrant
the continuance of opposition on educational grounds.

242 SECTIONAL ADDRESSES

In the third place, the responsibility for framing schemes for dealing
with their own unemployed juveniles should be thrown upon the local
education authorities. The Board of Education since Mr. Fisher’s Act
has had the power to require the authorities to submit schemes providing
for the progressive development and comprehensive organisation of
education in their several areas. The scheme procedure is, therefore,
familiar both to the Board and to the authorities. When the schemes
have been submitted to, and approved by, the Board, it will become
the authorities’ duty to carry them out. The change would involve the
transfer to the Board of Education of the administration of all Exchequer
grants in aid of juvenile unemployment schemes, subject to such condi-
tions as the Minister of Labour might think fit to impose. ‘The procedure
suggested is on all fours with that which is followed in the medical inspec-
tion and treatment service. The local responsibility for that service is
cast upon the education authorities : at the centre the Minister of Health
is responsible, the Board of Education acting as his agents directly in
contact with the authorities.

The training of the unemployed juvenile is strictly an educational
matter. The Ministry of Labour was established for quite other purposes.
It is responsible for the disbursement of millions of money to individuals,
and the method of check and counter-check, which in the public interest
it is bound to adopt, leaves no room for that play of local initiative which
is a characteristic feature of the relations subsisting between the Board
of Education and the local education authorities. The problem cannot
be dealt with properly on the somewhat rigid lines to which the Ministry
is habituated, for it varies from area to area. The Board of Education’s
administration, on the other hand, is flexible, and the local authorities are
accustomed to it. ‘They would be encouraged by the change and would
be put upon their mettle. But the essential condition of progress in this,
as in all educational business, is an enlightened public interest. A
society awake to the degrading influence which enforced idleness is having
upon this large section of its citizens-to-be could not tolerate a half-
hearted parsimonious handling of so grave an evil.

SECTION M.—AGRICULTURE.

CHEMISTRY AND AGRICULTURE

ADDRESS BY
DR. ALEXANDER LAUDER,
PRESIDENT OF THE SECTION.

A RECENT President of this Section referred in his presidential address
to the fact that while many of his predecessors in this chair had been
chemists, none of them in recent years had taken the relation of chemistry
to agriculture as the subject of his address. A glance at the subjects of
the addresses for the past twenty years shows that the presidents who
have been chemists have confined themselves to general agricultural
questions or to problems of agricultural education or research. It is
true that in his address at Toronto in 1924 Sir John Russell dealt with
“Present Day Problems in Crop Production,’ and in his masterly survey
of the progress of agriculture during the past century, delivered at the
Centenary Meeting of the Association in 1931, he surveyed the develop-
ment of agricultural chemistry during the century, the treatment in both
cases being necessarily general.

The importance of the application of science, particularly of chemistry,
to agricultural practice has been realised for a very long time. In his
address to the first meeting of this Section at Dundee in 1912, Sir Thomas
Middleton dealt with this aspect of the subject (‘ Early Associations for
Promoting Agriculture and for Improving the Improver’). So far as the
British Association is concerned, this importance, as we shall see later,
was early realised. As far back as 1839, a petition to which many
influential names were attached was presented to the General Committee
asking for the formation of a separate Section for Agriculture. The
proposal was rejected however, and for many years there was no direct
representation of agriculture ; more recently, a Subsection for Agricul-
ture was formed which was attached either to Chemistry or Botany, and
the present Section was definitely established in 1912.

When the Association last met in Leicester in 1907, agriculture was
represented by two papers presented to the Chemical Section. One was
a discussion on the qualities of wheat and flour, dealing particularly with
the strength of flour, and the second on the ‘ Production of Acid or
Alkaline Reactions in the Soil by Manures,’ by Mr. A. D. Hall. A glance
at the recent programmes of this Section will give some idea of the
developments which have taken place since we last visited Leicester.

At the meeting of the Association in Swansea in 1880 Sir J. H. Gilbert was
President of the Chemical Section, and devoted his address to the appli-
cation of chemistry to agriculture. He pointed out that not only was the

244 SECTIONAL ADDRESSES

application of chemistry to agriculture included in the title of the Section,
but that in 1837 the Committee of the Section had requested the late
Baron Liebig to prepare a report on the condition of organic chemistry.
The first part of his report, entitled ‘ Organic Chemistry in its Applications
to Agriculture and Physiology,’ was presented in 1840, and the second
part on ‘ Animal Chemistry or Organic Chemistry in its Application to
Physiology and Pathology ’ followed in 1842. It is not necessary for me
to refer to the far-reaching effects of these reports. As Sir John Russell
said in his Centenary address, they can ‘ without exaggeration be described
as the most important publication in the whole history of agricultural
science.” Sir John Gilbert went on to point out that in the forty years
which had elapsed since the publication of Liebig’s reports, no president
had taken agricultural chemistry as the subject of his address, and, as
I have already pointed out, the subject has generally been avoided during
the succeeding fifty years.

Gilbert devoted about a third of his address to an historical introduction
and to a detailed description of the new views brought forward by Liebig.
He then went on to discuss how far Liebig’s views had been modified in
the course of time, and to state the conclusions which had been arrived at
by recent work on plant and animal nutrition.

As regards plant nutrition, the main problems were the sources of carbon
and nitrogen, and the views then expressed by Gilbert are still held without
serious modification at the present day. He confirmed the opinion of
De Saussure and Liebig, that the greater part, if not the whole of the
carbon, was derived from the carbon dioxide of the air. It is worthy of
note in passing that he was greatly interested in the effect of continuous
daylight on the carbon assimilation of plants and also of the effect of
illumination by electric light, but concluded as regards the latter that the
determining factor was the cost, which is still the position at the present
day.

He then turns to the difficult question of the nitrogen supply of plants
and describes the results obtained at Rothamsted by Lawes and himself.
The careful experimental work led to no conclusive results. Summing
up the result of the inquiry, Gilbert says that ‘ although the recorded
evidence is admittedly very conflicting, we then came to the conclusion,
and still adhere to it, that the balance of the direct experimental evidence
on the point is decidedly against the supposition of the assimilation of
free nitrogen by plants. Indeed, the strongest argument that we know
of in its favour is that some such explanation is wanted.’

The explanation followed some six years later, when the memorable
results of the Hellriegel and Wilfarth investigations were published.

In the later part of his address, he dealt with two questions which were
then exciting much attention, viz. the origin of muscular power and the
sources of fat in the animal body.

The conclusion arrived at was that the fat of the herbivora is largely
produced from the carbohydrates of their ration. As regards the origin
of muscular power, he concluded after a careful review, ‘ that all the
experimental evidence at command tended to show that by an increased
exercise of muscular power there was, with increased requirement for

M.—AGRICULTURE 245

respirable material, probably no increased production and voidance of
urea, unless owing to excess of nitrogenous matter in the food or of a
deficiency of non-nitrogenous matter, the nitrogenous constituents of the
body were drawn upon in an abnormal degree for the supply of respirable
material.’

He concluded his address by stating that ‘ while much remained to be
done both in chemistry and physiology as regards the above problems,
yet I think we may congratulate ourselves on the re-establishment of the
true faith in regard to them, so far at least as the most important practical
points are concerned.’

I have dealt somewhat fully with the state of knowledge of our subject
fifty years ago in order that we may appreciate more fully the changes
which have taken place since then. A great deal of the investigations
during the past half-century have been concerned with the more accurate
and detailed working out of the ideas discussed by Gilbert and his con-
temporaries and the explanation of many points in agricultural practice
which had been evolved by centuries of experience by farmers, and while
nothing spectacular in the way of change may have resulted, the cumu-
lative effect of the more accurate knowledge about soils, fertilisers, crops
and nutrition has undoubtedly been important,

In addition, several discoveries of fundamental importance have been
made ; the synthetic manufacture of ammonia and nitrates; the effects of
vitamins in animal nutrition ; the theory of base exchange in soils ; and
the development of bacteriology, to mention some of the more outstanding
only.

Some of these, although they might be described as advances purely
from the scientific side, have yet had practical applications of the highest
importance. The theory of base exchange in soils, which may be said to
have originated in this country with the early work of Way in the fifties of
last century and is associated in modern times with the names of Gedroiz,
Hissink and Wiegner, has provided an explanation of absorption and
exchange phenomena and of soil acidity, and has been successfully applied
to the reclamation of alkali soils in Hungary (Von Sigmond) and the
Western States of America, as well as in the treatment of land recovered
from the sea.

Amongst other notable advances which have had a practical application
may also be mentioned the use of sulphur for reducing fungoid attacks
on crops and for reducing alkalinity in soils, particularly soils used for
growing potatoes, and the study of the functions of elements which occur
only in minute quantities in plants, e.g. copper, manganese and boron.
The application of modern statistical methods to the interpretation of
field experiments and of biological experiments generally, has led to a
more accurate appreciation of the experimental errors involved, and of
the significance attached to any result.

Since the last meeting in Leicester, very real advances have been made
in our knowledge of the chemistry of the proteins, carbohydrates and fats,
and of enzymes ; this has led necessarily to a clearer appreciation of the
processes concerned in the synthesis of plant products and of animal
metabolism. .

246 SECTIONAL ADDRESSES

Among the major problems awaiting solution are the methods by which
plants take up their nutrients and the further development of biochemical
methods generally.

Tue SOIL.

The study of the soil may be approached from two points of view. In
the first of these it is regarded as the seat of certain chemical, physical and
biological processes which are investigated entirely from the scientific
point of view without any reference to agriculture. This has been the
method of attack of the Russian school in particular, and the supposition
is that when a sufficient body of knowledge has been accumulated in this
way, the consideration of the facts obtained may result in practical appli-
cations of value to the agriculturist ; it should be emphasised, however,
that the approach in the first instance is purely scientific. The interesting
volume published a few months ago by Prof. G. W. Robinson of
Bangor gives a clear exposition of the methods of this school and of the
results which have, so far, been obtained. ‘The other method has been
to study the soil as the medium of plant growth, to investigate practical
problems as they arise and to have as its definite aim the giving of advice
to those engaged in agriculture as to improving their methods of tillage
and crop production. It is obvious, of course, that no definite division
can be made between the two methods of approach, as is shown by the
history of recent developments. In this country, while the former
method has been by no means neglected, as witness the large amount of
research work carried on at Rothamsted and to a lesser degree elsewhere,
it is the latter method which has been in the main officially supported
and subsidised by successive governments.

Amongst the scientific methods which have emerged and received
considerable prominence and support in recent years is the modern
method of soil classification. This, while belonging to the scientific
method of investigation, also seeks to justify its existence by the claim
that it is of immediate importance to the farmer. The method was first
developed in Russia where it was shown as early as 1879 that climate is
responsible for the great tracts of similar soil found in that country ;
this idea was developed by later workers and more recently by Glinka
and others, who recognised some of the limitations of the original method
and proposed in place of the earlier zonal type of classification a system
based on the effect of climate on the development of the soil profile.
Soils were divided into two great groups. In the first were placed the soils
in which the profile shows that the external soil-forming processes,
especially climate, have predominated ; the second group comprises those
soils in which the internal process, i.e. parent material, still predominates.
These groups are further subdivided, but the whole system lays special
emphasis on the development of the soil profile—that is, the vertical section
from the surface soil to the unweathered parent material.

Although soil surveys had been carried out for a considerable time in
Europe and the United States, modern soil surveying may be said to date
from the first International Soil Congress held at Budapest in 1909.
At this meeting Glinka explained the new method of classifying and

M.—AGRICULTURE 247

mapping soils on a climatic basis, and soil surveys on the new basis were
soon begun in a large number of European countries and in the United
States. At the International Soil Congress held at Rome in 1924 it was
agreed to construct a soil map of Europe, and in 1926 the special committee
representative of the different countries concerned met in Hungary to
discuss in the field the practical details of the work on which the map
was to be based. At a subsequent meeting in Budapest the details of
the methods were adjusted, and it was agreed to undertake the construction
of a map of the soils of Europe based on as uniform a method of surveying
as possible. The ‘ General Map of the Soils of Europe,’ under the
editorship of Prof. Stremme, Danzig, was published in 1927. The
English text, translated by Dr. W. G. Ogg, of the Macaulay Institute for
Soil Research, Aberdeen, was published in 1929 with the aid of a grant
from the Department of Agriculture for Scotland. The first edition of
the map is on the scale of 1 : 10,000,000, and preparations for a second
edition are in progress.

The idea of a soil map of Europe is an ambitious one and the conception
is not without its attractiveness. In the present state of our knowledge,
however, it appears to many that the plan is possibly premature and that
there is a great element of unreality in the results. It is only fair to the
editors to say that they fully realise the difficulties of carrying out a survey
of this extent on a uniform basis, and admit that the results are imperfect
and will require to be modified in various ways. It seems fairly clear,
however, that the difficulties of making such a map have been seriously
underrated. Few workers in Europe have any extensive knowledge of
soils outside their own countries, with the inevitable confusion as regards
classification and nomenclature. At home, our soil workers have to be
content with spending a few weeks in the field each summer. It is evident,
therefore, that the difficulties are great and that the rate of progress must
be slow. At the same time, the meetings of workers from different
countries at the International Soil Conferences with the resultant exchange
of ideas and experiences must be valuable in the development of the subject.

Turning next to the methods employed in surveying, the profile is
studied as regards horizons, colour and texture changes, structure, drain-
age and vegetation. The surface horizons are naturally more extensively
studied. As regards the chemistry of the profile, most weight is placed
on the ratio of silica to sesquioxides ; other factors examined are the
presence and accumulation of salts, including calcium carbonate, and
changes in acidity with depth. On the results of these observations, the
soil is placed in its appropriate class. In passing, it may be noted that
there appears to be a certain reluctance on the part of the advocates of
these methods to ascertain by means of carefully conducted field experi-
ments whether some of the differences they are mapping are really signifi-
cant in practice and whether some of the finer differences which they
map, between soils within the same type, have any reality and make any
appreciable difference in agricultural practice.

As regards the utility of soil surveys generally, a reasonable case can
be made out for the benefits which are likely to follow a careful survey of
a new country which is just being developed. ‘The difficulty there, is to

248 SECTIONAL ADDRESSES

provide the staff and funds so that the survey work is kept ahead of the
development.

In a country like this, on the other hand, there is considerable doubt on
the part of many as to whether the benefits which are supposed to follow
such a survey will ever be realised. 'The question of suitable crop distri-
bution and association is well established as the result of generations of
experience and is not likely to be seriously altered as the result of such an
investigation. It is claimed that a soil survey on the scale of x inch to
the mile would be of great importance in connection with manuring and
in the interpretation of the results obtained by the various methods of
estimating the available plant nutrients in the soil. Before undertaking a
survey of such magnitude, it should be pointed out that such a claim would
require to be based on the results of a wider series of accurate field trials
than are available at present. At the same time, the importance of survey
methods from the purely scientific point of view and also in connection
with land reclamation problems should not be overlooked.

What the farmer wishes to know about his soil is whether it is adequately
supplied with nitrogen, phosphates and potash, and whether there is
sufficient lime present to give a satisfactory soil reaction. These are
reasonable questions, but it must be admitted that in the past the task of
the agricultural chemist who had to attempt to answer them was by no
means easy. Much progress has been made in recent years, and although
much still remains to be done, more satisfactory replies can now be given
to the farmer’s questions than was formerly the case.

With regard to nitrogen, no method exists by which we can judge the
requirements of a soil as regards this element ; the fact that most soils
respond to dressings of soluble nitrogenous fertilisers is about as far as
we can go in the way of prediction.

At the same time, it must be pointed out that considerable progress
has been made in the difficult question of the nature of the soil organic
matter. The recent work of Page in England, Schmuck in Russia and
Waksman in America (S.C.I. Ann. Rep., vol. xvii (1932), p. 461) has shown
that the so-called ‘ humic acids’ are in all probability protein-lignin
complexes. Synthetic products of this type have been prepared and
agree closely in properties with the humic acids found in soil organic
matter.

On the other hand, the lime requirement of a soil can now be given with
reasonable accuracy by routine methods which are suitable for use on a
large scale. The question as to whether the dressing of lime which is
theoretically desirable can be recommended is generally an economic
rather than a chemical one.

To determine what the requirements of a soil are with regard to available
phosphates and potassium is a more difficult matter. The most that can
be aimed at at present is to be able to say whether the soil is well supplied
or moderately supplied with these constituents, or is deficient in them.

The difficulties of discriminating between the available and non-
available constituents in a soil are obvious. In the first place, the way in
which plants take up their nutrients from the soil is still a matter of con-
troversy, and the fact that the soil is a heterogeneous and ever-changing

M.—AGRICULTURE 249

system of extreme complexity greatly increases the difficulties. The
chemical methods generally employed involve the extraction of the soil
with water or some dilute solvent and the estimation of the phosphates
and potassium which come into solution under standard conditions.
When the results can be interpretated in the light of field experiments
or experience, they are a very useful guide in advisory work. The fact
that the method is an empirical one is a great drawback, but the more
serious objection is that the results give a measure of the condition of a
soil at a particular time only and obviously cannot apply to its condition at
different times throughout the year. There is probably no hard and fast
line between the ‘ non-available’’ and the ‘ available’ constituents, the
one set gradually merging into the other.

These fundamental difficulties have suggested the idea of making use of
the plant itself as an index to the available plant nutrients in the soil.
Much work from this point of view has been carried out and two methods
based on these principles have been in use on the Continent for several
years. These are the well-known methods of Mitscherlich and Neubauer.
These methods, as well as Wiesemann’s modification of Mitscherlich’s
method, have been very ably and critically reviewed by Dr. R. Stewart in
a recent publication of the Imperial Bureau of Soil Science (Technical
Communication No. 25, 1932).

Mitscherlich’s method is based on his claim to have discovered a Law of
Plant Growth which is applicable to all plant species ; he claims to have
established that the plant yield can be increased by each single growth
factor, even when it is not present in minimum, so long as it is not present
in maximum. In its original form it was given by Mitscherlich as follows :
The increase of crop produced by unit increment of the lacking factor is
proportional to the decrement from the maximum. This can be expressed
mathematically as follows :

dy

oY —C(A—y)

where y is the yield, A is the maximum yield and x the growth factor.
(It is interesting to observe that this equation is identical with that for
a mono-molecular chemical change.)

Mitscherlich developed an elaborate technique for applying his theory
to the testing of soils by means of pot experiments. Here again, certain
arbitrary assumptions had to be made, e.g. as regards the depth of
sampling, the effects of the subsoil and the permeability of the subsoil.
These assumptions regarding the sampling factor undoubtedly raise
serious difficulties and have been the subject of adverse criticism.

__ From his estimation of the manurial content of the soil, Mitscherlich

then calculates the manurial requirements, the calculation being greatly
simplified by the assumption of the constancy of the effect factor, which
means that the manurial requirements for any one soil are the same for all
crops.

Mitscherlich’s method has been subjected to severe criticism, first on
his theoretical assumptions, his treatment of his experimental data and
the applicability of the Logarithmic Law ; and secondly, on the constancy

250 SECTIONAL ADDRESSES

of the ‘ Effect-Factors.’ Notwithstanding these criticisms, Mitscherlich
had such faith in the usefulness of his method that he has developed
stations in different parts of Germany for testing soils by his methods.
The Soil-Testing Society in East Prussia had in 1931 no less than five
stations and the number of pots in use was 25,000, equivalent to 2,500
soils tested. The original cost of a test was {5—-£6, but this has been
very much reduced in later years. This is direct evidence, at any rate, of
the belief of the practical farmer in the value of the test. It is satisfactory
to know that an installation of Mitscherlich pots has been set up at the
Macaulay Institute for Soil Research at Aberdeen, and that in addition a
large series of field pots have been laid down on different types of soil
according to the Mitscherlich plan. It will be interesting to see what
agreement is found between the results of the tests and the results obtained
by laboratory methods of extraction.

The Neubauer method, on the other hand, depends on the estimation
of the nutrient content of the soil by the growth of young seedlings. The
method depends on the absorption of phosphates and potassium by plants
in the early stages of their growth. By adopting a standard technique,
and using rye seedlings as his crop, Neubauer proved that the amount
absorbed was constant for a given sample of soil. By using a large
number of seedlings and by diluting the soil with sand, he considered
that the phosphates and potassium taken up by the seedlings would
represent the total available supply of nutrients in the soil. This would
give the nutrient content of the soil without any reference to the manurial
requirements of a particular crop, the estimation of this being the same
problem which is met with in all chemical extraction methods of analysis.

Having determined the root-soluble nutrients in this way, the next
problem was to calculate from the figures obtained the manurial require-
ments of the various crops. ‘To do this he makes two main assumptions—
(1) that under the conditions of the test the seedlings absorb the total
quantity of available phosphates and potassium, and (2) that crops under
field conditions can utilise only a certain fraction of the total amounts
present owing to the different conditions of growth. Making the above
assumptions and estimating the quantities of phosphates and potassium
removed by the various crops, he then calculates the ‘ limit values’ for
the various crops. In order to calculate the amount of fertiliser to be
applied to soils showing less than the ‘ limit values,’ he again assumes
that only 60 per cent. of the potash applied and 20 to 33 per cent. of the
phosphates are availing during the year of application.

Neubauer’s method has also been subjected to considerable criticism
on the analytical details, the influence of external factors and the deter-
mination of the ‘ limit values.’

The analytical work concerned requires a high degree of accuracy and
possibly some of the criticism of the method has been based on results
obtained without sufficient care having been taken in the analytical work.

The question of practical interest is how do the results obtained by the
two methods agree, and which method is the more reliable as to the
manurial requirements of a particular soil and crop? Neither of these
questions is easily answered. It may be said at once that there is a wide

M.—AGRICULTURE 251

divergence between the figures obtained and yet, applying the different
standards of the two methods, it is claimed that there is a good agreement
in both cases between the results of field trials and the recommendations
of the methods. It should be pointed out that the method of comparison
is purely qualitative, i.e. if a deficiency of potassium has been indicated
by the test and there is a response to a dressing of potassium salts in the
field, this is taken as a case of agreement.

One general difficulty which applies to both methods is that they can
be carried out only at institutes specially equipped for the purpose. The
Mitscherlich method requires a whole season to carry out the test, while
the Neubauer requires much supervision and extreme accuracy in the
analytical work. Attempts have therefore been made to devise simpler
biochemical methods suitable for the ordinary laboratory use ; of these,
two are of special interest.

The Azotobacter Method—The Azotobacter chroococcum is a well-
known soil micro-organism which has the power of fixing soil nitrogen,
and its use as a method for testing soils was first worked out in Denmark.
The organism is very sensitive to acid conditions, and this was used as the
basis of a method for measuring the ‘ lime requirements ’ of a soil. This
method has been superseded by the more convenient and more accurate
physico-chemical methods now employed. In addition to requiring a
non-acid medium, the rate of growth of the organism depends also on the
supply of phosphates, and later the method was adopted for the estimation
of the available phosphates in the soil. The defect of the method is that
there is no accurate means of estimating the development of the bacteria
and that the results are therefore only qualitative in character.

The Aspergillus Method—The principle of this method is the same as
that described above, but it has the advantage of being more quantitative
in character, as it is possible to collect the fungus and weigh it. It was
found that under standard conditions the growth of Aspergillus niger is
proportional to the amounts of available potash and phosphates in the soil.

The mould is grown in a suspension of the soil in a culture solution
containing all the constituents necessary for growth except the one being
tested for. The mixture is inoculated with the organism and incubated
for four to six days. During that time, the mycelium develops and covers
the surface of the liquid like a felt. It is then removed, washed, dried
and weighed. The estimations are carried out in triplicate or quadrupli-
cate, and the results of a large number of experiments have shown that the
standard error is of the order 4 per cent. The particular strain of
organism employed and the form in which the nitrogen is supplied are
important factors in the success of the determinations.

The method has been worked out by Prof. Niklas and his colleagues
at the Agricultural Research Station at Weihenstephen, near Munich,
and has also been subjected to a critical examination by Dr. A. M. Smith,
Edinburgh, who has tested the method with a variety of Scottish soils,
as well as investigating the effect of different sources of nitrogen on the
process.

The results obtained by this method have been compared with those
obtained by Neubauer’s method and have shown on the whole very good

252 SECTIONAL ADDRESSES

agreement, especially for potassium. ‘The richer the soil as estimated by
the Neubauer method, the greater the growth of Aspergillus. For phos-
phates the agreement between the two methods is very good as far as
poor soils are concerned, but is only moderately good for the intermediate
or richer soils ; one difficulty is that the absorption of phosphates by the
fungus is not constant for different types of phosphates.

The Aspergillus method is therefore likely to be valuable in estimating
the potassium and phosphate requirements of a soil. The results, as
might be expected, are more reliable for potassium than for phosphates,
and while not rigidly quantitative, give information as to whether the soil
is rich or poor in these constituents. It has the advantage of being rapid
and requiring no expensive apparatus (A. M. Smith and R. Coull, Scot.
Journ. Agr. vol. xv (1932), p. 262).

The whole question of available plant food is necessarily bound up
with the complex relationships which exist between plant and soil, and it
is unlikely that any simple or single method will be devised to overcome
the inherent difficulties of the problem and be generally applicable to
different sets of conditions. ‘The admitted lack of agreement obtained
with the various methods at present in use is undoubtedly due, to a large
extent, to the variety of factors involved, as well as to the fundamental
objections which may be raised to any one method. We are still very
ignorant of the process of assimilation by the growing plant, and until
we have more information on this subject, methods of estimating availa-
bility must continue to be largely empirical and the results merely first
approximations. f

The usual method of approach to the problem has been to study the
effect of the soil or plant medium on the plant. In Edinburgh attention
has in recent years been directed in the opposite direction—namely, to a
study of the effect of the plant on the soil. ‘The alterations to be observed
are, of course, small, but by applying methods which might almost be
described as analogous to modern micro-methods of analysis, measurable
changes can be followed with considerable accuracy. The results which
have been obtained are interesting and sometimes rather unexpected, and
although it is scarcely to be supposed that they will furnish a complete
picture of the relationship between soil and plants, one feels that any
contribution to the subject from a new angle may be of value in the study
of such a complex problem.

FERTILISERS.

Turning next to the progress which has been made in the manufacture
and use of fertilisers since the time of Gilbert’s address, there are one or
two notable dates and achievements to be mentioned.

In 1878 Thomas and Gilbert introduced their new basic process for
the manufacture of steel which resulted in the production of basic slag as a
by-product. It was a few years before the value of the slag as a source of
phosphates for plants was discovered. ‘The importance of the new slag
in agriculture was first realised in Germany. ‘The earliest experiments
in this country were carried out in England by Wrightson and Munro in
1885, and by A. P. Aitken in Scotland about the same time ; a year.or

M.—AGRICULTURE 253

two later J. J. Dobbie carried out the first experiments with the slag in
North Wales.

The now classic experiments laid down by Prof. Somerville in 1896
and carried on and developed by his successors, Sir Thomas Middleton
and Prof. Gilchrist, have demonstrated the value of this addition to phos-
phatic fertilisers and show as the result of twenty-five years’ experiments
that basic slag is, for certain types of soil, even more valuable than
superphosphate. Changes in the modern methods of steel making and
the effect of the large amount of scrap iron and steel available in the years
succeeding the war brought about a considerable alteration in the com-
position of the slags produced in this country. About ten years ago,
therefore, the Ministry of Agriculture and Fisheries set up a permanent
committee on basic slag ‘ to consider the development and improvement
of the manufacture of basic slag and the extension of its use.’ This
* committee has produced a valuable series of reports, the last (tenth) report
being published in September 1932. The work of the committee has been,
in general, ‘to make a detailed study of the agricultural values of the slags
now available to farmers and the chemical means by which these values
can be expressed.’ By means of the old but empirical citric acid test, the
slags produced in this country can be divided into two groups—a high-
soluble group in which 80 per cent. or more of the phosphoric acid is
soluble in 2 per cent. citric acid and a low-soluble group in which less than
40 per cent. is soluble. The experiments in recent years have been
carried out with hay, and while no final conclusion can be drawn at this
stage, the results indicate that with this crop the high-soluble slag showed,
in the first year, a slight superiority over superphosphate and a marked
superiority over mineral phosphate and low-soluble basic slag, and there
was in addition a considerable improvement in the quality as well as the
quantity of the hay obtained from the more active phosphatic fertilisers.
The figures obtained for the recovery of phosphoric acid were interesting.
For two years, the recovery of phosphoric acid added were superphosphate
12 per cent., high-soluble slag 9 per cent., mineral phosphate 4 per cent.
and low-soluble slag 2 per cent.

Pot experiments with barley carried out from 1927 to 1931 gave similar
results, the high-soluble slags giving better results even than superphos-
phate on certain types of soil (e.g. Millstone Grit) and markedly better
than the low-soluble slags.

It must always be borne in mind that basic slag is a by-product and that
its composition may be altered by changes in the methods of steel manu-
facture. The need for the work of such a committee is, therefore,
obvious and the committee should be continued.

The beneficial effects of mineral phosphates as fertilisers was noticed
as far back as 1845. New sources of material and improvements in the
methods of grinding have led to a great extension of their use in recent
years,

Superphosphate—Improved methods of manufacture and better
sources of raw material have led to a progressive improvement in the
quality of this fertiliser. In 1907 the total world production was 7,813,570
metric tons and in 1930 this had been almost exactly doubled (15,582,162

254 SECTIONAL ADDRESSES

metric tons). There has, of course, been a fall since then, but this is due
very largely to the prevailing depression. Formerly, superphosphate was
considered an acid manure and its continued use was supposed to deplete
the soil of lime and to increase its acidity. A large amount of experi-
mental work has been carried out in recent years, and the result is
to show conclusively that the objections to the use of the so-called
physiologically acid manures have been the result of misconceptions or
possibly even misrepresentations. ‘The use of superphosphate does not
generally increase the acidity of the soil.

Nitrogenous Fertilisers —Attention has already been directed to the far-
reaching effects of Leibig’s reports to the British Association in 1843 and
1847. Inthe year 1898 the Association was again to take a prominent part
inthe development of agriculture. ‘The President that year was Sir William
Crookes, who devoted his address to showing that if the rate of increase then
assumed of the world’s population was correct, the world would be faced
with a wheat famine in the not far distant future. He pointed out also
the necessity, if we were to increase the production of wheat, of the
increased use of ammonium salts and nitrates as fertilisers. As regards
nitrogenous fertilisers, he showed that we were living on our capital
of combined nitrogen compounds and that there was also the danger of a
nitrogen famine to be faced. The remedy he suggested was to devise
methods for ‘ fixing’ or bringing into combination the nitrogen of the
atmosphere, and he actually sketched methods and estimated costs of
effecting this combination by electrical means. As far back as 1784
Cavendish had shown that oxygen and nitrogen could be made to combine
under the influence of the electric spark. Many years were to elapse,
however, before a practical commercial method was evolved. ‘The
earlier methods were electrical in character and were developed in
Norway and Italy, where cheap supplies of electrical energy were available.
These methods have been more or less superseded, and ammonia is now
manufactured by a synthetic method on an enormous scale at the works
of the Imperial Chemical Industries, Ltd., at Billingham. ‘The method
used is a modification of the Haber-Bosch process. The practical difh-
culties which had to be faced were great ; of these I need only mention
the problem of working at pressures of over 200 atmospheres—i.e. over
3,000 lb. per square inch—and at an elevated temperature, to enable you
to realise some of the difficulties which had to be overcome. ‘The success-
ful development of the method is certainly one of the greatest triumphs
of chemistry and engineering in modern times. By this process, which
incidentally dispenses with the use of sulphuric acid, sulphate of
ammonia can now be prepared more cheaply than from gas liquor
where the ammonia is obtained as a by-product.

By the oxidation of ammonia to nitric acid by means of a suitable
catalyst ammonium nitrate can be prepared, and by mixing this with calcium
carbonate a valuable fertiliser, known commercially as ‘ nitro-chalk,’ is
manufactured.

Concentrated Complete Fertilisers —One of the most interesting develop-
ments of the synthetic ammonia industry has been the manufacture of
concentrated complete fertilisers containing nitrogen, phosphates and

M.—AGRICULTURE 255

potash in suitable proportions and all soluble in water. The basis of
these fertilisers is a mono-ammonium phosphate which is made by
subjecting finely ground rock phosphate to the action of a mixture of
sulphuric acid and ammonium sulphate. This gives directly a solution
of mono-ammonium phosphate containing a little ammonium sulphate
and calcium sulphate is precipitated. ‘The mono-ammonium phosphate
contains 12-2 per cent. nitrogen and 61-7 per cent. phosphoric acid and
is thus a highly concentrated fertiliser. By mixing this with ammonium
sulphate and a suitable potash salt, a wide range of fertilisers can be
obtained. ‘The ingredients are finely ground and then passed to a special
incorporator in which they are churned by means of paddles, whilst
saturated steam is blown in. In this way, granules are formed which
are then dried ; roughly, one ton of such fertilisers supplies as much
plant food as two tons of the ordinary mixed fertiliser of similar com-
‘position. They possess the obvious advantage of reducing freight and
handling charges and cost of distribution to the land ; they are granular
in texture and very easy to sow, and they can be stored without risk
of deterioration ; further, the constituents are all soluble in water.
Another point claimed in their favour is that they contain little except
the three fertilisers, nitrogen, phosphates and potash, while the ordinary
fertilisers contain appreciable, and in some cases large, amounts of calcium,
sulphur, and other elements. It is possible that in some soils the absence
of the additional substances might be a disadvantage, and a careful com-
parison of the new fertilisers with the old mixed fertilisers will be necessary
_to show that no disadvantage attends the use of the new compounds over
a number of years. Accurate field experiments on a wide variety of soils
were carried out in this country in 1930 to compare the relative effects
of the concentrated complete fertilisers and of mixtures of sulphate of
ammonia, superphosphate and potash giving the same amounts of nitrogen,
phosphates and potash. With the three crops examined (oats, potatoes
and sugar beet), the concentrated fertilisers gave the same average increases
in yield as the equivalent ordinary mixtures. At certain centres, however,
the concentrated fertilisers gave better results and at others a poorer yield
than the ordinary mixtures. The work is being continued.
It is obvious that if the concentrated fertilisers were used continuously

over a number of years, increased attention would require to be given to
liming.

BIOCHEMISTRY.

When we consider the development of organic chemistry during the
past century, we see that the earlier workers were much occupied with
the investigation of the substances which occur naturally in plants and
animals ; although many individual organic substances were known before
this time, the modern developments of organic chemistry may be said to
date from Wohler’s memorable syntheses of oxalic acid in 1824 and of
urea in 1828. While the early organic chemists were much interested in
those compounds which occur in plants and in the animal body, the trend
of investigation, particularly in this country, then shifted to the investi-
gation of more theoretical questions, e.g. the investigation of radicles,

256 SECTIONAL ADDRESSES

the theory of substitution and types and the theory of structure. These
investigations gave a great impetus to organic synthesis and the number of
known carbon compounds increased rapidly. Most of the substances
investigated, e.g. the many products obtained from coal tar, had no
connection with animal or plant life, and organic chemistry became much
more the chemistry of the carbon compounds than that of living organisms.
Until the beginning of the present century, the interest in the chemistry
of natural products steadily declined, and it is only since then that the
development of Bio-chemistry, as we know it now, may be said to have
taken place. The monumental work of Emil Fischer on the purines, the
simpler carbohydrates, the proteins and the tannins, to which he devoted
the greater part of his life, laid the foundations of this new branch of the —
science. His method for the separation of the amino-acids by first con-
verting them into esters and then separating the esters by fractional
distillation under greatly reduced pressure, has been invaluable in thé
study of this group of substances. By 1906 bio-chemistry as a separate
branch of the science may be said to be firmly established, and in that year
three journals devoted entirely to bio-chemistry appeared in Britain, the
United States and in Germany respectively. ‘The work initiated by
Fischer has been carried on by a brilliant band of workers in this and
other countries, amongst whom may be mentioned Perkin, Willstatter,
Gowland Hopkins, Robinson, Barger, Haworth, Windaus, Wieland,
Hans Fischer and Dakin.

It is obvious that the investigation of the chemical changes which take
place in a living cell presents difficulties of a very high order. The
reactions involved take place in very dilute solution ; the intermediate
bodies formed have a very brief existence, being rapidly changed into
some further product ; so that, while we may know the initial substances
involved and the final product of the reaction, there may be little known
as to the various stages in the formation of the final product.

While there have been great advances in our knowledge of the structure
of many of the substances found in plants and animals, we still know rela-
tively little about the processes by which they are formed. ‘The various
stages in the fundamental process of photo-synthesis have not yet been
worked out, although plausible suggestions as to what takes place have not
been wanting. We are ignorant of the stages by which amino-acids in
plants are formed from nitrates and carbohydrates and little is known of
the methods by which carbohydrates are changed into fats and vice versa.
In the same way, while we have a considerable amount of knowledge as
to how the proteins, fat and carbohydrates are broken down in animals,
little information is as yet available as to how similar changes are brought
about in plants. A notable recent advance is Robinson’s theory of the
way in which alkaloids are synthesised in plants, which has enabled him
not only to predict the constitution of certain alkaloids, but also to effect
the synthesis in vitro of alkaloids and alkaloid-like substances.

It is interesting to note in passing that where individual instances of
katabolism have been worked out, the breakdown does not occur, as a
rule, in the manner which the organic chemist would expect. The same
is true of the degradation of the amino-acids in the animal body.

M.—AGRICULTURE 257

‘In a series of lectures on the amino-acids, proteins and the proteolytic
enzymes recently delivered in this country, Prof. Max Bergmann of
Dresden describes the recent advances which have been made in our
knowledge of the amino-acids and the polypeptides, as well as of the
changes brought about by the enzymes which attack them. He shows
that for more than thirty years chemists have been endeavouring to
discover suitable methods for the synthesis of peptides containing the
more complex amino-acids, but that only recently has a general method
been developed. It is generally assumed that in the proteins the amino-
acids are linked together by condensation of the carboxyl group of one
amino-acid with the amino group of the next, a molecule of water being
eliminated and an amide or peptide linkage formed ; the ordinary protein
molecule is supposed to consist of a large number of such linkages.
Bergmann points out that the outstanding problem of modern protein
chemistry is to determine the effect of combination in peptide linkage on
the different amino-acids, and; secondly, how the nature of the peptide
linkage itself is influenced by the character of the amino-acids which take
part in its formation.

Investigations along these lines, while yet in an elementary stage, have
thrown much light on many of the biological processes, e.g. the trans-
formation of an amino-acid to a fatty acid, the biological degradation of an
amino-acid to a keto-acid, and, conversely, the biological synthesis of
creatine and many other reactions of the highest importance. Willstatter,
Waldschmidt-Leitz and Bergmann and his fellow-workers have also devoted
much time to the action of the enzymes which attack proteins and have
made significant advances along this line of work. Summing up, Berg-
mann states: ‘ The key to present day and future protein chemistry lies
_ in the development of new synthetic methods, in the action of enzymes on
proteins, and on an extension of the knowledge of protein metabolism
both in normal and pathological cases.’

Similar advances in our knowledge of the structure of the carbohydrates
have also been made. The work of Purdie and Irvine at St. Andrews
and of Haworth and his school at Birmingham, of Staudinger, Zechmister
and Mark in Germany and of other workers in the United States has been
particularly important in elucidating the structure of these complex
bodies.

The structure of the simple sugars and of the di-saccharides has now
been more or less worked out. The introduction of the six atom ring
formula and the greatly increased use of stereo-chemical methods of
exhibiting differences in structure have been important factors in the
developments which have been made.

- More recently, the constitution of the polysaccharides has been engaging
much attention and speculation, and notable advances fall to be recorded
both by chemical and by X-ray methods of investigation. ‘The adoption
of Haworth’s hexagon formula for glucose has led to new interpretations of
the experimental evidence bearing on the constitution of these substances.
It has been shown by Haworth and his co-workers that the constitution
assigned to cellulose rests ultimately on the constitution assigned to the
di-saccharide cellobiose and the mutual linking of -glucopyranose
K

258 SECTIONAL ADDRESSES

residues in a chain through positions 1 and 4 of the glucose molecule is
the fundamental principle of modern cellulose structure. By purely
chemical methods of investigation, they have shown that in some forms
the cellulose is a straight chain of limited length containing not more than
100 cellobiose or 200 glucose units.

The question of the size of the cellulose molecule has been attacked
by various other methods—by viscosity measurements of cellulose dis-
solved in Schweizer’s reagent or of the acetate or nitrate in organic media
(Staudinger), by study of the cleavage products obtained by enzymes and
by the X-ray methods of the Braggs and of Mark. The interesting fact
emerges that the results obtained by the X-ray investigations of cellulose
structure are in such wonderful agreement with the views adopted from
chemical methods. Sir William Bragg pointed out in a lecture recently
delivered to the Royal Institution that cellulose is the fundamental mole-
cular combination occurring in vegetable growth and that it is pre-
eminently the molecule of growth in the vegetable world. The cellulose
occurring in plants cannot have the same properties in all directions for
growth takes place along definite lines. The fibrous nature of cellulose
has long been recognised, as we see by the use which is made of it in
spinning threads and ropes which can stand an immense strain in one
direction. Bragg’s investigations have shown that cellulose is made up
of crystals, or crystallites, invisible under the microscope, but capable of
detection by X-ray methods. These crystallites are partly oriented,
having one direction more or less in common and to this arrangement of
the crystallites the peculiar and characteristic properties of cellulose are
due. Recent studies by Thiessen have indicated that the structure of
the pure cellulose fibre is the same as that of lignified tissue, except that
the spacing in the latter is wider to accommodate the lignin. Reference
has already been made to the fact that the organic matter of the soil is
derived from this lignin complex from which the cellulose has been
removed.

It has already been noted that the various stages in the building up of
carbohydrates in plants have not yet been satisfactorily explained. At
the same time, much work of the highest importance on the composition
of the chlorophyll in plants, the active agent in the utilisation of the
radiant energy from the sun, has been accomplished during the last
twenty years. In 1912 Willstétter and his co-workers at Munich
showed that chlorophyll as ordinarily obtained is really a mixture of
two substances, chlorophyll a (C;;H,,O;N,Mg) and _ chlorophyll 6
(C;5;HyO,N.sMg). They also investigated the yellow or reddish-brown
pigments, carotene (C4yyH;,) and zanthophyll (Cy9H;,02), which accom-
pany the chlorophylls and which are generally referred to as the carotinoids.
By a series of brilliantly conceived investigations, Willstatter has been able
to throw much light on the structure of these complicated bodies and,
in particular, on the relation between the chlorophyll of plants and the
hemoglobin of blood. In this connection reference must be made to
the work of Hans Fischer who has already synthesised hamin and made
great advances towards the synthesis of chlorophyll.

Enzyme Action.—It has long been known that enzyme action plays a

M.—AGRICULTURE 259

highly important part in most of the chemical reactions taking place in
plants and animals. In addition, the breaking down of complex mole-
cules by the action of enzymes is often employed in investigating the
constitution of these substances.

The action of enzymes has been known for over 100 years. Kirchhoff
in 1814 had discovered the catalytic action of the glutinous component
of wheat meal, and later, in 1833, Payen and Persoz separated an active
preparation of this enzyme from malt, the enzyme now known as amylase.
While much work of a preliminary kind was carried out in the succeeding
years, the results obtained were frequently inconsistent and confusing.
This is not to be wondered at when we consider the excessive complexity of
these bodies, the difficulties of purifying them and the extremely com-
plicated reactions in which they play a part. It is again Willstitter,
whose brilliant work on chlorophyll has just been described, who has been
mainly responsible for the great advances which have been made in our
knowledge of the enzymes during the past fifteen years. He began by
improving the technique of the methods of preparation, introducing
quantitative methods of control, and in this way was able to prepare
specifically pure enzymes. ‘This has led to a much more accurate know-
ledge of the specification of enzymes and has cleared up much of the con-
fusion which existed previous to his work. He has investigated the
colloidal characteristics of enzymes, the significance of the H-ion concen-
tration of the medium and the action of enzymes as synthetic agents—to
mention only a few of the outstanding results.. In addition, a rational
classification of the enzymes is now possible and much more detailed
information about their specific action is available. While the chemical
constitution of the enzymes has not yet been solved, there is no doubt that
the results of Willstatter and his school have been most stimulating to
those engaged in bio-chemical research and have had an important appli-
cation to the many industries which make use of enzymes in manufacturing
processes,

Vitamins—A discovery which will always be associated with the
name of the distinguished President of the Association this year
(Sir Frederick Gowland Hopkins) is the importance in nutrition of the
accessory food substances now known as vitamins. As far back as 1881,
it was noticed that milk cannot be replaced by an artificial mixture of its
chief constituents. In 1905 Pekelharing of the University of Utrecht
made the striking claim that there is an unknown but essential substance
in milk and other foods which is essential to nutrition. This work was
overlooked, and it was not until the publication of Hopkins’ work in 1912
that general interest was attracted to the subject. The progress since
then in the study of these bodies is most striking. One of the most
remarkable facts which have resulted from these investigations is the large
number of substances of the vitamin type required for the proper nutrition
of the higher animals, the number being stated to be at least nine. Ordi-
narily, five different vitamins are recognised, designated A, B, C, D and E.
Vitamin B is now subdivided into no less than five substances, commonly
referred to as the Vitamin B complex.

Vitamin A,—It is now fairly definitely established that Vitamin A is

260 SECTIONAL ADDRESSES

formed by the liver from the pigment carotene ; this pigment occurs in
carrots, green leaves, and various vegetables ; it is a hydrocarbon, CyyH,g,
which is synthesised in plants by the action of light. Carotene has a
deep colour, but Vitamin A is colourless. How carotene is converted into
Vitamin A in the tissues is uncertain. The empirical formula C,)H3,O
(or Cy9Hs,0) has been suggested, and it appears probable that within
the next few years the constitution of this vitamin will be known and then
its preparation by synthetical methods will be a possibility.

Vitamin B—Much work has already been carried out on the various
members of the Vitamin B complex, but the position is still obscure and
rather confusing. It is still uncertain how many active substances are
present and there is still no general agreement as to their properties.
B, and B, are the only two about which definite conclusions are at present
available. B, has been obtained in the crystalline state and contains both
nitrogen and sulphur. The provisional formula C,,H,,ON,S has been
suggested. It is anticipated that the pure product will be available in
the near future. While aconsiderable amount of work has been carried out
as to the chemical nature of Bg, little definite information has yet been
obtained.

Vitamin C.—The striking investigations of Szent-Gyorgyi and of
Waugh and King have led to a great advance in our knowledge of this
vitamin. What appears to be the essential substance in the vitamin was
isolated and found to have the formula C,H,O, ; it was named hexuronic
acid. ‘The preparation of a larger quantity of the material from the
juice of Hungarian red pepper by Szent-Gyorgyi has enabled the consti-
tution of the acid to be worked out by Hirst, Cox and Reynolds at
Birmingham. ‘The substance is now named ascorbic acid, and its anti-
scorbutic properties are so marked that it may well prove to be Vitamin C
itself.

Vitamin D is now available as a commercial preparation under the
name ‘ Calciferol.’ It is prepared by the irradiation of ergosterol with
ultra-violet light ; its formula is C,,H,.O.

The discovery of vitamins has undoubtedly thrown much light on many
_ of the difficult problems of nutrition and disease, and there can be no
doubt that, as our knowledge of these substances increases, more and
more use will be made of them in feeding. Already some notable advances
have been made. The close connection between the yellow coloured
pigment carotene and Vitamin A has just been referred to. Milk and
butter produced in the summer months, when the cows are at pasture,
have a yellow colour which is associated with the presence of carotene and
of Vitamin A. On the other hand, butter produced from winter milk,
when the cows are stall fed, is much whiter in colour and has a much
lower content of carotene and Vitamin A. ‘The popular view which
associates the yellow colour of milk with ‘ richness’ is therefore not at
fault, and incidentally the importance of prohibiting the colouring of
butter and cheese should be mentioned. ‘The problem was how to
provide food with the necessary carotene or Vitamin A content during the
winter months. Experiments on the artificial drying of grass carried out
at the Agricultural Research Station at Jealotts Hill, Berkshire, have

M.—AGRICULTURE 261

shown that grass can be rapidly dried in a band drier at a temperature of
200° approximately, with scarcely any loss of digestibility or nutritive
value and, what is more surprising, with only a small loss of the carotene
content. It was also shown that the carotene content and the nitrogen
content of pasture herbage were associated, grass of high nitrogen content
being rich in carotene, so that by properly balanced manuring the carotene
content of the pasture might be maintained at a higher level. A winter
feeding experiment with cows was then arranged and the artificially dried
grass was used to replace an equivalent amount of the ordinary food, with
the result that the carotene and Vitamin A content of the butter was kept up.
This effect was not produced by the addition of ordinary green silage.
The importance to the public health of being able to produce in winter
butter which, in regard to colour and Vitamin A content, is equal to the
butter produced in summer from grass-fed cows, can hardly be over-
estimated.

As regards vitamins generally, the most important problems are the
differentiation of the different vitamins and the determination of the
vitamin requirements of man and the higher animals. By the time this
is done, it appears probable that there will be an abundant supply of
pure vitamins to compensate for the deficiencies in the ordinary rations.

While talking of nutrition, the part played by the mineral matter of the
food must also be mentioned and the necessity for maintaining a correct
ratio between the basic and acidic constituents. Much important work
has been carried out in this country in recent years by the Rowett Institute
and the Animal Nutrition Research Institute at Cambridge on the mineral
content of pastures. In his Presidential Address at Bristol in 1930
Prof. Du Toit described the far-reaching results of Theiler’s work in
South Africa on phosphorus deficiency, and referred also to Aston’s
work on iron deficiency in New Zealand.

AGRICULTURAL DEVELOPMENT.

Sufficient has been said of the scientific advances in recent years to
indicate the great importance of their application, when possible, to
agricultural industry. At one time it was only too apparent that there
existed a long lag between scientific discovery and its application in agri-
cultural research, but this has diminished considerably in recent years ;
indeed, it may now be said that any new line of work is almost at once
turned to account in agricultural investigation.

This agricultural work is undertaken mainly at the new agricultural
research institutes, although a considerable amount of work is still carried
out at the universities and the agricultural colleges.

The development of these research institutes has been one of the most
marked advances connected with agricultural science which have taken
place in recent years.

In Scotland alone, for example, institutes have been established within
the last few years for research in animal nutrition, in animal diseases, in
animal genetics, in plant breeding, in dairying and in soil science, and the
progress in England has been equally great.

How are the results of these investigations brought before the farmer

262, SECTIONAL ADDRESSES

and what is his response to them ? How far are they being incorporated
into modern agricultural practice ?

It is one of the functions of the agricultural colleges to be the connecting
link between the research institutes and the farmer. Advisory services
in connection with the colleges now cover the whole country, so that
farmers desiring advice have it provided at their own doors and without
cost. Mention must also be made of the services of the Ministry of Agri-
culture and Fisheries, the Department of Agriculture for Scotland and
the Ministry of Agriculture for Northern Ireland, whose various publica-
tions, journals, bulletins, etc., contain much valuable information.

As to the reaction of the farmer, one is bound to admit that, owing to
the inherent disinclination of the older farmers to listen to new ideas,
the response is not what we should desire. At the same time, the more
intelligent and progressive farmers are fully aware of the value of the
advisory work of the colleges and make use of them regularly. The
whole attitude of the farmer to the colleges is vastly different from what
it was twenty-five or thirty years ago, and the amount of advisory work is
increasing year by year.

This much must be admitted, however, that there is still room for
improvements in agricultural methods and that much of the farming still
requires to be raised to the level of the best practice.

We may state, therefore, with confidence that the difficulties of
present-day agriculture are not due to the lack of scientific advice avail-
able to the farmer; indeed, it is even sometimes alleged that the
present-day troubles of agriculture are due to scientific research and to
an abnormal increase in production ; even the Minister of Agriculture
remarked semi-humorously the other day : ‘ Improvements in technique
are the great curse of the modern world. Some infernal scientist comes
along and shows us how two blades of grass can be made to grow where
one was before. Instead of that being the highest praise, it is one of the
most damning accusations you can make against any man or any country just
now.’ An amusing piece of invective, but no help to us in our difficulties.

In a paper contributed to this Section last year at York, Mr. E. M. H.
Lloyd, the Assistant Secretary of the Empire Marketing Board, quoted
figures to show that the world production of food stuffs and raw materials,
though it increased rapidly after the set-back due to the war, had not
reached, in 1929, the continuation of the pre-war trend. The statistics
suggest that world agricultural production is, in fact, less now than it
would have been but for the war. ‘ The agricultural crisis is due to the
fall in prices ; and this fall of prices is due more to diminution of effec-
tive demand through a contraction of consumers’ money incomes than to
any exceptional increase of supply.’

It is certain, therefore, that the advances in the application of science
to agriculture are not the causes of the prevailing agricultural depression
throughout the world, but that these are to be sought for in the absence
of satisfactory schemes of collective planning, marketing, stability in the
value of money and the maintenance of better equilibrium between prices,
wages and debts, to quote again from Mr. Lloyd.

Whatever opinion may be held as to over- or under-production of agri-

M.—AGRICULTURE 263

cultural produce in the world as a whole, this much at any rate is clear :
that an increased production of home-grown food is of paramount
importance to our own country.

There are two main reasons why this isso urgent. We have to remember
that in the industrial changes which have taken place since the war many
of our industries have either disappeared or have been so reduced in
amount that there has been a serious displacement of labour. So far as
one can see, there is no prospect of these industries recovering their
former size in this country, and, while new industries may be introduced,
there is a grave fear that the displacement of many workers from their
previous occupations is permanent. No better way of using this displaced
labour can be imagined than to employ it on the land to increase our
home agricultural production. It is unnecessary to point out or minimise
the obstacles to so profound a change—the disinclination of an urban
population to move to the country, the problems of housing and wages,
and the necessity of obtaining a remunerative price for the food produced
are only some of the more obvious difficulties involved.

The second reason is equally important, and that is to supply the
consumer with as large a proportion as possible of fresh food which has
not been subjected to chilling or freezing or to any of the chemical
manipulations or treatment which are much too common nowadays.
The deleterious effects of some of these processes on the general quality
of food is now well appreciated, and it is certain that, no matter how care-
fully these methods are carried out and controlled, the resulting product
is not as good as the fresh material. The aim of the home producer
should be, therefore, to produce the type of food in largest quantity
where this quality of freshness is of the highest importance—e.g. meat,
milk, butter, eggs, poultry and market-garden produce and fruit. In
this way he can best meet the menace of overseas competition. At the
same time much work will require to be done to educate the consumer
to appreciate the superior value of fresh home-grown food as against
that which has been chilled or preserved. It is quite certain that the
consumer will not purchase home-grown produce for sentimental reasons :
he will have to be convinced that the quality is better and that he is
getting equally good value for his money. It will be necessary in this
connection for the home producer to study the public taste a little more
carefully perhaps than he has done in the past.

The modern farmer must now choose between two courses. He may
either adhere to traditional systems under which his products have to
meet those of overseas competitors who possess dominant advantages in
the production of most of their crops, or, on the other hand, he may alter
his system to meet the new conditions and produce those commodities
which will command an unassailable position in the home market.

This alteration in the system of farming will mean many important
changes ; more concentrated foods must be grown, e.g. beans and peas,
and less concentrated foods imported. In this connection the highly
nutritive quality of young grass and the methods for its utilisation should
receive more attention ; the growing of hay on a quality basis and the
adequate use of silage should also be mentioned.

264 SECTIONAL ADDRESSES

Another problem to which sufficient attention is not being paid. at
present is the use of the poorer quality of land, such, for example, as we
find in Scotland at elevations of 600 feet and: over. Much of this, under
proper methods of management, could produce a larger number of store
cattle, milk and milk products, and poultry than it does at present. In
more favourable times the possibility even of further land reclamation
should not be overlooked. It may seem futile at a time when there is
such difficulty in getting any adequate return from our best land to
suggest that further land should be reclaimed ; the present conditions,
however, will not, we hope, be permanent, and we have to consider what
may be possible in more normal times. The spectacle of large areas of
land suitable for reclamation and.close to our great industrial centres
reflects little credit on the agricultural policy of the past generation or
two. In many of these areas there are abundant supplies of labour near
at hand, and the difficulties of housing and transport would be reduced
to a minimum. It is not suggested that at the present such reclamation
would be economic, but as a means of using unemployed labour it would
at least have the merit of leaving something tangible as the result. In an
article contributed to The Times last November, Sir Daniel Hall gives
an interesting account of the enormous reclamation and land drainage
work which has been carried out in Italy during the past ten years, and
points out that thé agriculturally minded man must regard it as the
biggest bit of constructive work since the war ended. In conclusion he
says: ‘A great work. But what of the cost? As yet, it is impossible
to judge of the finance, for who shall say what land is worth or is going
to be worth? But the Italian State is said to have expended £31,000,000
gold in the last ten years on “‘ Bonifica,”’ against which it is claimed that over
a million acres have been or are being reclaimed. ‘The severely economic
English view would be that, since land is going out of cultivation, it is
waste of money to make more. But in Italy men do still live by the land ;
the money has been spent in Italy and almost wholly on labour, and there
is something real and lasting to show for the expenditure. It is a return
to the high Roman way, to the courage that drove the first roads and
built the bridges through Barbarian Europe.’

The importance of agriculture, not merely as a means of producing
additional home-grown food but as an industry of fundamental social
value, is now being realised by all sections of the community.

With the good offices of statesmen, scientists, economists and others
interested, and with the goodwill of the people at large, it is not too much
to hope that the British farmer will choose wisely, and that the character
and energy which have distinguished him for generations will enable him
to secure once more for our British agriculture that prosperity which is
vital to the welfare of our nation.

REPORTS ON THE STATE OF SCIENCE,
Etc.

SEISMOLOGICAL INVESTIGATIONS.

Thirty-eighth Report of Committee (Dr. F. J. W. WuippLe, Chairman ;
Mr. J. J. SHaw, C.B.E., Secretary ; Prof. P. G. H. Boswe tu, O.B.E.,
F.R.S., Dr. C. VeRNoN Boys, F.R.S., Sir F. W. Dyson, K.B.E.,
F.R.S., Dr. WiLFrep Hatt, Dr. H. Jerrreys, F.R.S., Sir H. Lams,
F.R.S., Mr. A. W. Les, Prof. H. M. Macpona.p, F.R.S., Prof. E.
A. Mine, M.B.E., F.R.S., Mr. R. D. O_pHam, F.R.S., Prof. H. H.
PLaskETT, Prof. H. C. Plummer, F.R.S., Prof. A. O. RANKINE,
O.B.E., Rev. J. P. Row.anp, S.J., Prof. R. A. Sampson, F.R.S.,
Mr. F. J. Scrase, Dr. H. SHaw, Sir Frank E. Smitu, K.C.B.,C.B.E.,
Sec.R.S., Dr. R. SToNELEY, Mr. E. TILLotson, Sir G. T. WALKER,
©Si3 F:R:S.),

Dr. }. E. Crombie—In August 1932 the Committee lost one of its most
valued members by the death of Dr. J. E. Crombie, who had served since
1915. He was a practical seismologist and maintained in turn in his beau-
tiful home near Aberdeen seismographs of several patterns, the last one
being a Milne-Shaw. In 1919 when a home had to be found for the seis-
mological equipment and library from Milne’s station at Shide in the Isle
of Wight, Dr. Crombie provided funds, which were, after some delay,
devoted to paying part of the cost of a well-schemed extension of the Uni-
versity Observatory at Oxford. It was his generous help that enabled Prof.
Turner to continue the international seismological work through the years
of financial stringency. Dr. Crombie was a man of many interests, and
served well his University and the City of Aberdeen. His memory is held
in honour by his colleagues on the Seismological Committee.

By his will Dr. Crombie provided that on the death of his wife his trustees
should allocate the sum of £1,000 free of Government duties to the Seismo-
logical Committee of the British Association ‘ to be applied towards assisting
in the investigation of seismological research.’

Dr. Crombie’s seismographs were bequeathed to the University of
Aberdeen. The Milne-Shaw seismograph has been set up for trial in a
cellar at King’s College, Aberdeen. An Agamennone seismograph has been
presented to the Science Museum, South Kensington, which already had a
Mainka seismograph given by Dr. Crombie. His other Mainka seismograph
remains at Aberdeen.

Finance-—The Accounts for the year ending June 30, 1933, differ in
several respects from those for the preceding year. The new scale of sub-
scriptions adopted by the International Union for Geodesy and Geophysics
in 1930 came into force in 1932 and in spite of prognostications, on which
the statement in the last report ‘no increase in the subvention from the
International Seismological Association towards the cost of the International
Seismological Summary is to be anticipated ’ was based, there has been an
increase from £259 to £404. In view of this increase, the Committee was

L

266 REPORTS ON THE STATE OF SCIENCE, ETC.

able to withdraw the application to the Council of the British Association
for a special grant for the year.

On the other side of the General Account there is a large saving in printing,
but a new item appears, the Committee having accepted for this year the
responsibility, formerly borne by Dr. Crombie, for part of the salary of the
scientific assistant at the University Observatory, Oxford.

The income of the Gray-Milne Trust Fund has fallen (temporarily it is
hoped owing to the lapse of the dividend due from the Canadian Pacific
Railway. There has been no considerable call on the Fund during the
year. It is anticipated, however, that the charges for printing the memoir
by Messrs. Jeffreys and Bullen referred to below will come out of the Fund.

It is hoped that at the meeting at Lisbon in September 1933 of the
International Seismological Association such a grant will be given to the
University Observatory, Oxford, as will allow the work on the International
Seismological Summary to be continued there. The Committee wishes to .
assist the Observatory by devoting to this purpose the £100 payable from
the Caird Fund. The Committee is not asking for an additional grant
this year.

ACCOUNTS, JULY 1932—JUNE 1933.
General Account.

Pits) id, Los. d.
Brought forward . 192 3 8 I.S.S.—Printing . 254 15 Oo
B.A. Caird Fund . 100 o o Printing and Stationery 4 9 I
U.G.G.1., for I.S.A. . 404 11 3 Postage . = SSO Peal LR
Sale of I.S.S.. . © 13° 7 Computing y . 87 11° 5
Bank Interest . A © 7 © Scientific Asst.
(Salary, Part) . . 150 0 0
Translation d . 010
509 7 114
Operation of Seismo-
graphs . F OY OB MEN
Committee expenses . O10 0
518 14 64
Balance carried forward 179 0 11%
£697 15 6 £697 15 6
Gray-Milne Trust Account.
Los. d. Lin gid,
Brought forward - 342 19 3 Miss Bellamy (Honora-
Trust Income . . 66 14 10 rium) . ¢ . 30 0.0
Bank Interest . ; 113 8 Milne Library . , 414.0
Fire Insurance . ; o1I5 0
Press Cuttings . , LMEVSIO
36 10 0
Balance . ; » 374 17° 9
£411 7 9 £41r 7 9

SEISMOLOGICAL INVESTIGATIONS 267

The International Seismological Summary.—During the latter half of 1932
there were two issues of the Summary. ‘These completed the volume for
- the earthquakes of 1928. The issues containing the Summary for the first
two quarters of 1929 have been printed. Prof. Plaskett reports that the
MS. for the rest of that year is nearly ready for the printer. As far as the
records for 1930 have been received, they have been copied on to cards in
readiness for analysis. It is proposed to take into use at once such new
tables as may be adopted at the meeting of the International Seismological
Association at Lisbon.

Seismographs. —The five seismographs belonging to the British Associa-
tion have remained on loan to the Seismological Stations at Oxford (2),
Edinburgh, Perth (W. Australia) and Cape Town.

Interesting memorials of the earliest seismological station in England
have been obtained recently by the Science Museum, South Kensington.
Early in 1932 Miss Morey of Newport, Isle of Wight, presented to the
Museum the original lamp-post on which Milne erected his first seismograph
at Shide. The drum and recording mechanism of this seismograph, which
were in the possession of Mr. W. H. Bullock, have been purchased and an
effort is to be made to reconstruct the apparatus as accurately as possible.

A good many parts of old instruments from Milne’s workshop are now
at the University Observatory, Oxford, but it appears that there is nothing
of definite historical interest, and with the approval of this Committee
Prof. Plaskett will dispose of the material at his discretion. Some of the
parts found in this collection have been lent to the Rev. H. Pain of Turville
Vicarage, Henley-on-Thames, who has constructed a seismograph and
obtained good results.

During the year the Milne-Shaw seismographs supplied by Mr. Shaw
to the Department of Geology, Liverpool University, and to the Depart-
ment of Geology, University of Vermont, have been brought into operation.

British Earthquakes——A valuable paper dealing with the macroseismic
evidence of four recent Scottish earthquakes has been published by Dr.
G. W. Tyrrell in the Transactions of the Geological Society of Glasgow,
Vol. xix, Part I, 1931-32. The shocks examined are:

(1) The Oban earthquake of 1925, December, 23 12%.

(2) The North Sea earthquake of 1927, January, 24° 5".

(3) The Collentraive earthquake of 1927, January, 274 92.
(4) The Lochgilphead earthquake of 1927, January, 27% 162.

On January 14, 1933, at about 8530™ an earthquake was felt over a large
area in the North of England ; and a slight after-shock, felt at 16h. 3m. on
the 17th, was recorded at Stonyhurst. A report on this earthquake has
been prepared by the Rev. J. P. Rowland. An earthquake which was felt
in Jersey on April 12 was recorded by seismographs in England.

Small disturbances not recorded by seismographs were reported by
newspapers as occurring on the following dates : 1932, December 31, Devon;
1933, April 23, Canterbury. A weak tremor, reported as being felt at

Great Harwood, Lancs., on 1933, July 7, was reported at Stonyhurst
at 12h. 1m.

The Revision of Seismological Tables —The following note has been
contributed by Dr. H. Jeffreys and Mr. K. E. Bullen:

The observations recorded in the I.S.S. from 1923 to 1929 are being
used to construct revised tables for the principal waves recorded in large
earthquakes. The method used is equivalent to a least-square solution by
successive approximation. The numbers of earthquakes used in the
respective regions are: Europe, with the Mediterranean and Central

268 REPORTS ON THE STATE OF SCIENCE, ETC.

Asia, 10 3 North and Central America, with the North Atlantic, 19 ; South
America, 4; Japan, 15 ; Pacific and Indian Oceans, 9 ; total, 57... These
have been selected as specially well observed and capable of having the
epicentres well determined from the data.

The solution for P proved to be straightforward. The times already
found by H.J. and published by the Committee were right within a second
up to about 19°; but there is a sharp bend in the curve at this distance,
the maximum correction needed being — 5.7s. at 30°. Beyond that dis-
tance smaller corrections are needed, reaching + 1s. about 60°. At greater
distances still the corrections are again negative, reaching — 3s. at 105°.

In the case of S there was much difficulty owing to misidentifications.
It seems that the H. J. tables are nearly right to 15°, but need a slight in-
crease to 19°, and that there is at this distance a discontinuity similar to
that found for P.; a correction of — 8.7s. is needed at 30°. The correction
vanishes about 60° and is about +4s. beyond 80°.

The waves through the core! have also been discussed and times have
been found for PKP(= P’ =P.P-P), SKS(= ScPcS) and SKKS(=ScPcPcS).
The forms of the curves differ very little from those given by Gutenberg,
but, additive constant corrections are needed to adapt them to the same
focal depth. ‘Times for the diffracted P at distances up to 143° have been
obtained.

The outstanding problems relate to the determination of focal depth and
of the depths at which PP, PS and SS are reflected. So long as the focus
is within the upper layers the effect of focal depth is simply to make S arrive
early by about the same amount at all distances, the forms of the P and S
curves remaining unaltered. This additive constant can be determined
and allowed for. But it remains doubtful to what focal depth the standard
S curve corresponds ; though several methods have been tried none seems
satisfactory. ‘The additive constant varies between different earthquakes
by as much as 18s. This is inconsistent with the supposition that P move-
ment is always. generated by the original shock ; in that case the variation
could only be about 5s. There seems to be no doubt that in some earth-
quakes there is primitive P movement and in othersnone. All the curves
have been made to correspond to the same focal depth, but there remains
some doubt as to what that depth is. Some earthquakes not recorded as
having deep foci in the I.S.S. have proved to have foci 50 to 100km. below
the top of the lower layer.

PP, PS and SS are frequently recorded, but the residuals are irregular and
it is still uncertain whether any definite conclusions can be drawn from them.

The bends in the P and S curves at 19° may be the result of either a
rapid continuous increase of velocity or a discontinuity at a depth of about
400km., the velocities rising by about ro per cent. when it is crossed. On
the former alternative points of large amplitude would occur, which have
been sought by Miss Lehmann but not found. A discontinuity on the
other hand would give reflexions, which again have not been found, but
their amplitudes would in any case be small. The most likely one to be
observable may be one of PP type reflected on the inside of the discon-
tinuity, just as SKKS is the best observed reflexion on the surface of the
central core.

Other waves recorded with fair frequency are PKS, P’, and SKSP.
An attempt will be made to construct empirical tables for these also.

Valuable supplementary information has been received in correspondence
with other seismologists, especially Miss I. Lehmann, Miss E. F. Bellamy

1 The letter K is used for a compressional wave through the core (Kernwelle).
The notation is taken from Bulletins issued from Georgetown.

MATHEMATICAL TABLES 269

and Messrs. Gutenberg, Scrase, Byerly and Hodgson. This will be
acknowledged more fully later.

High Focus Earthquakes —That earthquakes with deep foci occur is well
established, but the significance of the observations which led Turner to
attribute high foci to certain earthquakes is not yet known. Mr. E. Tillotson
has chosen for investigation an earthquake of this type, ‘ The African
Rift Valley Earthquake of 1928, Jan. 6.’ Mr. Tillotson has examined about
100 original records of this earthquake. There is no doubt as to the
location of the epicentre, which is in the Subukia Valley, Kenya Colony.
The anomalies in the observations are still under consideration.

Microseisms.—The discussion, by Mr. A. W. Lee, of the microseisms
recorded in all parts of the world during January 1930 has been completed
and will be published shortly. Data are available for 57 observatories.
The most disturbed of them are Reykjavik and Honolulu.

In Europe microseismic storms do not occur in the absence of barometric
depressions over the eastern part of the Atlantic, but some deep depressions
are not accompanied by large microseisms. No evidence for a direct
connection between microseismic disturbance and the sea-disturbance in
particular regions has been found.

Periodicity of Earthquakes.—Two notable papers by Dr. C. Davison (a
former member of the Committee) on periodicity in earthquakes have
appeared recently in the Philosophical Magazine (Ser. 7, Vol. 15 (1933) ).
In the first paper the eleven-year period is discussed on the basis of statistics
covering the whole globe and the last two centuries. It is found that in all
parts of the world earthquakes are more frequent in the years of many
sunspots. In the second paper a 19-year period is investigated. In this
case the maximum frequencies of the northern hemisphere tally with the
minimum frequencies of the southern hemisphere. The period seems to
be identical with the nutation period of the earth and it is therefore demon-
strated that the strains associated with the movements of the earth’s axis
are factors in determining when earthquakes shall occur.

Reappointment—The Committee asks for reappointment and for the
confirmation of a grant of £100 from the Caird Fund.

MATHEMATICAL TABLES,

Report of Committee on Calculation of Mathematical Tables (Prof. E. H.
NEVILLE, Chairman; Prof. A. LopcE, Vice-Chairman; Dr. L. J.
Comrie, Secretary; Dr. J. R. Atrey, Prof. R. A. Fisuer, F.R.S.,
Dr. J.. Henperson, Dr. E. L. Ince, Dr. J. O. Irwin, Dr. E. S.
Pearson, Mr. F. Rossins, Mr. D. H. Sapier, Dr. A. J. THompson,
Dr. J. F. Tocuer, and Dr. J. WisHart).

General activity. —Six meetings of the Committee have been held, in London.
The grant of £50 has been expended as follows :

Calculations connected with the Bessel functions co 2

Fi(x), Fa(x), Fa(x), Fa(x) . a7, 19. 10
Calculations connected with the confluent hypergeometric

function . Io 0 Oo
Calculations Eonnesteds with. the Bessel functions Y,(x)

and Y,(x) for x = 6-o(o- any oO. , : F fa) 227 100"

Secretarial expenses. ‘ : ; p at Me 5HrOwro

270 REPORTS ON THE STATE OF SCIENCE, ETC.

Cunningham Bequest.—(a) The work on the table of reduced ideals and
primitive units in real quadratic fields has been continued by Dr. E. L.
Ince. It is hoped that the manuscript will be ready for the printer by the
end of this year.

(b) The printing by a photographic process of Prof. L. E. Dickson’s
tables of the minimum decompositions of the numbers 1-300,000 into fifth
powers has been put in hand. ‘This will constitute the Committee’s
Volume III.

(c) The Council has authorised the preparation and publication of
a volume containing all the prime factors of all numbers up to 100,000.

The calculations are being done voluntarily, in duplicate, one copy
by Mrs. E. Gifford, and the other by Miss E. J. Ternouth, of Reading
University, and Prof. A. Lodge.

(d) The purchase, for table-making, of a National Accounting machine
(formerly called the Ellis) has been authorised, and the machine is now on
order. It contains an eleven-column keyboard, printing mechanism, and
six adding mechanisms.

Bessel functions—The sub-committee formed to draw up a report on the
tables of Bessel functions which have appeared in the Reports of the Com-
mittee, with a view to the possibility of their publication in one volume, has
now completed the examination of these tables. Interim reports were made
during the session, and action was taken for the preparation of the Y func-
tions. ' The full report and recommendations of the sub-committee will be
considered during the next session.

The Committee has calculated, at the request of Dr. R. Stoneley,
47-figure tables of the functions F1(x), F-34(x), F:(~), F-2(~), for the range
x = 0:00(0:01)0-50(0-02)2-50(0-05)5-0(0-1)20-0.

The preparation of printer’s copy of ¥9(x) and 7;(x) to 10 decimals for
% = 0:000(0-001)16-00(0-01)25:00 has been completed, as has also copy of
8-figure values of J,(x) and I,(x) for x = 0-000(0-001)5-000.

The preparation of an 8-figure table of Y,(x) and Y,(«) for «=
0-00(0-01)16:00 has been begun, and will be carried to completion next
year.

Airy integral—The Committee has received a request from Dr. H.
Jeffreys for the tabulation of the Airy integral and its first derivative. It is
hoped that this may be done next year.

Confluent hypergeometric functions —The Committee has received a request
from Dr. R. Stoneley for certain calculations in connection with these
functions. The work is being put in hand by Dr. A. J. Thompson.

Publication —The Committee has expressed to the Council its desire for
the publication of the following material :

(1) The Legendre functions described in the last report ;

(2) The Bessel functions of orders +} and +? described in this report ;

(3) The Bessel functions ¥)(x), 7:(x), Io(x) and I,(«) described in this

report.

Reappointment—The Committee desires to be reappointed, with the
addition of Dr. J. C. P. Miller, and with a grant for general purposes of £100.

TERTIARY AND CRETACEOUS ROCKS 271

QUANTITATIVE ESTIMATES OF SENSORY EVENTS.

Interim Report of Committee appointed to consider and report upon the
possibility of Quantitative Estimates of Sensory Events (Dr. A.
Fercuson, Chairman; Dr. C. S. Myers, C.B.E., F.R.S., Vice-
Chairman; Mr. R. J. Bartiett, Secretary ; Dr. H. BANIsTER, Prof.
F. C. Bartuett, F R.S., Dr. WM. Brown, Dr. N. R. CAMPBELL,
Dr. S. Dawson, Prof. J. Drever, Mr. J. Guitp, Dr. R. A. Houstoun,
Dr. J. O. Irwin, Dr. G. W. C. Kaye, Dr. S. J. F. Porvport, Dr. L.
F. Ricuarpson, F.R.S., Dr. J. H. SHaxsy, Mr. T. Situ, F.R.S.,
Dr. R. H. Tuouress, Dr. W. S. Tucker).

THE Committee met on four occasions ; memoranda prepared by members
have been circulated.

The memoranda which have been circulated have dealt critically with
(a) the possibility of quantitative estimates of sensory events, (b) the mean-
ing of the term measurement in its application to the estimation of sensory
magnitudes, and (c) the validity of the modes of presentation and interpreta-
tion of the Weber-Fechner law.

The matters so raised and discussed have resulted in the resolving of
many doubtful points and in raising clear-cut issues of fundamental import-
ance, but it is evident that further discussion and research are necessary
before a satisfactory synthesis of opinion can be effected.

The Committee is agreed that (a) a critical résumé of past work on the
Weber-Fechner law, paying special attention to experimental conditions and
introspective reports, would be of great value ; and that (b) further experi-
mental work should be undertaken on the measurement of just noticeable
differences, equal-appearing intervals, and ratio estimates in the various sensory
fields, full use being made of modern physical instruments.

In furtherance of the above, at the suggestion of the Committee, work has
been commenced at Cambridge, at Cardiff and at Edinburgh, and it is hoped
that other psychological laboratories will be able to give assistance later.

The main work of the Committee is necessarily carried out by the
interchange of memoranda between its members, and the Committee desires
to record its indebtedness to the Council of the British Psychological Society
for their hospitality and for the assistance which they have given in the
duplication of the memoranda involved.

- The Committee asks to be reappointed, without grant.

TERTIARY AND CRETACEOUS ROCKS.

Report of Committee appointed to investigate Critical Sections in the
Tertiary and Cretaceous Rocks of the London Area and to tabulate
and preserve records of new excavations in that area (Prof. W. T.
Gorpon, Chairman; Dr. S.W. Woo.pripce, Secretary; Mr. H. C.
BERDINNER, Prof. P: G. H. Boswett, O.B.E., F.R.S., Miss M. C.
CrosFiELD, Mr. F. Gostinc, Prof. H. L. Hawkins, Prof. G.
HICKLING).

THE grant allotted to the Committee for 1932-33 was expended in investi-
gating the structure of a critical area south of the Lower Greensand

272 REPORTS ON THE STATE OF SCIENCE, ETC.

escarpment near Nutfield, Surrey. Here and eastwards at Tilburstow
Hill, Godstone, a number of outliers occur south of the main scarp. The
beds in several cases are highly inclined and much disturbed, and at first
sight a strong suggestion is conveyed of a major fault parallel to, but to the
south of, the main escarpment. Such a fault would lie in a known zone
of tectonic instability, and would form an important element in Wealden
structure. An alternative hypothesis attributed the outlying disturbed
masses to large scale slip-faulting of the type seen on many British sea-
coasts, as well as along the banks of the Panama Canal. A large number
of borings were made under the supervision of Mr. F. Gosling, B.Sc.,
F.G.S., and the evidence from these has been brought together in maps
and sections, which it is hoped will shortly be published. ‘The evidence
so far obtained is definitely opposed to the hypothesis of regional faulting,
but enables the detailed reconstruction of a structural arrangement con-
sistent with bodily slipping of portions of the former scarp-face. An
important contributory factor in the process here, and probably elsewhere, is
the flattening, or reversal of the general northerly dip, in the vicinity of
the present escarpment.

SEX PHYSIOLOGY.

Final Report of Committee on the Influence of the Sex Physiology of the
Parents on the Sex-ratio of the Offspring (Prof. J. H. Orton, Chazr-
man; Mrs. RutH C. Bisse, Secretary; Prof. A. M. Carr-
SAUNDERS, Miss E. C. HERDMAN).

Tue EFFECT OF ALTERED SEX PHYSIOLOGY OF THE PARENT ON THE SEX
RATIO OF THE OFFSPRING IN GUINEA-PIGS.

SOME years ago a series of experiments was carried out and yielded
extremely interesting results. Some male guinea-pigs each had one testis
removed when only a few weeks old. When they became adult they were
used for breeding, and gave offspring in the proportion of 299:16¢. As
there were more than 300 young, it seemed fairly certain that the proportions
were not due to chance.

An attempt has been made during the past three years to repeat these
experiments on a small scale, but the animals have bred so slowly that the
number of offspring is still too small to give a conclusive result. As they
are breeding so slowly it has been decided not to continue the experiments
during the coming year, but to wait until the animals can be kept under
more normal conditions. It is not proposed, therefore, to ask for any
further grant at the present time.

A grant of £5 was received last year and was used for the maintenance
of the stock.

Mrs. Bisbee wishes to express her gratitude to the Committee for the
financial help which she has received, and to assure them that the work
will be continued as soon as possible.

ZOOLOGICAL BIBLIOGRAPHY 273

ZOOLOGICAL BIBLIOGRAPHY.

Zoological Bibliography and Publication (Prof. E. B. Poutton, F.RS.,
Chairman; Dr. F. A. BaTHER, F.R.S., Secretary ; Mr. E. HERON-
Auten, F.R.S.; Dr. W. T. Carman, F.R.S., Sir P. CHALMERS
Mircuett, C.B.E., F.R.S.; Mr. W. L. Sciater).

Durinc the past year the Secretary has been consulted on various questions
of publication and has offered advice in the terms of previous reports by
the Committee.

A difficult question has been raised by the Entomological Society of the
South of England regarding the publication of papers reproduced by dupli-
cator or other methods than type printing. ‘The Society suggests that a
minimum limit of 500 copies should be fixed and that the papers should in
all other respects conform to the requirements of the International Rules
of Zoological Nomenclature (which are essentially the same as the condi-
tions laid down by your Committee), We do not think that any distinction
can be drawn between the various processes of multiplying copies, provided
that the results are reasonably permanent. The size of the edition must
be governed by ordinary economic forces and by the probable number of
people interested in the particular subject. It is important that the publica-
tion should be advertised ; an edition of 50,000 would be of little use if not
made known.

Attention is again drawn to the undesirability of mentioning the systematic
name of an animal in the title of a paper without any indication of the class
to which it belongs. Editors of publications in applied, economic, and
ecologic zoology would help their colleagues by insisting on closer adherence
to the accepted rules and methods of nomenclature.

It may assist editors and authors if we mention that the International
Rules of Zoological Nomenclature, as well as other information of use in
preparing papers, have recently been printed in the following :

Krejci-Graf, Karl. ‘ Scientific Nomenclature and the Preparation of
Papers.’ Geol. Surv. Kwangtung and Kwangsi. Special Publication.
XII. Canton. December 1, 1932.

Pearson, Joseph. ‘Ceylon Journal of Science. Instructions and Rules
to be observed by Authors and Editors.’ March 1933. Private circulation
only.

The Secretary has protested in Nature (vol. cxxxii, p. 102, July 15, 1933)
against the waste of time caused by the omission of page numbers from the
opening pages of chapters, articles, and so forth.

The Committee seeks re-appointment with the same constitution as last
year, and without a grant.

274 _ REPORTS ON THE STATE OF SCIENCE, ETC.

HUMAN GEOGRAPHY OF TROPICAL AFRICA.

Report of Committee appointed to inquire into the present state of Know-
ledge of the Human Geography of Tropical Africa and to make
recommendations for furtherance and development (Prof. P. M. Roxsy,
Chairman; Prof. A. G. OciLviE, O.B.E., Secretary; Prof. C. B.
Fawcett, Prof. H. J. FLeure, Mr. E. B. Happon, Mr. R. H.
Kinvic, Mr. J. McFarvane, Col. M. N. MacLeop, D.S.O., M.C.,
Prof. J. L. Myres, F.B.A., Mr. R. U. Sayce, Rev. E. W. Smiru,
Brig. H. S. L. WInTERBoTHAM, C.M.G., D.S.O.).

Past ACTIVITIES OF THE COMMITTEE.

THE Committee, which was first appointed after the Oxford Meeting of
the Association in 1926, was occupied during the first period of its work
in bringing its proposed activities to the notice of a wide circle of people
in Africa who are in a position to supply data. This was most effectively
done by the issue of a pamphlet of 46 pages, first printed in 1930 and re-
printed in 1931, containing: (1) An introduction setting forth the nature
of the gap in our knowledge of the material life of African natives, in so far
as it relates to the use of land and is directly affected by local environment ;
(2) a list of subjects upon which information is specially required ; and
(3) reprints of two essays of the kind which the Committee desired to receive
from residents throughout Africa, these reprints to be regarded as models.

This pamphlet was sent: (1) in bulk to the Governments of the various
British Colonies and Mandates in Tropical Africa, and was distributed by
them to their local officers, and (2) to a number of selected missionaries
and other residents. The response from members of the latter group has
been slight, but there is every indication that the interest of Government
Officers in various parts of Africa has been aroused. The Committee has
already been able to procure publication of an essay by Mr. L.H.L. Foster on
the Mlanje District of Nyasaland (Geography, 1932), and is now seeking pub-
lication for two reports from Tanganyika Territory, by Mr. G. D. Popplewell
and by Messrs. E. A. Leakey and N. V. Rounce respectively. Other docu-
ments have been received which, though not suitable for separate publication,
yet furnish much useful information. Among these are a paper by Mr. R. C.
Northcote on the Rungwe District of Tanganyika Territory, and reports
on specific points by officers of the Agricultural Department of Sierra
Leone. To all of these gentlemen the Committee gratefully acknowledges
its debt.

The Committee has further obtained co-operation in several of the
University Geography Departments in this country, especially with the
view of constructing population maps of the African Colonies.

NORTHERN RHODESIA.

While the Governments of all the Colonies have helped the Committee
by distributing the pamphlet, the Government of Northern Rhodesia

1 Arrangements have now been made by which copies of the pamphlet may be
obtained, price 7d., post free. from the Clerk, Geographical Association, Municipal
High School of Commerce, Princess Street, Manchester.

GEOGRAPHY IN DOMINION UNIVERSITIES 275

invited all the District Officers of the territory to submit reports. Twenty-
eight of these District reports have now been received by the Committee,
while only five remain to be sent in. Thus, by the acquisition of what
it is hoped will soon be material for a complete review of the human
geography of a large African territory, the Committee is enabled to enter
upon the second stage of its work, that of examining, collating and making
available to a wider circle the information so generously compiled by the
responsible officers on the ground.

The Committee gratefully acknowledges the courtesy extended to it
by the Government of Northern Rhodesia, and hopes to make the fullest
use of the results thus acquired as soon as possible, when it will make the
proper acknowledgment to the individual contributors.

FURTHER OUTLOOK.

The Committee having received certain reports, as above mentioned,
from other East African territories, hopes that the latter Colonies will in
the near future yield more comprehensive material. It seems likely that
this result may be hastened by the present visit to East Africa of Mr. S.J. K.
Baker, a former member of the Committee.

It is of course recognised that while the data now accumulating have
their chief value as contributions to knowledge of specific geographical
relationships, they will also possess considerable value to anthropological
and ethnological studies. The Committee therefore intends to establish
and maintain close touch with bodies which for any reason may be interested
in the material accumulated, such as the Royal Anthropological Institute,
the Royal Institute of International Affairs, and the International Institute
of African Languages and Cultures.

In short, it will be seen that the real work of the Committee lies before it.

REAPPOINTMENT AND EXPENSES.

The Committee therefore asks to be reappointed, with the addition of
the names of Mr. S. J. K. Baker, Dr. A. Geddes, and Mr. R. A. Pelham.
It asks for a grant of £5 to cover secretarial expenses in 1933-34, and it
intimates that any profits accruing from sale of the pamphlet will be handed
to the General Treasurer of the Association.

.}

GEOGRAPHY IN DOMINION UNIVERSITIES,

Report of Committee appointed to ascertain the place which Geography
occupies in the curricula of the universities in the various Dominions
of the Empire (Prof. C. B. Fawcett, Chairman; Dr. L. DuDLEY
Stamp, Secretary ; Dr. L.J. Burpee; Prof. F. DEBENHAM; Dr.C.A.E.
FENNER ; Prof. GRIFFITH TayLor ; Prof. J. H. WELLINGTON).

1. ACTIVITIES OF THE COMMITTEE.

Havinc collected preliminary suggestions from the members of the
Committee then in England, the Chairman and Secretary met and drew
up a draft. of a letter and questionnaire to be circulated to all universities
concerned. These drafts were circulated to the members of the Committee

276 REPORTS ON THE STATE OF SCIENCE, ETC.

for suggestions and approval. It was agreed to co-opt Dr. Benson to
help in New Zealand. Copies of the letter and circular as finally approved
by members of the Committee were then duplicated (Documents A and B
attached) and distributed as follows :—
(a) in bulk to Dr. L. J. Burpee for distribution to Canadian universities
and the collection of replies.
(6) in bulk to Dr. C. Fenner for Australia.
(c) in bulk to Prof. J. H. Wellington for South Africa.
(d) in bulk to Dr. W. N. Benson for New Zealand.
(e) in bulk to Prof. Griffith Taylor for the collection of comparable
details of the leading universities of the United States.
(f) individually by the Secretary to the universities of India, Singapore,
and Hong Kong.
(g) individually by the Secretary to the universities and university colleges
of the British Isles for the collection of comparable details.

An Interim report was presented in manuscript to the 1932 (York)
Meeting of the Association and contained details of the replies received
from South Africa, Australia, New Zealand, India, and the Far East, with
replies received from the British Isles and the United States for purposes
of comparison. The replies from Canada had not, at that time, been
received; and since the Interim Report certain other replies to the
questionnaire have been received from other parts of the Empire.

The sections which follow deal with the major parts of the British Empire
in turn.

II. Dominion oF NEW ZEALAND.

Dr. W. N Benson of the University of Otago, Dunedin, New Zealand,
who was co-opted a member of the Committee and collected the replies
to the questionnaire from his colleagues, summarises the position in New
Zealand as follows:

‘The four constituent colleges of New Zealand University are all con-
cerned with the same prescriptions and the differences between the replies
merely reflect different arrangements for dealing with the subject. The
prescriptions are contained in the New Zealand University Calendar,
Briefly Geography figures in the Entrance or Matriculation examination,
in the Entrance Scholarship examination requiring one or two years further
high school work. Examination of these prescriptions is conducted by
University teachers, almost invariably the Professors of Geography in
association with one or more assistants, usually University or Teachers’
Training College lecturers. Economic Geography is also taught by a
lecturer in the Department of Economics in each college, for the purposes
of the B.Com. degree only, such requiring only one, or sometimes two,
hours per week, unaccompanied by any laboratory work. Geolcgy in
its general aspects as a subject for the B.A. course, first year work only, is
taught in the Auckland and Wellington Colleges by the Professor of
Geology, associated with a lecturer from the Teachers’ Training College
in Auckland and a lecturer from the Economics Department in Wellington.
There has resulted from this the emphasis on the physical and economic
side, without (unless it be in Auckland) any special attention to the human
side. In the hopes of encouraging advanced study in Geography and the
appointment ofa teacher specialist in the subject, the University has approved
courses for a second and third year in Geography for the B.A., but as yet
provision for the teaching of such courses has not been made by any college.
The several replies summarised are thus :—

GEOGRAPHY IN DOMINION UNIVERSITIES 277

AUCKLAND: Professor of Geology and associate lecturers from the Teachers’
Training College are doing most of the B.A. first year Geography
course ; Professor J. A. Bartrum, M.Sc., F.G.S.; Lecturers, C. R.
Laws, M.Sc., and — Jones, B.Sc. (Training College).

WELLINGTON: Professor C. A. Cotton, D.Sc., F.G.S. (Department of
Geology); Miss Hilda R. Heine, M.A., Ph.D., for Economic
Geography.

CuristcHuRCH: R. S. Allan, M.Sc., Ph.D., Lecturer in Geology (not
giving instruction in Geography every year); G. C. Billing, Lecturer
in Economics Department, gives the Economic Geography course.

In addition, the giving of Economic Geography lectures in Auckland by
a lecturer in the Department of Economics should be noted.

“It is worthy of remark that it is not possible to take Geography as a
subject for the B.Sc. degree, nor to take both Geography and Geology as
subjects for the B.A. degree on account of the overlapping in Physical
Geography.’

Details of Auckland University College were supplied by Professor J. A.
Bartrum (Professor of Geology), details of Victoria University College,
Wellington, by Professor C. A. Cotton, and for Canterbury College,
Christchurch, by Dr. R. S. Allan (Lecturer in Geology).

III. COMMONWEALTH OF AUSTRALIA.

The replies from Australian universities were collected by Dr. Charles
Fenner, of the University of Adelaide. He summarises the position as
follows :

“The attached schedule discloses the replies to the questionnaire
submitted by the above Committee to the Universities of (1) Sydney,
(2) Melbourne, (3) Adelaide, (4) Brisbane, (5) Perth, (6) Hobart.

“Summing up the position it may be said that, except in one instance,
the teaching of Geography is not in an advanced position in the universities
of Australia. The exception is the University of Sydney, where a complete
and well-equipped department of Geography is in existence, carrying out
a four-year course of work, including Honours, branching into the faculties
of Science, Arts, and Commerce, and conducting research work.

“In other Australian universities there exist movements making for the
progress of geographical teaching ; these come mainly from three directions :
_ first, from departments of Commerce, which stress the need for the teaching
of Economic Geography ; secondly, from departments of Geology, where
it is felt that their physiographic teaching should develop into geographical
work ; and thirdly, from the public and private schools of the various
States, where teachers of geography feel the need for university teaching
and guidance.

“The movement towards the extension of geographical teaching from a
geological basis has advanced well in the University of Queensland, as
reported by Professor H. C. Richards, and also in the University of
Adelaide, where Sir Douglas Mawson has interested himself in the matter.
In the latter case Geography is at present a one-year Arts subject ; in the
former, progress has been held up on account of expense.

“In the Melbourne University the teaching of Economic Geography is
on asound basis, and there is some correlation with the Geology Department.
There is no geographical teaching in Perth, and only a one-year course in
Economic Geography in Hobart. Thus, apart from the University of

278 REPORTS ON THE STATE OF SCIENCE, ETC.

Sydney, no Australian university is doing geographical work at all com-
parable with that of the leading universities of Britain.’

IV. UNIon oF SoutH AFRICA.

Replies to the questionnaire from the Union of South Africa were
collected by Professor J. H. Wellington of the University of Witwatersrand,
Johannesburg. ‘The position is shown in the schedule.

V. THE DoMINION OF CANADA.

The replies to the questionnaire from Canadian universities were collected
by Dr. L. J. Burpee. Dr. Burpee summarises the position as follows :—

“It will be seen from the replies received that very little has yet been
done in this direction (i.e. the establishment of Geography, in the universities).
In the sense in which the question is meant, it must be said that so far
there is no Department of Geography in any Canadian university. It will
be noted that the University of British Columbia and the University of
Montreal both report a Department of Geography but it would seem that
for all practical purposes the situation is the same in these universities as
in Toronto and McGill and most of the other universities, where Geography
is more or less a course in the Department of Geology and the Department
of Economics. It will be noticed that from Professor Innis’ letter that
Toronto University has for some time been feeling its way towards the
establishment of a Department of Geography, but the time is not yet ripe.
I think the same situation applies to several other Canadian universities,
and probably after we have got through this period of depression some
progress may be anticipated.’

The actual position is shown in the attached schedule.

VI. INDIA AND THE Far East.

The questionnaire was sent to all the Indian and Far Eastern universities
(i.e. including Singapore and Hong Kong) and replies were received from
all those mentioned in the schedule.

VII. Summary.

For purposes of comparison, Professor Griffith of the University of
Chicago obtained replies to the questionnaire from a number of representative
universities in the United States.

It will be clear from the replies to the questionnaire that Geography does
not yet occupy the important position in the curricula of the universities
of the Dominions that it does in the universities of the Home Country,
or in the universities of the United States. In the universities of Australia
and New Zealand the subject is represented, and there is a remarkably
strong department in the University of Sydney. In South Africa the
subject is important, especially in the Universities of Witwatersrand and
Pretoria.

In India the subject is growing in importance ; there is a specially strong
department in the modern University of Rangoon.

The position in Canada, which cannot be said to have any full department
of geography in its several universities, is a remarkable contrast to the
United States and to the Home Country.

GEOGRAPHY IN DOMINION UNIVERSITIES 279

DocuMENT A.

Dear S1r,—On behalf of the Committee appointed by Section E (Geo-
graphy) of the British Association at its Centenary Meeting held in London,
September 23-30, 1931, to inquire into the position of Geography in the
universities of the Empire, we enclose a short questionnaire relative to the
position occupied by Geography in your University.

It will be of great assistance to us if you will be so good as to answer the
questions as fully as possible and also add any other information bearing
on this topic which you think would be of value.

(signed) C. B, Fawcett (Chairman).
L. Duprey Stamp (Secretary).

The Committee consists of the following : L. J. Burpee (Ottawa) ; W.N.
Penson (Dunedin) ; F. Debenham (Cambridge) ; C. B. Fawcett (London),
Chairman; C. Fenner (Adelaide); Griffith Taylor (Chicago, late of
Sydney, N.S.W.) ; L. Dudley Stamp (London, late of Rangoon), Secretary ;
J. H. Wellington (Johannesburg), with power to co-opt.

DocuMENT B.
Questionnaire.

(1) What is the position of Geography as a subject—
(a) in the Matriculation or other entrance examination ?
(6) in Intermediate or other pre-graduation examinations ?
(c) in the First Degree (Pass and/or Honours) and in what faculty or
faculties ?
(d) in Higher Degrees ?
(e) in other qualifications recognised or awarded by the University
(e.g. Diplomas) ?
(f) as part of the training for Degrees in other subjects ?
(2) (a) Is there a Department of Geography ?
(6) If so, in what faculty or faculties ?
(c) Is Geography independent or combined with one or more other
subjects in a joint Department ?
(3) What is the teaching staff in Geography? Please give names and
status.
(4) What, if any, members of the staffs of other departments teach
Geography ? Please give names and status.
(5) What proportion, if any, of the work takes the form of laboratory
work (in hours per week) ?
(6) Please give any other information which bears on the subject.

Replies should be sent as follows :—

From Canadian universities to Dr. L. J. Burpee, International Joint
Commission, Ottawa.

From United States universities to Prof. Griffith Taylor, University of
Chicago.
' From Australian universities to Dr. C. Fenner, University of Adelaide.

From South African universities to Prof. J. H. Wellington, University of
the Witwatersrand, Johannesburg.

From New Zealand institutions to Dr. W. N. Benson, University of
Otago, Dunedin.

REPORTS ON THE STATE OF SCIENCE, ETC.

280

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281

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REPORTS ON THE STATE OF SCIENCE, ETC.

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REPORTS ON THE STATE OF SCIENCE, ETC.

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REPORTS ON THE STATE OF SCIENCE, ETC.

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‘Sauphs 4 "yMeg —

296 REPORTS ON THE STATE OF SCIENCE, ETC.

EMPIRE SOIL RESOURCES.

Report of Committee appointed to co-operate with the Imperial Soil Bureau
to examine the soil resources of the Empire (Sir JouHN RussELL, O.B.E.,
F.R.S., Chairman; Mr. G.V. Jacks, Secretary ; Prof.C. B. Fawcett,
Mr. H. Kine, Dr. L, Duptey Stamp, Mr. A. STEvENs, Dr. 5. W.
Wootprincz, Dr. E. M. Crowruer, Dr. W. G. Oae, Prof. G. W.
ROBINSON).

THE Committee has secured the assistance of several noted geographers,
who are now engaged in collecting climatic and ecological data of the
different countries of the British Empire. Corresponding maps are being
prepared, and it is hoped that a fairly complete series will be ready by the
end of the year. The Committee has held one meeting, in conjunction with
its collaborators, at which progress was reviewed and a programme outlined
for the continuation of the work.

STRESSES IN OVERSTRAINED MATERIALS.

Interim Report of Committee on Stresses in Overstrained Materials (Sir
Henry Fow ter, K.B.E., Chairman; Dr. J. G. Docuerty, Secretary ;
Prof. G. Coox, Prof. B. P. Haicu, Mr. J. S. Witsown).

Tue following interim report is submitted :

“The work of the Committee on the yield point and on stress distributions
in the initial stages of plastic yield in a variety of cases is proceeding. It is
hoped that a full report of these experiments will be submitted in 1934.’

The Committee ask to be reappointed for another year.

ELECTRICAL TERMS AND DEFINITIONS.

Report of Committee on Electrical Terms and Definitions (Prof. Sir J. B.
HENDERSON, Chairman; Prof. F. G. Barty and Prof. G. W. O.
Howe, Secretaries; Prof. W. Cramp, Prof. W. H. Eccres, F.RS.,
Prof. C. L. Forrescur, Sir R. Grazesroox, K.C.B., F.RS.,
Prof. A. E. KENNELLY, Prof. E. W. Marcuant, Sir FRANK SMITH,
K.C.B., C.B.E., Sec. R.S., Prof. L. R. WILBERFORCE).

IN last year’s report reference was made to the undesirability of making
a technical report pending the decision of the Symbols, Units and
Nomenclature (S.U.N.) Commission of the International Union of Physics
which had just been constituted.

This Commission has reported, and this report goes a long way to
remove the difficulties our Committee had encountered. As further reports
of the above Symbols, Units and Nomenclature Commission are expected,
we ask for reappointment.

The Committee’ ask for reappointment without grant.

EARTH PRESSURES 207

EARTH PRESSURES.

Eighth Interim Report of Committee on Earth Pressures (Mr. F. E.
WENTWORTH-SHEILDS, Chairman; Dr. J. S. Owens, Secretary ;
Prof. G. Coox, Mr. T. E. N. Farcuer, Prof. A. R. Futon,
Prof. F. C. Lea, Prof. R. V. SourHwett, F.R.S., Dr. R. E,
STRADLING, Dr. W. N. Tuomas, Mr. E. G. WaLkKer, Mr. J. S.
WILson).

SINcE the Committee’s last report, a meeting was held at Garston on
June 22, 1933, when the Committee had the advantage of meeting Prof.
Jenkin and hearing from him an account of the work he has done during
the past year. A short report from him is appended.

His work, of which the Committee would again express high appreciation,
has been of great importance. The work has consisted almost entirely of
investigations and experiments on the mechanical properties of clay, the
experiments being carried out with apparatus devised by him. It is hoped
that these investigations and experiments will lead to an understanding of
the fundamental principles of the mechanics of clay, and that it will then
be possible to estimate the forces exerted by clay, used, for instance, as a
.foundation of a structure or as backing for a retaining wall.

The Committee would endorse Prof. Jenkin’s conclusion that, although
no definite results have been reached so far, the experiments are working
well, and a promising theory is being worked out.

They recommend that his and their work be carried on for a further
period.

REPORT FOR THE BRITISH ASSOCIATION EARTH PRESSURES COMMITTEE.

May 15, 1933.

Since my report dated July 1, 1932, the work on the mechanics of clay has
been carried on continuously.

The filter press has been improved so that samples of air-free clay can
now be prepared under any load up to 1,000 Ib. (100 lb. per sq. in. in the
largest cylinder). The pressure/moisture curve for China clay has been
determined with this press. The result was quite unexpected : the mois-
ture left in the clay is found to depend much more on the way the clay
is handled than on the pressure. Rotating the piston in the press greatly
reduced the water content, and rotation in alternate directions produces a
still greater reduction in the water content.

An apparatus for measuring conjugate pressures on clay cylinders has
been made and a full series of tests with it carried out. The results were
again unexpected. It is found that the hydraulic conjugate pressure is
transmitted through the clay in a few seconds by the water in the clay, so
that it has no effect; the compression strengths are not altered by the
_ presence of the hydraulic pressures. Tests were made with positive con-
jugate pressures up to about 1 atmosphere, and also with negative pressures
approaching 1 atmosphere.

This apparatus has also been used to measure the compression strengths
of clays of all moisture contents, and a complete curve of strength against
moisture content has been plotted.

To extend this curve into the region of partially dry clay—i.e. clay into
which air has penetrated—a simple compression testing machine has been

M

298 REPORTS ON THE STATE OF SCIENCE, ETC.

made suitable for applying the larger loads needed. ‘The tests with this
apparatus are almost complete.

To enable automatic records of compression load/strain curves to be
obtained, and particularly to enable hysteresis loops to be recorded, the
shear apparatus, referred to in the last report, has been slightly added to.
With the new additions a very large number of records have been made on
clays of various water contents, and some particularly interesting experi-
ments have been made on clay tested under water and under oil. This
‘hysteresis loop apparatus ’ produces records on smoked glass, which are
varnished and stored.

At the present time a full investigation is being made on shear strengths
in the shear apparatus. One of the many difficulties is that water is often
extruded from the clay during the test. The cause of this extrusion is the
point under investigation at the moment.

A good deal of thought and time has been spent on the design of a kneading
apparatus which is wanted to mix the clay produced in the press so as to
destroy any possible lamination, Some interesting results have been
obtained, but no method has yet been found by which clay can be kneaded
without introducing air.

All these experiments are valueless unless they lead to the understanding
of the fundamental principles of the mechanics of clay. ‘They are sufficient
to show that none of the existing theories are tenable, and they all appear at
present to point to an explanation which is fundamentally very simple,.
though disguised by many subsidiary effects. All the work at present is
aimed at checking the accuracy of this hypothesis. ‘Though there are many
difficulties, none of them appear to be insuperable. The great trouble
of endless creep has not appeared in any of the tests, all of which give
definite results.

Conclusion—Though no definite results have been reached so far, the
experiments are working well, and a promising theory is being worked out.

C. F. JENKIN.

BRITISH SOMALILAND.

Report of Committee appointed to make a preliminary survey of some reported
archeological sites in British Somaliland (Dr. A. C. Happon, F.R.S.,
Chairman; Mr. R. U. Sayce, Secretary; Prof. J. L. Myrss,
F.B.A.).

THE Committee was appointed at the Bristol Meeting in 1930, to enable
Dr. L. S. B. Leakey to visit Somaliland and make preliminary examination
of some reported archzological sites. Dr. Leakey was, however, prevented
from going to Somaliland, either on his journey to Kenya Colony or on
his way home; and has accordingly refunded the grant.

DERBYSHIRE CAVES 299

DERBYSHIRE CAVES.

Eleventh Interim Report of Committee appointed to co-operate with a
Committee of the Royal Anthropological Institute in the exploration of
caves in the Derbyshire district (Mr. M. C. Burxirr, Chairman ;
Dr. R. V. Fave.t, Secretary ; Mr. A. LESLIE ARMSTRONG, Prof. H. J.
FLeurE, Miss D. A. E. Garrop, Dr. J. WILFRID JAcKsON, Prof. L. S.
Pater, Mr. H. J. E. Peake).

No new excavation work has been undertaken by the Committee during
the current year, but the excavation of the Pin Hole Cave, Creswell Crags,
has been steadily advanced by Mr. Leslie Armstrong, F.S.A., who reports
as follows:

* During the autumn of 1932 work was concentrated upon the depressions
in the floor of the passage on the east side of the main chamber, referred
to in the report for 1932. Removal of the breccia over the whole area of
_ the passage and the trefoil-shaped terminal chamber revealed four large cavities
in the rock floor, one of which coincided with the width of the passage and
extended 7 ft. along it. ‘These were entirely filled with cave earth to a depth
of 2 ft. 6 in. overlying sterile red sand. The cave earth was of Mousterian (1)
age and yielded examples of the usual fauna, of which the most interesting
specimens are the greater portion of the skull and lower jaw of a young
mammoth with complete dentition, and two large fragments of the lower
jaw of giant deer. Human occupation of the large cavity was demonstrated
by a small but well-preserved hearth and the presence of a stone pounder,
animal bones (split and charred), and crude artifacts of quartzite and crys-
talline stalagmite. Similar tools were recovered from the smaller cavities
at the rear of the chamber. The most important finds in this level were
several worked bone tools, including a bone knife and two awls. The red
sand which underlies the cave earth was removed to a depth of 2 ft. and
carefully sieved but, with the exception of the uppermost layer, proved to
be entirely sterile and to have been introduced by water—probably during
the original formation of the cave.

“Upon completion of the work in the east passage attention was turned
to the large inner chamber of the cave, where operations had been suspended
at the 12-ft. level in order to facilitate the excavation of the passage. This
has now been completely excavated to the base—a total depth of 17 ft., of
which the lowest 1 ft. 6 in. was entirely sterile and consisted of red sand,
similar to that found in the passage cavities and previous sections of the
main cave.

-* The layer of fallen slabs which, throughout the cave, has so consistently
marked the division between the Mousterian (1) and Mousterian (2) levels
was found to be exceptionally thick and to include several massive slabs
of tabular limestone. The underlying cave earth (Mousterian (1) in age)
was also interspersed throughout by rocks and fragments of limestone,
many of them of large size and entailing considerable labour in their removal,
despite the disintegration which is common to all rocks and also to the cave
walls at this level.
~* The presence of so many rocks no doubt rendered this portion of the
cave unsuitable for general occupation, and, in consequence, the remains
recovered there in the Mousterian (1) zone have been less numerous than
elsewhere in the cave. \'They include, however, a superb side scraper of
flint and a number of quartzite fragments, split bones, etc.

300 REPORTS ON THE STATE OF SCIENCE, ETC.

‘Work is now proceeding at the rear of the main chamber, where the
width of the cave gradually contracts to a mere passage. It is hoped that
the section under examination will be excavated down to the base level
before the proposed visit to the cave by Section. H during the forth-
coming meeting at Leicester, in which case the complete stratification of the
cave deposits, 17 ft. in thickness, will be exposed to view.’

Since the York Meeting, the bone upon which a masked human figure
is engraved, and also the engraved mammoth ivory lance point, have been
presented to the British Museum. ‘The most important artifacts and a
characteristic group of associated objects, faunal remains, etc., have been
placed in the County Museum, Derby, in accordance with the decision of
the Committee.

The Committee desires to be reappointed, and makes request for a
further grant to enable the work at Creswell to be completed.

M. C. Burkitt, Chairman.
R. VERNON FavELL, Secretary.

DISTRIBUTION OF BRONZE AGE IMPLEMENTS.

Report of Committee appointed to report on the Distribution of Bronze
Age Implements (Prof. J. L. Myres, F.B.A., Chairman; Mr. H.J.E.
PEAKE, Secretary; Mr. A. Lestig ARMSTRONG; Mr. H. BaALrour,
F.R.S.; Mr. L. H. DupLey Buxton ; Prof. V. GorpoN CHILDE;
Mr. O. G. S. Crawrorp ; Prof. H. J. FLeure ; Dr. Cyrit Fox).

IT is now twenty years since this Committee was appointed at the
Birmingham Meeting in 1913. _ Hitherto the Committee has been engaged
in compiling an illustrated card catalogue of all.the ‘ Metal objects of the
Bronze Age’ in museums and private collections in the British Isles, and
it is able to report that, with insignificant exceptions, all the specimens
in England and Wales have been drawn, measured and described, and it is
hoped that by the time that the Association meets in Leicester all the
cards will have been stored in the drawers of the cabinet, which is being
housed for the Association by the Society of Antiquaries.

At an early date it was found that if strict uniformity was to be preserved,
all the cards should be prepared by one draughtsman. For this purpose
the services of Mr. C. H. Howell, were engaged, and retained until.a few
years ago, when the work, then nearing completion, became too intermittent
to necessitate the services of a whole-time officer. Since then the cards
have been prepared by Miss L. Chitty and Mrs. Michell-Clarke. While
the funds necessary for the remuneration of these draughtsmen have been
partly supplied by donations from generous patrons, a large part has been
received from grants made to the Committee by the Association. The
balance from these grants became exhausted before the end of 1932, since
which date Mrs. Michell-Clarke has very kindly completed the work of
drawing the specimens at the British Museum free of charge. Thus, ‘the
Committee believes, it has full information respecting all the metal objects
of the Bronze Age in England and Wales, excepting the specimens of
foreign origin in the British Museum, the Ashmolean and the Museum at
York. In addition, it has a complete series of cards from the Isle of Man
and the Channel Islands, cards for the majority of the specimens in Scotland

BRONZE AGE IMPLEMENTS—KENT’S CAVERN 301

and of a considerable number from Ireland, as well as of those in the
Harvard Museum and of the early specimens in the Museum of Copenhagen.

When the catalogue was first projected, the Committee hoped that, with
international co-operation, it would have been possible to extend this
catalogue so that it would cover the whole of Europe and the adjacent
lands. _With a view to thus widening the scope of this work, the Secretary
attended a Meeting of the Association Frangaise at Le Havre in July 1914,
where he had an opportunity of bringing the matter to the notice of its
Anthropological Section. ‘Though much interest in the project was
expressed, the mobilisation of the French army on the following day
prevented for a time any help from this direction. Last year the Secretary
brought the matter before the International Congress for Prehistoric and
Protohistoric Sciences, and took representatives of France, Germany and
other countries to see the catalogue. So far, however, no movement for
extending the work upon the continent has been apparent.

The Committee asks to be reappointed, to make recommendations
for the maintenance of the catalogue and for future work.

The Committee has considered the situation resulting from the virtual
completion of the catalogue for England and Wales, and for the consequent
need for a change of procedure in order to deal with accessions for the
future. Without such provision: the’ catalogue will. rapidly become
antiquated. The catalogue is now housed by the Society of Antiquaries,
but without provision for accessions ; and it does not seem likely that the
Society of Antiquaries would make such provision.

The Committee recommends that the best permanent repository for the
catalogue, and for the incompleted records for Scotland and Ireland, would
be the British Museum, provided that arrangements can be made for
systematic record of accessions. In the event of an independent survey
being made of the bronze implements of Scotland and of Northern Ireland,
the Committee recommends that items should be duplicated for exchange
between the national catalogues of those countries and the Committee’s
catalogue.

The Committee recommends that if this destination of the catalogue is
approved, the Chairman and Secretary should be authorised to discuss the
matter with the Director of the British Museum, and to report to the
‘Organising Committee of Section, H.

KENT’S CAVERN, TORQUAY.

Report of Committee appointed to co-operate with the Torquay Natural
History Society in investigating Kent’s Cavern (Sir A. Keiru, F.R.S.,

Chairman ;, Prof. J. L..Myres, F.B.A., Secretary; Mr. M,. C.
Burkitt, Dr. R. V. Favett, Mr. G. A. Garritt, Miss D. A. E.
). Garrop, Mr. LacalLue).

Tue following report has been received from the excavators, Messrs. F.
‘Beynon and Arthur H. Ogilvie :

__ ‘Excavation in the vestibule adjoining the northern entrance to Kent’s
Cavern was begun on October 3, 1932, and on April 24, 1933, was adjourned
to the next winter season.

_ “Work began by digging a trench 24 ft. long by 3 ft. wide alongside the

302 REPORTS ON THE STATE OF SCIENCE, ETC.

eastern wall of the chamber up to the entrance door. The surface of the
present floor there is 5 ft. 9 in. below the level of the original granular
stalagmitic floor, and the trench attained a depth of 1 ft. 6 in. at the inner
end up to 5 ft. at the entrance, the depth being determined when bed-rock
was reached. After sorting all excavated material this trench was refilled,
and three other wide trenches at right angles to the first were made, begin-
ning at the entrance to the cavern transversely across the passage way. Each
portion was filled up as soon as bed-rock was encountered, that imme-
diately inside the door being 7 ft. deep, the next 8 ft., and the third 4 ft. 3 in.
deep. It is interesting to note that the foregoing shows that the opening
into the cave at this point must have been at least three times the height that
it appeared when operations were begun early last century.

‘ Specimens of the usual cave fauna were found, including a right ramus
of the lower jaw of a hyena, with its condyle and lower border ungnawed ;
it is most unusual to find one in this state in Kent’s Cavern, as the hyena
always seems to have left as little as possible of the remains of his deceased
relatives.

‘ The discovery of the bony base of a rhinoceros horn is also of interest.

* Artifacts found included a fine bone awl and two similar) but less
noticeable specimens ; also small tines of deers’ antlers which seem to
have been used as borers. Flint flakes and chips were met with occasionally,
and encourage the belief that more finished flint-work, of which they are
the remains, will be found not far away next season.’ (Signed) F. BEYNON,
ARTHUR H, OGILVIE.

The Committee asks to be reappointed, with a small grant for the employ-
ment of a labourer to remove excavated material after examination. The
expenditure on labourer’s wages during the period covered by this report
amounted to £8 13s. 9d., of which £5 was met by the British Association’s
grant.

SUMERIAN COPPER.

Fifth Interim Report, by Dr. C. H. Descu, F.R.S., of Committee appointed
to report on the Probable Sources of the Supply of Copper used by the
Sumerians (Mr. H. J. E. Peake, Chairman ; Dr. C. H. Descu, F.R.S.,
Secretary ; Mr. H. Batrour, F.R.S.; Mr. L. H. DupLey Buxton ;
Prof. V. GorDON CHILDE; Mr. O. Davies; Prof. H. J. FLeure;
Sir FLINDERS PETRIE, F.R. S.; ty eagle RASTALL).

SINCE the publication of the last Report the analytical work of the Committee
has been transferred from the University of Sheffield to the National
Physical Laboratory. Specimens have been received from a number of
sites, together with a few ores. ‘The presence of arsenic in relatively high
proportion in several objects of early date has made it necessary to regard
this, like nickel, as a key element, which should assist in the location of the
source of the original copper. Unfortunately, the information as to the
actual composition of copper ores in the regions now being studied is very
scanty. As a rule, the statements in works of reference, and even in
geological monographs, are confined to a record of the occurrence of copper,
together with a figure expressing the average richness of the ore, with
statistics of production where the mine has been recently worked. It is

SUMERIAN COPPER 303

rare to find any mention of the presence of accessory elements. Such
specimens as have been received for examination, except for the native
coppers described in the First Report, have been from deep-seated deposits
of pyrites, whilst the ancient copper was undoubtedly derived mainly from
oxidised outcrops. Some specimens have proved to be slags from compara-
tively modern workings. The search for ores is being pursued, and the
Committee is indebted to Sir Arnold Wilson for his assistance in procuring
them and in advising as to possible sources. Arsenical copper ores, some-
times containing nickel, are found in Armenia, south of Lake Van, and in
Anatolia, at Yenikoi, south of the Sea of Marmora, whilst the ore at
Kastamouni, near to the Black Sea, is known to contain nickel. The known
occurrences have been mapped, and the region within which such mixed
ores, containing both arsenic and nickel, may occur appears to form a band
extending through Anatolia, Armenia and Azerbaijan, but sources farther
afield cannot at present be excluded.

A piece of thin metal from Professor Langdon, from the 1930 excava-
tions at Kish, reported as of date 3200 B.C., gave 95°17 per cent. copper,
0:08 nickel, 4-60 arsenic, and 0-15 iron. This proportion of arsenic is
unusually high. ‘Two objects of early date from Ur were received from the
British Museum for micrographic examination, having a core of uncorroded
metal. One proved to be a copper and the other a bronze, the structure
showing that the former had been hammered and slightly reheated after
casting, whilst the bronze was in the cast condition. Analyses :—

Copper. Tin. Nickel. Arsenic. Lead.
Spear. U 12239 BMLIII . 97:2 0:56 1°36 _- trace
Axe. U12098 BML XVI . 87-93 11°65 0'20 — 0:22

An arrow head from Anau, obtained from the Hermitage Museum at
Leningrad, from its Director, through the good offices of the Foreign Office,
was accidentally omitted from an earlier Report. A core of unoxidised
metal was present, and the composition was :—

Copper, 96°85. Tin, 2:35. Iron, 1°25.
Nickel, arsenic and lead were absent: ‘The object was found in the North
Kurgan, but the layer in which it occurred was not indicated.

An analysis has been received from Philadelphia of the copper spearhead
found by Mr. Woolley at Ur below the ‘ Flood ’ level, and described as
copper. The copper found was 99:69 per cent., with 0°16 arsenic, 0-01
iron, and 0:12 zinc, without a trace of nickel, tin, or silver. The zinc
reported must be regarded as doubtful. The writer at one time found zinc
in a number of specimens, which was at last traced to the presence of that
metal in the glass vessels used for analysis.

The largest number of specimens examined has come from the excava-
tions of the Oriental Institute of Chicago at Tell Asmar and Khafaje, sent
by Dr. H. Frankfort, to whom the Committee is indebted for a grant of
£20 to supplement that received from the Association. The bronze ‘dagger
which appears first on the list is of special interest, since it still held the
remains of an iron blade, analysis showing that this iron is of terrestrial
origin, and not, as in the case of other early iron objects, examined by the
Committee, forged from a meteorite.

A portion of a spearhead from Nineveh, submitted by Mr. Mallowan,
although completely oxidised, proved to be of pure copper, tin and nickel
being completely absent, whilst the minute quantity of iron found (0-15 per
cent.) may well have been derived from the soil.

A batch of specimens has been received recently from Dr. H. H. von der

304 REPORTS ON THE STATE OF SCIENCE, ETC.

Osten, Field Director of the excavations of the Oriental Institute of Chicago,
at Alishar Héyiik, in Anatolia. The analyses, so far as completed, are
included in the table.

An Egyptian razor of the Fourth Dynasty was received from Sir Robert
Mond. This thin razor, in very perfect preservation, had all the appearance
of being of copper, but the analysis showed it to be atrue bronze. Determina-
tions of hardness showed that the edge had been hardened by severe
hammering. Analysis :—

Copper, 88:5. Tin, 8-5. Iron, 1:8. Lead, 0-3. Nickel, o-or.

A little slaggy matter was present.

Mention may be made of a few analyses published elsewhere. Dr. C. F.
Elam has examined five objects from Mr. Woolley’s finds at Ur (F. Inst. Met.,
1932, 48, 97) and found two objects from the earliest levels to be true bronzes,
whilst the later specimens contain either no tin, or a small and variable
quantity. This is in accordance with our own observations. The nickel
content recorded is mostly higher than that found by us, but is of the same
order. Sir Harold Carpenter has examined an Egyptian axe head of early
Dynastic age, this being a large object, weighing over three pounds,
Analysis (Nature, 22 Oct., 1932) :—

Copper, 97°35. Nickel, 1:28. Arsenic, 0:49.
Lead, 0°17. Tron, 0:15. Manganese, 0-06.

The remainder being oxygen. Manganese is known to be associated with
copper in Egyptian ores.

In the table which follows, the highly oxidised specimens have not been
re-calculated, the reason being that the amount of earthy matter present is
sometimes so large as to make it uncertain whether some of its components
are to be attributed to the metal, whilst other specimens contain sulphur,
derived from the ore, and present in the metal as sulphide. This sulphur
has not been determined, but its presence is noted. In view of the high
proportion of sulphur in many of the objects from Mohenjo-daro in the
Fourth Report, specimens of the soil were obtained from Mr. Mackay,
with the object of determining whether this sulphur was derived from the
soil. ‘Two samples were received, labelled ‘' Top of mound ’ and ‘ Lowest
levels ’ respectively. Neither contained any sulphide, and the total quantity
of sulphate in the lower layer was only 0-16 per cent., that in the upper
layer being 1°92 per cent. The sulphur found in the specimens had,
therefore, come from the ore. In the case of the Tell Asmar specimens,
a core of uncorroded metal is: sometimes present, in which sulphide may
be detected under the microscope. It does not follow that the pyritic ores
were deliberately smelted ; it may have been that the outcrop ores were
more or less contaminated by sulphides.

Tell Asmar, Pre-Sar- Ar-
gonid hoard. Copper. Tin. Nickel. senic. Lead. Iron.
Bronze dagger . 1080 88:61 7°60 0°67 trace 0:94 0°46*
Vase . 4 . 105t 85-51 Oo 0°02, 0°05 0°36) 5 —
Vase . : » 1085 85°53 0 0:07 07°06 0:99. —
Tell Asmar, Akkadian.
Lump oringot . 764 Q5°OI 0 0'62 0°25 Oo — ft
Implement . Sige Meera <o 0°13 0°67 ‘i
Wire bangle . . 1239 93:96 o O'II ovr!
Arrow butt . f 559 87°48 0°74 0°32 1°57

* Some oxide. + Much sulphur.

SUMERIAN COPPER—MECHANICAL ABILITY 305

Ar-

Tell Asmar, Early Dynastic. Copper. Tin. Nickel, senic.Lead. Iron.
Dagger blade . 1329 90°82 2°63 0°33 O°15 0 O°I5
Sickle blade . sb Jgagx -/88"'rTii0 ° 2°23. 0 0°40
Arrow butt . . 1048 61°50 oO 0736. 0°37 0 —
Arrow butt . . 1097 70'0 trace 0°39 0°86
Rolled pin. . 1038 95°49 0 0°30 1:27 10 1°30
Rolled pin . ’ 986 87:81 0 0:90 2°08 Oo 1°04

Khafaje, Early Dynastic.

Dagger blade . 1296 49°82 0 6°29 0°94 022 °° —
Rolled pin . epAOR. 520570, 10 ° ° trace
Rolled pin . 1 187 77°98 o trace 0°22 0

Lump. : 3 152. 78°73 6°31 0°22 0°90 0

Alishar Héyiik, Anatolia,
Copper age and transt-
tion period.
e—700 58:12 4°82 0°04 0°14 1°22
e—833 61°36 10°8 o751 0°03 0
e—o963 60°52 0°76 trace orII 0°40

+ Much sulphur.

MECHANICAL ABILITY.

Final Report of Committee appointed to inquire into the factors involved in
Mechanical Ability (Dr. C. S. Myzrs, C.B.E., F.R.S., Chairman ;
Dr. G. H. Miss, Secretary; Prof. C. Burt, Dr. F. M. Earte,
Dr. Li. Wynn Jones, Prof. T. H. Pear).

ARISING out of the work reported to the Association by the Committee
on Vocational Tests in 1931, the present Committee arranged for a thorough
revision and statistical examination of the results to be made. As an
outcome of this work the need was apparent for a further examination of
the routine manual factor which plays an important part in the process of
repetitive manual operations.

I. SuITABILITY OF MEASURES.

Reliability.—The suitability of the measures upon which the conclusions
of this report are based was carefully investigated. The reliability of the
‘ mechanical ’ tests (assembling and aptitude), as indicated by their inter-
correlations, was in the neighbourhood of 0-6 to.o:7. ‘That of the routine
tests, based on the correlation of one test with a general repetition, varied
from 0-52 to 0-91. The reliability of the ‘intelligence’ tests, based
on the correlation between the sum of the odd sub-tests and that of the
even, varied from 0:8 to 0°9.

The intercorrelation of each ‘trial’ with the other trials constituting
the test was examined in the data on the routine tests obtained from the
adult subjects. The figures indicated that the reliability of manual tests
depended primarily on the number of repetitions (or ‘ trials ’) rather than
upon the complexity and length of the ‘trial’ itself. About the same
degree of ‘ reliability ’ could be expected from a given number of trials,

M2

306 REPORTS ON THE STATE OF SCIENCE, ETC.

irrespective of the length of the operations that are being tested, and which
constituted the ‘ trial.’

The figures also showed that, so far as the first five trials that constituted
these tests were concerned, one ‘ trial’ was about as reliable as another.
A similar result was observed during the much longer practice period, for
it was found that the reliability of the ‘test’ was much the same from
one day to another, irrespective of the stage of the subjects’ practice.
Generally, the tests measured ‘ initial’ ability to about the same degree
of accuracy as they predicted ability after practice.

Little difference in reliability was observed between the adults and
elementary school subjects.

Incentives—The correlation between the scores made at the various
tests, and estimated ‘incentive,’ proved to be negligibly small. The
results which we have now to examine can, therefore, hardly be explained
on the basis of differences in incentive.

Il. THe SpeciaL ABILITIES (OR GROUP-FACTORS).

The Mechanical Factor.—Having secured reliable measures of ability, our
next step was to determine the intercorrelations of all the tests in the
case of each group of subjects tested (i.e. the ‘ adult ’ group, and the several
elementary school groups). It was at once evident from these correlations
that the data tended to fall into three groups, viz.: (i) a ‘mechanical’ group
consisting of the mechanical aptitude tests and the mechanical assembling
tests ; (ii) a routine (or ‘manual’) group composed of the routine assembling
and stripping tests, and the simple manual tests, and (iii) a general
intelligence group consisting of the tests and estimates of intelligence, and
general school subjects.

The next step was to determine, by Spearman’s method of tetrad-
differences, how far these observed differences in the correlation coefficients
are due to chance, or to differences in the degree of correlation which all
of the other tests showed with the intelligence group. The application of
this criterion indicated that although the general positive correlation running
throughout the data could best be ascribed to a general factor common to
all, there were also present group-factors, tending to produce a closer
relationship between members of the same group than could be accounted
for by this general factor.

To determine more precisely the location and range of the group-factors,
the influence of the general factor was next statistically eliminated and the
tetrad-difference criterion was then applied to the resulting specific
correlations.

It is impossible to present here the numerous correlation tables examined
in the course of the analysis. It must suffice to say that the following
conclusions were clearly indicated’:

(1) The specific intercorrelations of the ‘mechanical’ group: were
best explicable by a single group-factor common to both the ‘ aptitude’
and the ‘ assembly’ tests. This seemed most reasonably identified with
the mechanical factor (‘m’) which was disclosed in the aptitude type of
test in a previous research, and whose presence was thus confirmed in the
present research, and shown, for the first time, to be present in suitable
tests of the mechanical assembling type.

(2) The mechanical aptitude type (which, it will be remembered, involved
no manual activity) were more highly saturated with the mechanical group-
factor than were the assembling type, and therefore provide better measures
of this special ability.

MECHANICAL ABILITY 307

(3) It was definitely established that the group- -factor in the * mechanical ’
group was not the same as the group-factor in the routine ‘ manual ’ tests.

The Routine Manual Factor.—Statistical analysis of the manual tests
along similar lines indicated that :

(1) The specific intercorrelations of the routine ‘manual’ assembling
and stripping tests, and the simple manual tests, could be best explained
by a single group-factor.

(2) This routine (or ‘ manual’) factor was clearly distinguishable from
the ‘mechanical ’ factor seen in the mechanical aptitude and mechanical
assembling tests.

(3) In general, the more complex assembling tests were more highly
saturated with this factor than were the simpler manual tests.

(4) Where the tests were both very simple and very similar (such as
screwing and unscrewing the turnbuckle), small additional factors common
to the pair of tests concerned, and to these only, were observed.

The ‘ Abilities’ in Assembling Work.—The independently measurable
‘ abilities ’ or ‘ group-factors’ in assembling work were thus found to be
(i) amechanical factor, associated with the solution of a mechanical problem ;
(ii) a routine manual factor associated with the manual activity involved
in this work ; and (iii), to a less extent, general intelligence. As the work
assumes a routine character the mechanical factor tends to disappear.
There was little evidence of the routine factor in the mechanical assembling
operations. In these the manual activity involved appears to function
specifically, rather than as a group-factor.

The Organisation of Manual Activity.—The more complex forms of
manual activity appear to depend on a broader and more important group-
factor than earlier work on simpler manual tests would lead us to suppose.
As the operations become simpler they depend less upon this common
factor and more upon factors specific to the particular operation. ‘The
measurement of this group-factor, in relative independence of other factors,
as provided by suitably constructed tests, would seem to be essential
wherever vocational guidance or sélection in the sphere of manual activity
is in question.

III. THe MeEntTat Processes IN MANUAL ACTIVITY.

The analysis divides into two parts. The first attempts to elucidate the
cognitive processes involved in the solution of the mechanical problem
which accompanies certain forms of manual activity such as that of the
mechanical assembling operations. It thereby extends to manual activities
the analysis of mechanical aptitude which the writer has already described
in a former work.. In the former analysis the problems were of a different
kind and were uncomplicated by manual activity. The present extension
of the analysis to include manipulative operations throws light on another
large class of engineering occupations.

The analysis also includes an examination of the processes underlying
the cognition of shape, and the relation of these to drawing and design.
The results are therefore of vocational interest wherever the worker is
called upon to deal with spatial material.

_ The second part of the analysis deals with those manual activities which
involve no special mechanical problem and which we termed routine
assembling operations. It attempts to unravel the cognitive processes
associated with the manual factor which our objective measurements
disclosed. It includes an account of the kind of knowledge that is acquired

308 REPORTS ON THE STATE OF SCIENCE, ETC.

by practice at manual operations, and an analysis into elementary processes
of the mental activity essential to its acquisition.

The ‘ mechanical’ factor and the ‘ routine manual’ factor appear to
enter into many occupations. It is hoped, therefore, that these analytical
results when published! may find wide application in the field of vocational
psychology, as also the methods of analysis which have been adopted.

TRAINING IN PSYCHOLOGY.

Report of Committee appointed to inquire into (a) the occupations for which
a training in psychology is necessary or desirable, (b) the place
psychology should occupy in the curricula for University degrees in
Arts, Science, Medicine, Education, Economics and other subjects
(Prof. F. C. Bartiett, F.R.S., Chairman ; A. R. Knicut, Secretary ;
Prof, F. AVELING, Dr. WM. Brown, Prof. J. DREVER, Prof. BEATRICE
Epceitt, C. A. Macs, Prof. T..H. Pear, Dr. R. H. THOULEss,
Prof. C. W. VALENTINE, A. W. WOLTERS).

I. THE OCCUPATIONS FOR WHICH A TRAINING IN PSYCHOLOGY IS
NECESSARY OR DESIRABLE.

1. A TRAINING in psychology is now recognised to be necessary _ for
(i) teachers, who aim at forming mind and character, (ii) medical
practitioners, who aim at curing mental as well as physical disorders, and
(iii) industrialists, who aim at directing human energy in the most economical
way; and educational, medical, and industrial psychology are three
established branches of applied psychology. But a training in psychology
is also helpful to any other person whose work lies in dealing effectively
with human beings. It helps him not merely because it provides him
with important and special knowledge of the human mind and of human
behaviour, but also because it develops in him the habit of dealing with
human relations and problems in an objective, scientific manner.

2. (i) Medicine —Every physician should have received, in his medical
course, a training in general psychology, and in the psychological
treatment of mental disorder.

(ii) Education—Intending teachers require a training in general
psychology, and in the facts about mental growth and the formation
of character, individual differences, abnormal and delinquent
behaviour, the measurement of abilities, and the applications of
psychology to methods of teaching.

(iii) Theology—Clergymen require a training in general and abnormal
psychology, in the psychological facts underlying religious and
moral behaviour, and in the technique of effective pastoral work.
Missionaries require, in addition, some knowledge of racial —
psychology and of the mental life of primitive peoples.

(iv) Law.—Both branches of the legal profession require, or at any
tate benefit by, a training in general psychology, especially in its

1 A detailed account of the analysis outlined in this report will be published in
book form by the National Institute of Industrial Psychology.

TRAINING IN PSYCHOLOGY 309

relation to motivation, intelligence, mental defect, testimony, and
the technique of appraising and dealing with people.

(v) The Services:—Officers in the Navy, Army, and Air Force require
a training in general psychology, especially in its bearing on the
selection and training of recruits, leadership, discipline, morale,
and the mental disorders of warfare. Colonial administrators
also require a training in general psychology and in the psychological
problems raised by the government of native races.

(vi) Industry and Commerce-—Those aiming at executive or adminis-
trative posts in industry and commerce, or at salesmanship and
advertising, need a training in general psychology and in the
various branches of industrial and vocational psychology.

(vii) Soctal Work.—Those professionally or unprofessionally engaged
in social or welfare work require a training in general psychology.

(viii) Other occupations—A training in general psychology, especially
in its dynamic aspects, is desirable for economists, historians,
anthropologists, literary critics, biologists, and everyone else who
aims at describing or explaining the thought and behaviour of
men or animals. A course on the special senses is also required
in scientific work where accuracy of observation depends on the
accuracy of the response of human sense-organs. And there may
well be other occupations for which some training in psychology
is necessary or desirable.

Il. THE PLACE PsyCHOLOGY SHOULD OCCUPY IN THE CURRICULA FOR
UNIVERSITY DEGREES IN ARTS, SCIENCE, MEDICINE, EDUCATION,
EcoNOMICS AND OTHER SUBJECTS.

1. The present position of psychology in the universities of Great Britain
lacks uniformity. In some universities there is a Professor of Psychology,
while in others there is not even a specially appointed lecturer. In some
there is a full, self-contained honours course in psychology, while in others
psychology, if it is taught at all, forms merely a subordinate part of a course
in some other subject. Again, in some universities a course in psychology
qualifies for degrees both in Arts and in Science, while in others it qualifies
for only one of these degrees or for neither. "And these are not all the
anomalies.

2. Psychology should occupy such a place in university curricula as
‘will exhibit its distinction from philosophy and its status as an independent,
positive science. The fundamental concepts used in psychology do indeed
stand in need of philosophical analysis, as do those used in any other branch
of empirical science. Moreover, since psychology deals with the thought
‘and behaviour of men, its connection with philosophy and the other
humanities is much closer than that of other sciences, like physics or
‘chemistry. And for these reasons it is entitled to a prominent place in
the Faculty of Arts in each university. Still, its position as one of the
established biological sciences requires that it shall also be taught in every
‘Faculty of Science.’ Its special cultural value should not be allowed to
prejudice its scientific status. An independent, positive science that is of
special importance to Arts students is still an independent, positive science.

3. (i) Arts and Science—There should be pass courses and honours
courses qualifying for degrees both in Arts and in Science.
(ii) Medicine —Courses in psychology should be compulsory for first
degrees in medicine.

310 REPORTS ON THE STATE OF SCIENCE, ETC.

(iii) Education—Courses in psychology should be compulsory for
degrees or diplomas in education.

(iv) Theology—Courses in psychology should be available for
theological students, and compulsory for those proposing to engage
in pastoral work.

(v) Law.—Courses in psychology should be available for law students.

(vi) Military Subjects, etc—If university courses are provided for
prospective candidates for the fighting services, psychology should
be made a compulsory subject in such courses.1 Training in
psychology should also be given to those aiming at the colonial
administrative services.

(vii) Economics, Commerce, etc-—Courses in psychology should be
provided for degrees in economics, commerce, industrial adminis-
tration, etc.

(viii) Social Science, etc——Courses in psychology should be compulsory
for degrees or diplomas in social science, mental hygiene, welfare
work, etc.

(ix) General—Short courses on the art of study and effective thinking
should be available for all university students, especially freshmen.

4. At present the Committee makes no recommendation as to the precise
nature and length of these several courses, except in so far as the first part
of this report indicates the different kinds of course which different
occupations demand. But it does strongly recommend three things:
(i) Every course should include experimental work. (ii) Even where some
special application of psychology—as to medicine, or education, or
industry—is the main subject of the course, this should always be presented
against a sound background of general psychology. (iii) Every course
should be given by a trained psychologist. At present psychology is often
set before students (especially in Faculties of Medicine and Theology) by
unqualified persons, with the result that the teaching and examinations are
unsatisfactory and out-of-date.

TRANSPLANT EXPERIMENTS AT POTTERNE, WILTSHIRE.

Report of Committee on Transplant Experiments (Sir ARTHUR HILL,
K.C.M.G., F.R.S., Chairman; Dr. W. B. TurriLy, Secretary ;
Prof. F. W. Oxtver, F.R.S.; Dr. E. J. Satissury ; Prof. A. G.
TAanstey, F.R.S.).

Tuis Committee was appointed by the British Association at the 1930
meeting and reappointed at the meetings in 1931 and 1932.
The second report on the progress of the experiments is being published
in the Fournal of Ecology for August 1933. A third report is in preparation.
The balance of £2 6s. 2d. of the British Association grant has been used
to meet (in part) expenses represented by vouchers (receipts) which have
been submitted. No further grant is asked for this year.

1 Professor Pear and Dr. Thouless dissent from this on the ground that specific
instruction in the application of psychology to problems of warfare should not be
given in universities.

KLEINIA ARTICULATA 311

KLEINIA ARTICULATA.

Final Report of Committee appointed to investigate the effect of conditions
on the growth, structure and metabolism of Kleinia articulata (Prof. D.
TuHopay, Chairman; Mr, N. Woopueap, Secretary; Dr. F. F.
BLACKMAN, F.R.S.).

THE starvation experiments referred to in the last report showed that
malic acid is broken down in the later stages, and associated with this is
a marked increase in the pH of the sap. When protoplasmic breakdown
occurs in the pith, the pH of the escaping sap reaches about 8.

Observations on wound-healing have been continued and extended to
Kleinia neritfolia and other species. The distribution of solutes in these
other species has also been examined.

An experiment, lasting five weeks, was carried out in the three chambers
previously mentioned, each chamber illuminated by a s500-watt Osram
lamp with white dispersive reflector and running-water screen. In each,
24 cuttings, previously sprouted in the dark, were exposed respectively to
daily periods of illumination of 8 hours, 12 hours and 15 hours. The
temperature in the chambers during illumination was about 18—20° C., and
fell in the intervals to about 16-17° C. In the 15-hours chamber many of
the sprouts rapidly withered. In the 12-hours chamber most of the shoots
showed a more or less marked tendency to plagiotropism, which was only
shown by a few in the 8-hours chamber. The average elongation was
gteatest with the shortest daily illumination, least with the longest.
Further experiments are contemplated for further analysis of these effects.

The stock of plants was depleted by this experiment, and attention has
since been concentrated on replenishing it. The work will be continued,
but the Committee does not apply for reappointment.

The following papers have appeared during the year :

H. Evans; ‘The Pentosan Content of Kleinia articulata,’ Biochemical
Journal, xxvi, 1095-1100 (1932).

D. THopay and H. Evans: ‘ The Distribution of Soluble Calcium and
Phosphate in the Tissues of Kleinia articulata and some other Plants,’
Ann. Bot., xlvi, 781-806 (1932).

D. TuHopay and H. Evans: ‘ The Distribution of some Solutes in the
Tissues of Kleinia articulata,’ Ann. Bot., xlvii, 1-20 (1933).

312 REPORTS ON THE STATE OF SCIENCE, ETC.

GENERAL SCIENCE IN SCHOOLS.

Final Report of Committee on the Teaching of General Science in Schools,
with Special Reference to the Teaching of Biology (Dr. LILian J.
CLARKE, Chairman; Mr. G. W. Ottve, Secretary; Mr. C. E.
Browne ; Major A. G. Cuurcn, D.S.0.; Mr. G. D. DUNKERLEY ;
Mr. S. R. Humspy; Sir Percy Nunn; Mr. E. R. B. REYNOLDs ;
Dr. E. W. SHann; Dr. E. M. THomas; Mr. A. H. WHIPPLE ;
Mrs. GorDON WILSON ; Miss von Wyss).

CONTENTS.

I. Introduction. II. Historical Review of Reports previously issued on
the Teaching of Science. III. Analysis of the Results of the Questionnaire.
IV. Examinations. V. Out-of-School Activities in relation to Science.
VI. Summary and Conclusions.

I. INTRODUCTION.

THE committee undertook to ascertain as far as possible the position occupied
by General Science with special reference to the inclusion of Biology in the
curriculum of secondary schools of England and Wales. ‘The term General
Science has frequently been taken to mean physics and chemistryalone. It is
therefore to be understood that the term when used in this report means a
course or syllabus which includes at least a study of living things, both plant
and animal, together with physics and chemistry. Inorderto givetheinquiry
its maximum value, the co-operation of heads of secondary schools and
science teachers was invited, and this assistance was fully and freely given.
Teachers were obviously interested, and.a large number of questionnaires
were returned, completed in detail and supplemented by explanatory notes.

At the outset, members of the committee were conversant, broadly
speaking, with the position occupied by General Science in the schools.
They were aware of the work undertaken by various bodies and pioneers
in the past, and of the investigations already made. Their first step was to
prepare a historical review of the growth of opinion in favour of Biology as
a part of the general science work of aschool. Their next step was to obtain
as complete and comprehensive information as possible on—

(1) The extent to which General Science was already adopted in the
schools ;

(2) The attitude of heads of schools and science teachers towards the
value of General Science under the present organisation of schools.

This information they sought largely by means of questionnaires, circu-
lated to schools throughout the country. In this connection, certain
selected schools were invited to supply information on special features of
‘their out-of-school activities, as ancillary to the work carried on in school.

As examinations play a large part in determining the type of science work
in schools, and exercise a restricting influence on a school’s freedom in the
choice of subjects or in the scope of a subject, the committee have considered
the problem of school examinations in relation to the adoption of General
Science as a school subject.

Out-of-school activities play an important part in science teaching. It
was essential, therefore, to obtain information on this point also, and again

GENERAL SCIENCE IN SCHOOLS 313

heads of schools and science teachers gave every assistance. The mass of
information actually received was large as well as pertinent, and the report
can do no more than present this in outline.

At the end of the report will be found a summary as well as a statement
of the conclusions at which the committee has arrived.

II. HistortcaL REVIEW.

The principle that School Science should include more than elementary
physics and chemistry can be traced back many years. It was in fact present
in the minds of those who first advocated the study of science in schools.
Huxley in 1854, when referring to the educational value of Natural History
sciences, said : ‘ Biology needs no apologist when she demands a place, and a
prominent place, in any scheme of education worthy of thename. Leaveout
the Physiological sciences from your curriculum, and you launch the student
into the world, undisciplined in that science whose subject, matter would
best develop his powers of observation ; ignorant of facts of the deepest
importance for his own and others’ welfare ; blind to the richest sources of
beauty in God’s creation ; and unprovided with that belief in a living law,
and an order manifesting itself in and through endless change and variety,
which might serve to check and moderate that phase of despair through
which, if he take an earnest interest in social problems, he will assuredly
sooner or later pass.’

The Royal Commission in 1860 recommended that all boys should receive
instruction in some branch of natural science during at least part of their
school life, that there should be two branches: one consisting of chemistry
and physics, and the other of physiology and natural history, animal and
plant.

At the Nottingham Meeting of the British Association, 1866, a committee
was appointed, which included Professors Huxley and Tyndall and Canon
Wilson, ‘ To consider the best means of promoting Scientific Education in
schools.’ Ample reference to their report, issued in 1867, was made in the
Report on Science Teaching in Secondary Schools, published in 1917,
but it may be noted here that the list of science studies recommended
included : simple facts of astronomy, of geology, and of elementary physio-
logy, experimental physics, elementary chemistry, and botany.

Canon Wilson, in his Essays on a Liberal Education, published in 1867,
describes the methods adopted when introducing science teaching in
Rugby School ; he explains that it was lack of equipment and of teachers
that limited the work actually adopted to Botany and Physics, these two
being claimed as the standard subjects for the scientific teaching in schools.
Chemistry was not then considered possible owing to difficulties in obtaining
suitable apparatus and equipment.

In 1884 Prof. H. L. Armstrong, when speaking at the International
Conference on Education in London, said: ‘In my opinion no single
branch of natural science should be selected to be taught as part of the
ordinary school course, but the instruction should comprise the elements
of what I have already spoken of as the science of daily life, and should
include astronomy, botany, chemistry, geology, physics, physiology and
zoology. . . . The order in which these subjects should be introduced is
a matter of discussion ; personally I should prefer to begin with botany,
and introduce as soon as possible the various branches of science in no
Particular order but that best suited to the understanding of the various
objects and phenomena to which for the time being the teaching had
reference.’

314 REPORTS ON THE STATE OF SCIENCE, ETC.

Encouraged by grants made on results of examinations by the Science
and Art Department, and influenced by the establishment of scholarships
in Natural Sciences at Oxford and Cambridge, and by the inclusion of
science subjects in the requirements of London Matriculation examinations,
most schools had by 1890 included science teaching of some kind in their
curriculum. The teaching of botany, however, did not long survive in
boys’ schools, by the end of the century it was mainly confined to girls’
schools. In 1903 a British Association Committee on ‘The Teaching of
Botany in Schools’ issued a report on methods of teaching the subject.
The report drew attention to the need for substituting an experimental study
of living plants for the excessive study of classification and morphology
which then obtained in the majority of botanical classes ; emphasis was laid
on the need for the pupils to work for themselves, to be the inquirers, and
the recorders of actual experiences instead of being the recipients of didactic
lessons by teachers. It was further asserted that ‘ In Botanical and Zoo-
logical teaching, more than in any other scientific courses, it is easy to adopt
improved methods.’

Instead of developing on broad lines advocated in the early years, science
teaching in boys’ schools became almost wholly concerned with physics
and chemistry, and for the most part with only very restricted parts of
those subjects. The influence exerted by the highly specialised university
requirements for a science degree contributed in no small way to consolidate
this tendency, for the majority of science degrees were awarded to persons
without the most elementary knowledge of biology.

The withdrawal of botany and zoology as compulsory subjects for the
Intermediate Science Examination of London University in 1898 has been,
in the opinion of many teachers, a contributory cause for the decline in
interest in biology in schools, and a cause of the deficiency of candidates
for that subject at the University. All London graduates in science had,
up to that time, at least some knowledge of biological principles and
facts.

The report of the British Association Committee on ‘ Science Teaching
in Secondary Schools,’ published in 1917, gives a survey of the position
of science teaching at that date, and includes important memoranda on
methods of teaching science, on the value of experimental work, on inspec-
tion and examination, and on school organisation so far as it affects the
adequate treatment of the subject.

About the same time the Civil Service Commission attempted to bring the
teaching of science in schools more into relation with the facts of daily life
by demanding for certain examinations a much broader type of science study
than was usual in schools. Similarly the Science Masters’ Association
made a vigorous effort to obtain recognition for General Science in the
School Certificate Examinations. In response to this the Oxford and
Cambridge Joint Board and the Delegates of the Oxford Local Examination
provided a General Science paper alternative to those of the special subjects
of physics and chemistry.

In 1917 the extension of sixth-form work in grant-aided secondary
schools was encouraged by the institution of advanced courses by the Board
of Education. The grant of £400 made in connection with each such
course made it possible to free a teacher for the instruction of a compara-
tively small number of pupils in the sixth form, and to give help in the
equipment of laboratories and libraries. In the first year, 1917-18,
127 courses were recognised, 82 of which were courses in Mathematics
and Science. In 1924-25 there were 469 courses, 235 being courses in
Mathematics and Science. There can be little doubt that the science work

GENERAL SCIENCE IN SCHOOLS 315

in the schools containing Advanced Courses in Science Subjects developed
considerably under their influence. It might have been expected that the
existence of specialised courses in the top forms would have left the science
staff free to devise a General Science course covering the years between the
years 12 and 16, based in the main on the needs of that large majority of the
pupils who leave school on reaching the latter age. Unfortunately this does
not appear to have been the case ; on the contrary, there has been a tendency
to frame the science course with a view to covering as much ground as
possible in the subjects of the Advanced Course, and specialisation has
spread down the school.

A report was published by the Prime Minister’s Committee on ‘ Natural
Science in Education’ in 1918 (reprinted in 1927). It stressed the need
to broaden the basis of science work in secondary schools, saying :

‘Some knowledge of the facts of the life of plants and animals should
form a regular part of the teaching in every secondary school. . . . The
main facts as to the relation of plants and animals to their surroundings,
and the changes in the material and in the energy involved in life and growth
should form part of a well-balanced school course.’

The same report deals in some detail with various conditions affecting
the teaching of science, such as the influence of examinations, the supply,
qualifications and training of teachers, university requirements and
laboratory accommodation, and says :

‘The want of teachers with wider scientific qualifications is at present
the real difficulty in the introduction of biology into school work.’

In a summary of the principal conclusions of this committee the following
are worth quoting, as they refer to the science course recommended for
pupils of ages 12 to 16:

‘The science work for pupils under 16 should be planned as a self-
contained course, and should include besides physics and chemistry some
study of plant and animal life. . . . More attention should be directed to
those aspects of the sciences which bear directly on the objects and ex-
periences of everyday life.’

By 1920 there was a rapidly growing opinion that biology is a necessary
element in all school science, and that neither botany nor zoology as separate
subjects could take its place. In most girls’ schools botany had long been
a recognised subject of the curriculum. Only in comparatively few boys’
schools had biology been given any serious consideration. Natural history
of a very elementary type sometimes formed the early stages of a science
course, but it was, more often than not, relegated to voluntary work out of
school hours as part of the work of the Natural History Society.
~ In 1924 the committee of the Science Masters’ Association again attacked
the problem in their publication General Science. In order that there
should be no misunderstanding as to the meaning of the title, the authors
‘expressly ‘ consider that, in any well-balanced course, Biology with Human
Physiology and Hygiene is entitled to about one-quarter ’ of the total time
@iven to the science course as a whole. The pamphlet has helped to focus
‘attention upon the need for reform in school science, it has encouraged
teachers fortunately placed as regards freedom of action to draw up their
Own courses, to make trial of them and to give others the benefits of their
‘experiences. The revised edition, published in 1932, has two specimen
‘syllabuses, and suggestions for practical work, especially with respect to
‘the biological aspect of the course. In General Science it is especially
‘claimed that ‘ the whole essence of General Science lies not in the syllabus,
but in the interpretation of it. . . . It must not be merely bits of specialist
science. . . . General Science aims at unity,’ to ‘ be conceived as something

316 REPORTS ON THE STATE OF SCIENCE, ETC.

whole and undivided,’ and ‘ General Science will not be successful unless
it is treated as a whole.’

In 1925 the Board of Education issued a report of an inquiry carried out
by their Inspectorate on the conditions affecting science teaching in a number
of large urban secondary boys’ schools. It pointed out that the recommen-
dations of the Prime Minister’s Committee of 1918, on the desirability of
some elementary teaching of biology as a part of the normal curriculum of
boys’ schools, had produced, so far, practically no effect on the science
syllabuses in those schools.

In 1926 the Hadow Report on the ‘ Education of the Adolescent.’
suggested ‘ That most schemes for courses in elementary science in modern
schools, central schools, and in senior classes of elementary schools might
be grouped round a simple syllabus consisting of :

‘(a) The chemical and physical properties of air, water, and some of the
commoner elements and their compounds, and elements of
meteorology, and astronomy, based on simple observations, and
the extraction of metals.

‘(6) A carefully graduated course of instruction in elementary physics
and simple mechanics, abundantly illustrated by means of easy
experiments in light, heat, sound, and the various methods of
production and application of electricity.

‘(c) A broad outline of the fundamental principles of biology describing
the properties of living matter, including food, the processes of
reproduction and respiration, methods of. assimilation in plants,
the action of bacterial organisms and the like.

‘(d) Instruction in elementary physiology and hygiene based on lessons
in biology.’

It contained, on page 223, the following recommendations :

‘(x) As a general rule, in country schools the science syllabus both for
boys and girls might be largely based on biological interests, the
study of elementary physics and chemistry being subsidiary but
arranged so as to supply the indispensable foundation for a
course in elementary biology with special reference to its bearing
on horticulture and agriculture.

‘(2) Science courses for girls in modern schools and in senior classes should
in their later stages frequently have a biological trend. . . .. The
work should not be confined to botany, as. the study of simple
forms of animal life can, under a wise and skilful teacher, be made
an admirable means of widening and disciplining the pupil’s sym-
pathies, and giving her broad hygienic ideals and a knowledge of
nature which may increase her happiness and efficiency as a human
being.

‘(3) Instruction in elementary physiology and hygiene developing out
of the lessons in elementary biology should be given to all boys
and girls in Modern Schools and Senior Classes... Such instruction
should be largely the practical outline of a study of elementary
biology, treated, not as a series of classifications but as the study
of the development of form and function in suitable types of plant
and animal life, leading up toa study of how the human body is
built up and how it works. Such instruction in biology and
elementary physiology, if properly carried out, might well provide
the basis for a right attitude to many social problems.’

GENERAL SCIENCE IN SCHOOLS 317

In 1928 a British Association Committee of Zoologists published a report
on ‘ Animal Biology in the School Curriculum.’ In this report the com-
mittee regarded the principle that biological teaching should have some
place in the education of all children as generally admitted, and after
emphasising the unity of this teaching in that it must take in the whole
range of life, plant and animal kingdom alike, they dealt mainly with the
amount and scope of studies to be recommended. ‘They made suggestions
for the actual building up of a scheme of work, and presented in outline
a syllabus of biology for pupils from 11 to 16 years of age.

In 1929 the British Association Committee on Educational Training for
Overseas Life again urged that a broader view should be taken of the
function of school science as a preparation for life and service. ‘They viewed
with satisfaction the movement to introduce biological studies into the
curriculum. Such studies dealing with the living environment of the child,
they claimed, would introduce naturally and purposefully most of the
biological work possible in many schools as well as much of the physical
science necessary.

“In Rural Studies, schools would possess an educational instrument of
wide adaptability, affording intellectual material of the highest kind. . ..
The contact with life which rural studies bring gives purpose and reality to
school work generally ; they create interest and provide a rational basis for
all branches of scientific inquiry. . . . These studies provide opportunities
for a simple approach to the physiological processes of life, and, when
correlated with the teaching of geography and history, constitute a basis
of instruction of far-reaching importance.’

The report draws attention to the chief causes of the slowness of the
schools to extend their biological work, a course so strongly urged by
educationists and so clearly in accord with the needs of the time.

In 1929 the British Association Committee on Science in School Certifi-
cate Examinations showed, in their report, that a detailed analysis of
examination statistics proved that ‘ General Science occupies a low place in
comparison (with specialist subjects) and biological subjects other than
botany are deplorably neglected.’ This report includes some valuable and
suggestive syllabuses both for General Science and for Biology.

In' 1929 a report on the condition of science teaching in Oxfordshire,
compiled by a committee of the Oxfordshire Branch of the Assistant Masters’
Association, emphasised the need for the inclusion of biology in the science
work of the schools.

In 1929 the Friends’ Guild of Teachers published a report based on
answers to a questionnaire sent to the Friends’ schools, to a number of
other well-known schools, and to a number of specialist teachers. In
answer to the questions, ‘ What Life Sciences ought to be included in the
_ curriculum for pupils aged 12 to 18, and on what grounds can their inclusion
be adequately justified,’ the following expression of view summarises the
general opinion :

_ “There is but one ‘‘ Life Science ’’—Biology, of which Nature-study,
Hygiene, Botany, Physiology, Zoology are specialist sub-divisions. Too
generally at present the instruction of Life Science in schools provides little
more than some knowledge of Nature Study, Hygiene and Botany, and a
very strong case can be made out for instruction in the general principles
of Biology even as early as the first stage—tr1o to 12 years of age.’
~In February 1932, a committee of the Economic Advisory Council,
presided over by the late Viscount Chelmsford, reported on the ‘ Education
_ and Supply of Biologists.’ The report, besides making recommendations
on the education of specialists for work at home and overseas, urges the

318 REPORTS ON THE STATE OF SCIENCE, ETC.

inclusion of biology in schools ‘ as a cultural subject apart from its value
for medicine and for the professional biological services.. Biology should
be brought to the notice of every boy, and none should leave school without
some knowledge of it,’ and further, ‘ the introduction of biology into the
schools as a general cultural subject is essential in that the interests of the
ordinary boy requires consideration as much as those of the scholarship
candidate.’

A memorandum on ‘ Science in Senior Schools’ (Board of Education
Pamphlet No. 89, 1932) reports that 214 out of 584 senior schools pay no
attention to Biological sciences. Out of 599 men science teachers, only
38 have qualifications in Biology, while 198 women teachers had 111 qualifi-
cations in Physics, 129 in Chemistry, 117 in Botany, and 51 in Zoology.
The memorandum recommends three periods a week as the minimum for
science in senior schools. It makes suggestions for teaching various aspects
of physics, chemistry and biology, urges constant cross-references between
all parts of the science course, and gives lists of apparatus and equipment
considered necessary.

A National Conference on ‘ The Place of Biology in Education ’ was held
in London, November 1932, under the auspices of the British Social
Hygiene Council. The conference lasted three days and dealt with the
following aspects of the subject :

(1) The National and Imperial Need for a Biological Outlook.

(2) The Place of Biology in Public Education, including :

(a) Biology as an Integral part of Science ;

(b) How Local Education Authorities can further the Teaching, of
Biology.

(c) The Teacher’s contribution to Biology.

(3) Biology in the Training Colleges.

(4) Biology in National Life.

(5) Biology in the Elementary School.

(6) Biology in the Public, Secondary, and Preparatory Schools.

A discussion followed on the schemes for teaching Biology submitted for
consideration by Prof. Julian Huxley, Prof. W. Cullis, and Prof. Sir J. A.
Thomson.

A report on the School Certificate Examination, prepared by a panel of
investigators appointed by the Secondary Schools Examinations Council to
inquire into the working of the examination in question, was published by
the Board of Education in 1932.

JII. ANALYSIS OF THE RESULTS OF THE QUESTIONNAIRE,

The questionnaire sent out by the committee asked for information on
the following topics :

(1) The present position of science in the schools and science subjects
taught.

(2) The position of Biology in the schools.

(3) The position of General Science, taking that term to include
chemistry, physics and biology, at least.

(4) If Biology and General Science are not commonly taught, what are
the reasons for their exclusion ?

(5) Where General Science is taught, is it found to be advantageous o
disadvantageous for the specialised work later in the school course ?

GENERAL SCIENCE IN SCHOOLS 319

1. The present position of science in schools and science subjects taught.

In England and Wales there were (March 31, 1931) 1,367 State-aided
and 362 non-aided secondary schools. The questionnaire was sent to the
majority of these schools, and replies were received from 98 boys’ schools,
198 girls’ schools, and 62 mixed schools. Table I shows to what extent
the various subjects were studied in these 358 schools.

TasB_e I.
Boys’. Girls’. Mixed.

Percentage of schools taking Chemistry. 97 83 92
9 9 »» _ Physics _. 97 72 87

” »” ” ” General
Science . 56 69 50
» ” » Biology . 25 41 32
» a9 55 So Botany 1 9 22 84 52
3 sue. » Zoology’ . 16 27 2r

It is clear from this table that chemistry and physics dominate the science
work in boys’ schools and in mixed schools, but the position in girls’ schools
is not at first obvious. To clarify it, Table II shows the percentage of pupils
taking the various science subjects.

TaBLeE II,
Boys’. Girls’, Mixed.

Number of schools ; ~ ; ; . 98 198 62
Average percentage of pupils taking Chemistry . 50 26 51
»”» ” ” ”? »”» Physics i! 55 21 5°

” ” ”» » ” General
i Science . 37 40 42
3 a LEME » Biology. 21 26 28
” ” ” ” ” Botany . 4 31 24
” ” > ” ” Zoology od 4 4 3

_ This table, taken in conjunction with Table I, makes it clear that botany
is still a popular science in girls’ schools, but that General Science appears
to be holding an important position. It must be noted that the above
figures are liable to be misleading as many schools have courses in General
Science for the younger pupils, but do not carry the subject on to the
school certificate stage. Of 137 girls’ schools taking General Science, we
are informed that only 35 take the subject in school certificate, whereas
almost all the 167 taking botany and two-thirds of those taking chemistry
present it for examination. It is fair to conclude that in boys’ and mixed
schools chemistry and physics dominate the science work, and in girls’
schools there is a wider field. General Science is usually taken as an
introduction for pupils of ages 11 to 13, and further, it is clear, from a second
inquiry that was made, that in many schools ‘ General Science ’ is taken to
mean chemistry and physics only. None the less, General Science in the
broader sense is evidently becoming more popular than it was a few years

ago.
“It may be profitable to add a note here about Nature Study. This may
conveniently done in the form of Table III.

320 REPORTS ON THE STATE OF SCIENCE, ETC.

Tasce III.
Boys’. Girls’. Mixed.

Number of schools : 98 198 62
Percentage of schools taking N. ature ‘Study 26 42 44
Percentage of pupils of these schools taking

Nature Study . 14 19 25
Percentage of schools taking Nature Study and

not Biology : 12 20 23
Percentage of schools taking Nature Study and

Biology . 14 22 21
Percentage of schools taking. Biology but not

Nature Study 29 30 18
Percentage of phpils taking Biology in " ‘these

schools. 13 21 24

The replies to ae questionnaire hes ige st that gtie» Study is generally
taken for the first year or two of the pupil’s school life only ; in very few
schools is it taken beyond the age of 12.

2. The position of Biology in Schools.

Taste IV.
Boys’. Girls’. Mixed.
Number of schools P : 98 198 62
Percentage of schools taking Biology ; é 25 41 32
of », pupils taking Biology in these ; 21 26 28
a ,, schools taking Bicleey in school
certificate 2 ; : II 16 19

The last line of figures may be ca: as a fair measure of the seriousness
with which biology is pursued in schools,

3. The position of General Science.

It is very difficult to obtain figures which give a reliable account of the
position. All the following subjects are studied by various schools as part
of their general science courses: chemistry, physics, botany, physiology,
physical geography, astronomy, biology, zoology, geology, soil science,
nature study, domestic science, hygiene, and meteorology. In some schools
the course is evidently an introductory one leading on to a more detailed
survey of two or more subjects, in others it is a general course for senior

pupils who are on the classical or modern languages side. In some schools —

_the course is experimental ; in others it consists of reading and lectures
only. It will be clear that figures showing the number which take General
Science will be misleading, and for that reason the figures for General
Science in Tables I and II must be accepted with caution. It is possible,
however, to give a few figures whose meaning is clear.

TABLE V.
Boys’. Girls’, Mixed.

Number of schools ‘ 98 198 62
Percentage of these taking Gétieral Stierce e 56 69 50

m », pupils taking General Science in
these . 37 40 42

i ,, schools taking General Scidnee i in
school certificate form . 22 18 15

(The figures in the last line may be a little too es but are certainly not
a little too low.)

GENERAL SCIENCE IN SCHOOLS 321

4. Reasons why Biology and General Science are not commonly taught.

Tables IV and V show that at present neither General Science, including
biology, nor Biology is taught as much as other scientific subjects. ‘The
main reasons given in questionnaire answers for the absence of biological
teaching are tabulated :

Reason A.—Omission due to the requirements of some School Certificate

Examination.
Reason B.—Lack of suitable teachers.
Reason C.—Lack of suitable accommodation.

eagaatatss Boys’. Girls’. Mixed.
Number of schools : : : , ; 98 198 62
Percentage of these giving reasons why Biology is
not taught y : , : : : 53 36 35
Of schools giving reasons why Biology is not
taught :
Percentage, ReasonA . j ; : 45 50 41
Percentage, Reason B ; A 3 ; 47 33 aI VAG
Percentage, Reason C ; 2 : 43 39 4I

Some schools give more than one reason.

It should be noted that the above reasons were those suggested in the
question paper, and they are the most common reasons given. They may
be taken as the effective reasons for the exclusion of biology at present,
but, from their nature, they could be overcome if the desire for biology
were sufficiently urgent. Other reasons which occur fairly often are
© Crowded curriculum,’ ‘ Insufficient time,’ ‘ Lack of demand generally,’
‘ Superior claims of physics and chemistry,’ ‘ Unsuitable subject for young
pupils.’ A few schools state that they do not consider biological subjects
to have a greater claim to inclusion than sciences already taken. Generally
it may be said that schools are alive to the value of biology as an educational
subject, but they do not see their way to introduce it owing to their over-
crowded time-table or to difficulties connected with staffing or accom-
modation. They also doubt whether gain in breadth of teaching is a real
compensation for loss in depth. .

Considering one of the main reasons in more detail—difficulties connected
with the school certificate examination—it is evident that a large number of
schools find this a very serious factor in their decision to exclude biology.
General Science including biology is not accepted for matriculation in most
universities, whereas chemistry and physics are. If a pupil can take
chemistry and physics as two subjects in the school certificate examination,
both acceptable for matriculation, it is probable that schools will take the two
subjects and exclude biology. (It may also be pointed out that most pro-
fessional bodies do not accept General Science as a qualifying subject for
the preliminary examinations.)

Further, with regard to the taking of biology as a separate subject in the
school certificate examination, certain difficulties are raised. In town
schools it is said to be more difficult to obtain material for the teaching of
zoology than for that of botany, and that in any event, botany is an easier
subject for class teaching than zoology. With the same time available,
teachers say (1) it is easier for pupils to pass examinations in botany than
in biology; (2) botany is cheaper than biology, both in materials and
apparatus ; (3) where the number of science pupils is small, it is very
expensive to take up a third science owing to increase of staff; (4) the
classes would have to be smaller than is profitable.

322 REPORTS ON THE STATE OF SCIENCE, ETC.

Many heads of schools are not convinced that biology has any advantages
over botany or other sciences as an examination or as an educational subject,
and they are leaving matters in their present position until they can be sure
that a change is desirable.

5. General Science in relation to later specialised work.

The fifth point set out in the questionnaire was the advantage or otherwise
of General Science as a foundation for the specialised work later in the
school course. In considering the answers given, it should be borne in
mind that the term ‘ General Science ’ has different meanings for different
schools. ‘The following shows the opinions of those schools which take
General Science and which give their views :

STs eV Boys’. Girls’. Mixed.

Number of schools : 98 198 62
Percentage of these taking General Science - 56 69 47
Percentage of schools stating General Science

advantageous for later work : 20 44 20
Percentage of schools stating General Science

disadvantageous for later work . 3 3 5
Percentage of schools taking General Séience i in

School Certificate forms . F g é 22 18 15

On the face of this evidence it would appear that the opinions expressed
were overwhelmingly in favour of General Science but for the lack of
certainty as to what precisely is meant by ‘ General Science,’ and what by
specialised work later in the course. An examination of the replies to the
questionnaire shows that about seventy schools consider two sciences
constitute a General Science course, and of these two, biology i is very seldom
one. Further, by ‘ specialised work later in the school course,’ some schools
mean Higher School Certificate work and others mean School Certificate
work. Itis clear that, in the first case, the General Science course will mean
a course extending over three or four years, whereas in the second it may
mean one or two years’ work with younger pupils.

Probably the best way to give an accurate impression of the views stated
is to quote from them, dealing first with those schools which have a General
Science course of three or four years.

(1) General Science is taught only to non-science specialists. I should
strongly disapprove of science specialists going through a course of General
Science.

(2) From an educational point of view, entirely advantageous. From
the point of view of the necessity of passing School Certificate it is still
advantageous, though the time spent on non-examination subjects is some-
times grudged by boys. It is greatly to be desired that a School Certificate
paper in General Science acceptable for matriculation should be provided ;
a paper consisting of so many chemical, physical and biological questions
in water-tight compartments does not meet the case. (The point about
a General Science paper acceptable for matriculation is made by several
other schools.)

(3) It is certainly true that a General Science course with its wider scope
is not advantageous to the specialised work later on, as there is a limited
amount of time available for the study of science, and what is gained in
breadth is lost in depth. Nevertheless I am sure that a General Science
course is desirable.

(4) As science scholarships are at present awarded it is hardly possible to
obtain scholarships unless specialisation in physics and chemistry begins at
fourteen, and at this age only the modern forms go on with General Science. ~

GENERAL SCIENCE IN SCHOOLS 323

(s) It would be an advantage to Higher School Certificate work if General
Science were taken up to School Certificate standard ; for examination
requirements we find it easier'to take a special subject.

(6) We consider that a General Science course is too disconnected and
not a scientific training, and therefore not a good foundation for later work.

(7) General Science course advantageous on the whole, but only in so
far as it is amplified by more special work for two years below School
Certificate standard if advanced work is aimed at after matriculation.

These opinions, typical of many more, would seem to indicate that
General Science is approved educationally but it is not the best possible
preparation for the present matriculation or scholarship work. Dealing
now with those schools whose General Science course comprises one to
three years in the early part of the school life, it may be said at once that
the general consensus of opinion is favourable. Very many schools mention
that a knowledge of the elements of one science is essential to a proper
understanding of the more advanced work in another science. Very few
schools object to General Science in these early years, and of those that do,
a number are largely concerned with the need for more specialised know-
ledge necessary for examination in separate subjects later in the school
course.

Generally, then, it may be stated that most schools which have taken
General Science find the subject of value educationally, and based most of
their objections to it on the needs of matriculation and scholarship work.

(In this analysis the opinions stated are those given to the questionnaire
except where it was necessary to gather up, in a comprehensive sentence,
the views previously stated.)

IV. ExAMINATIONS.

At present the regulations and schedules of the various School Certificate
Examination Boards decide to a great extent the content of science teaching
in schools. In some schools these schedules decide also the form in which
the instruction is given, and control much of the laboratory work.

A number of examining bodies include General Science as a subject for
the First School Examination, but three of them at present consider General
Science to be a course which includes only chemistry and physics.

Several universities do not at present accept General Science as a
qualifying subject for University matriculation.

Much effort has been expended in late years in attempts to standardise
more accurately the marking and grading of examinations. There is perhaps
one danger here to which attention may be drawn. Certain types of
questions are easy to set and easy to mark with precision. Unfortunately,
facility in answering them can be acquired without any real knowledge of
science or understanding of scientific method. This sort of question reacts
injuriously on the teaching of science. The school teachers, who in recent
years have been invited in increasing numbers to assist as examiners and
critics of the papers, can help materially by combating questions of this
type. The committee would welcome an extension of the system by which
teachers are utilised as examiners or moderators.

In 1932 a panel of investigators appointed by the Secondary Schools
Examination Council issued a report on the School Certificate Examinations.
The report was drawn up after an extensive investigation, and the panel
was able, from its constitution, to obtain material which would be available
to no other body. Included in the report of the panel of investigators is a
recommendation that all candidates in science should be obliged to take
a paper in ‘ Elementary Science’ (by which is meant a course similar to

324 REPORTS ON THE STATE OF SCIENCE, ETC.

what is called ‘ General Science” in this report). While this committee is
of opinion that the recommendation if adopted would lead to an improvement
in the study of biological sciences, yet it would prefer some alteration in
the syllabuses set for examination purposes which would ensure that all
candidates sitting for the science papers should have passed through an
adequate course of General Science as defined previously.

1'The report suggests that optional papers in chemistry, physics and biology
should be retained as additional subjects, and candidates should be allowed
to take one or more of these. Candidates who, in good faith, take all these
additional papers might be exempted from the Elementary Science paper.

The present system of examinations encourages a narrow specialisation
which is unsound educationally. A school may find that candidates for,
say; physics only have a greater chance of examination success under the
present arrangement than they would if they took General Science. ‘ It
will be clear that such an attitude towards science teaching is due to
making the School Certificate Examination an end in itself rather than
a means to test the results of a course of general education before the pupil
begins such a course of specialisation as is appropriate for secondary
schools.”’ (Circular 849, B. of E.) ‘It is a cardinal principle that the
examination should follow the curriculum and not determine it’ (loc. cit.),
A course which deliberately sacrifices the best education of the pupil to the
desire of passing an examination is hard to defend.

A further recommendation of the panel is that which advocates ‘ Easy
papers and a high standard of marking.’

The plain fact is that it is extremely difficult to test a pupil’s appreciation
of science, and possibly no written test can be adequate. The one person
who should be able to say whether the pupil is well grounded in science is
the teacher. If the teacher is personally known to the examiner, the latter
may be able to judge of the value of his opinion. Actual contact between
examiner and teacher is very desirable. One examining body sends an
examiner to each school for the practical examinations in science, and it is
clear that the system has great advantages. In a few years the examining
body would have a shrewd idea of the value of each school and of each
science teacher, whereby the work of the pupils could be more accurately
known and assessed. ‘The chief obstacle in the way of adopting the system
generally is the size of some of the School Certificate Examinations. (Over
17,000 candidates sat for the School Certificate Examination of one
authority in 1931.)

The committee feel bound to state, however, that they see no ultimate
value in this tendency to standardisation of methods, materials and results.
Assuming that the one perfect School Certificate Examination were uni-
formly adopted, the committee would not be satisfied. It is a common-
place to say that much of the work of a school cannot be examined, and it is
not too much to say that many of the most valuable parts of a pupil’s make-up
cannot be tested by any written work. This applies with great force to
a pupil’s work in science. The efficient school will continue to turn out the
good pupils and the inefficient school the bad ones however perfectly the
School Certificate Examination be devised, and the committee feel that
efforts to increase the efficiency of schools are of more ultimate value than
efforts to improve the efficiency of examinations. If it is asked to state
what efforts it has in mind, the committee would suggest more frequent
inspection, more pedagogic research, a more rigorous selection of candi-
dates for the teaching profession, more efficient training of teachers.

1 This committee would have preferred the report to have included options so
that pupils could take papers in Botany, Zoology or Biology as additional subjects.

ay

GENERAL SCIENCE IN SCHOOLS 325

fQ :
5 = E cs 4 ~
School Certificate Biol S 4 4 = g iC) — | 3
f ool Certificate Biology. e So 4 E E = re E
rea ‘
eS A S Z
| Papers (in hours where stated) | I, II | 13,13) I, I 3. Ee = 3
| Demonstration of dissection =
| d; lens =1; microscope=m | 1, m ] d,l,m}| d,1 1 d,1,m 1 dy sl
| Knowledge ‘of Elementary
Physics and Chemistry , a esp. ia au Te ae ety de

|
(q
)
| Differences between animals

and plants : : : + + au =e
| Food materials; nature and a
assimilation of . : 4+ Te £0, ar +
i Respiration ; energy relation + + 5 2 + o- + oe +.
| Reproduction ; sexual and an
| asexual : , j at LE a 2 a —
‘| Reaction to stimuli + + ae + + + + —
| Cellular structure ; ; + TA
Soil Science = s; C. & N.
Gycles =(c.\: . ; 4 c sh.c s

| Structure and functions of
flowering plant : + + + +
‘ Herbaceous and arborescent

| _ types

4 Floral structure ; Buttercup =
‘ B; Pea = P: several = x oc |B, P| B,P
| Fruits and seeds ; dispersal =

Ha 8 +24
&
8
8

| -d; germination = g Ped aNt hee at GSB? led: & d dre yr d, ig
| Tubers, corms and bulbs. ok + ate
| Algee ; Chlamydomonas = C ;
Pgs Spitogyra=S . Qs hes bivs c oc
q Fungi; Mucor = M, others
| =-+ ;, Bacteria = B B M M+ | M+ M oh
-Archegoniates ; ; Moss = M;
Liverwort = L; Fern = F M L+ F F
| Relation of plants to environ-
qe ment 3 + + (alt)? =F esp. = a
| Rana , as type; systems and
functions (alt.) |» + sh y + + -
| Rana, development (externals Qs
| eae typ (alt.) Big et 70 teas
| Mamm as e F P ¥ skelet -- 5 a
'| Amoeba Sh: eg ge be de lab
Hydra = H; Worm =W .| H H H te te cided a
'f S; éxternals = €; life- 7
% alta =1; dissection = d e, 1 e “See varrerth Hinge e end e, 1
tolo+ S$ is
Natu ral history ‘(of certain 3 2
_ types). falidoskass “- ao
{ yee of animals to en- 4
vironment. pas edets 2 + > + +

F
otes ue + means the subject is specified; esp., the subject is emphasised; alt., an alter-
native or option.

326 REPORTS ON THE STATE OF SCIENCE, ETC.

V. Out-or-ScHOOoL ACTIVITIES IN RELATION TO SCIENCE.

In response to a special request sent out by the committee many schools
supplied information upon the various out-of-school activities ; the reports
received show that science teaching owes much to the work done out of
the ordinary school hours.

A natural history society exists in most schools. The older natural
history societies are usually divided into sections: astronomical, natural
science, ornithological, entomological, botanical, and so on, the interests
of each section being supervised by curators or other officers. Physical
and chemical sections may organise expeditions to works and factories, set
up demonstrations illustrating phases of the development of the particular
section, or undertake definite pieces of work in the laboratory. Geo-
graphical and historical clubs are fairly common, while in a number of
rural schools bee clubs and gardening clubs are linked with the ‘ Young
Farmers’ Club’ movement. To all such societies a camera club is con-
sidered a useful adjunct.

Under conditions where the time assigned to science is limited or
negligible, as for example, on a few classical ‘ sides,’ out-of-school science
may be regarded, without exaggeration, as a saving factor in an unbalanced
curriculum.

There seems to be variation in the conditions of membership. In the
majority of schools boys or girls of all ages are eligible for membership,
though the natural history society may be divided into senior and junior
sections. In a few, membership is limited to the older pupils, while in
others, active membership declines as pupils reach higher forms. Again,
there are schools in which it would appear that the natural history society
is run for the smaller boys only, and the old function of the natural history
society is regarded as having been largely superseded by biological teaching.

It is evidently becoming more possible for boys to take part in out-of-
school activities other than organised games. ‘The clash of interests that has
ensued between games and other out-of-school activities is diminishing,
probably because many heads of schools exercise wise supervision over the
activities of all departments, and realise their obligation to maintain a proper
balance between them. One hears less of the obstacles raised because
younger pupils must perform house duties or because senior ones are
impeded by convention.

Several heads have emphasised the value of organised holiday camps,
either for week-ends or longer periods. They point out that this enables
members to spend periods in contact with countryside or seaside, to the
benefit not only of the work but of the whole life of the school.

As a development of the principle of doing service to the community,
one school, at least, sets up experiments and exhibits that are demonstrated

for the benefit of adjacent schools and adult evening classes, while another |

school provides surplus biological material for others less fortunately
situated.

The records of the societies, whatever their purpose or mode of organisa-
tion, demonstrate that, as a general rule, the pupils do most of the work and
bear much of the responsibility, and further, that the work has a depth and
quality that must reflect most beneficially not only on the scientific training
of the individual but on the whole educational outlook of the school.

It is clear that many schools have undertaken pioneer work, and have
thus made some contribution towards breaking down the artificial boundary
between indoor and outdoor activities.

GENERAL SCIENCE IN SCHOOLS 327

The following is a summary of the information obtained by the com-
mittee :

School Societies—The science club often embraces all the sciences so as
to give boys or girls, especially those: who are specialising in non-scientific
subjects, a chance to listen to lectures and debates on scientific subjects of
current interest. It provides for the display of films of scientific appeal in
natural history, archeology and other subjects. Lectures by visitors from
other schools and from universities often provide great interest. Sections
devoted to particular branches of science-appeal specially to the field worker
and the collector; they give opportunities for the more enthusiastic
members to read papers or, less formally, to describe or exhibit natural
phenomena in the knowledge of which they are versed. Interest in the
weather is fostered by the regular recording of meteorological observations.
A combination of zoological and botanical garden for the use of pupils is
a great asset; skilled guidance is necessary here, but much of this work
can be done by suitable chosen curators. In this connection it is interesting
to read the report on the Botany Gardens of the James Allen’s Girls’ School,
Dulwich (Educational Pamphlet No. 41, Board of Education). A room in
which special collecting apparatus and aquaria, both large and small, can be
kept is desirable ; but experience shows that work need not be delayed on
account of the lack of such accommodation. For more advanced field-
work a laboratory must be open at suitable out-of-school times. This kind
of work is very valuable as a training in scientific method, provided the
workers keep accurate records of data relevant to their observations.

Lectures of general scientific interest may well be thrown open to the
whole school, and not limited to members of a society. In the North-
Western area the Association of Women Science Teachers has a panel of
lecturers who visit schools in the Manchester and Liverpool districts. The
lecturers are chiefly teachers in secondary schools or University lecturers
or museum keepers.
~ Many school museums are organised to help those interested in particular
branches of science. ‘The use of the material in the museum is encouraged
and interest aroused by frequent changes in the exhibits. The possession
of a museum, however good, offers little stimulus unless the pupil is already
interested in field-work.

- According to an experienced teacher of biology there are three stages
through which boys will usually pass during the course of their member-
ship in the science club, though not all boys will arrive at the third stage :
(i) casual interest ; (ii) enthusiastic cdllection ; and (iii) a stage at which
the work is pursued on scientific lines.

_ Unorganised Voluntary Holiday Work.—Where the school has scouts or
guides much useful work is often done under competent leaders. The
Whitsuntide and Summer camps are the means of introducing many urban
pupils to some of the secrets and joys of the countryside.

_ Expeditions —These may have as their primary objective: (i) the culti-
vation of a wider scientific outlook than class teaching can give; (ii) the
establishment of an interest in the practical application of scientific know-
ledge to human affairs ; and (iii) the acquisition of a first-hand experience
of field-work. Under (i) and (ii) would be included visits to factories, gas
and electrical stations, wireless stations, dairies, research stations, and
Zoological and botanical gardens. Managers are almost invariably generous
in granting facilities for such visits, as well as in providing skilled guidance.
Under (iii) would be included short expeditions into the country for the
purpose of studying the flora, fauna and physical features.

328 REPORTS ON THE STATE OF SCIENCE, ETC.

From the administrative point of view, expeditions may be divided into
(i) class expeditions in which a whole class takes part, either in school hours
or on a holiday ; and (ii) voluntary expeditions undertaken for a like purpose
by groups of pupils from different forms.

The best results are obtained from biological expeditions if in any one
year attention is concentrated upon one or two localities only, and visits
are made at different seasons. Casual expeditions, however enjoyable, are
liable to be relatively unproductive. It is recommended that before the
expedition each pupil should be provided with or should make a map of
the region to be studied.

Longer voluntary expeditions call for expenditure and are less easily
arranged ; where they are practicable they justify the trouble involved.
Some schools arrange a week in the neighbourhood of Port Erin, and while
studying the flora and fauna of the seashore they are also able to see the
aquarium, museum and laboratories of the Marine Station there. Similar
expeditions are made to the Lakes and to Derbyshire. Other schools arrange
holiday courses in conjunction with the Marine Laboratories at Plymouth
and at Millport ; while a less advanced course has been devised for younger
boys at Colwyn Bay during the summer holidays. ‘The biology mistresses
of several London schools take girls to Seaford for a like purpose in the
Easter holidays. All teachers of biology who have organised such ex-
peditions have found them both useful and enjoyable.

VI. SumMMaRY AND CONCLUSIONS.

There has been in recent years a definite but relatively slight increase in
the biological content of school science courses, and good pioneer work is
being done in the teaching of General Science.

There is ample evidence that, on the whole, Biology is being taught with
skill and enthusiasm. The same may be said of General Science, though in
a few cases the criticism may hold true that the teaching tends to be diffuse
and generally to lack scientific character.

There appears to be a general feeling of growing intensity that the
traditional chemistry and physics or botany of the secondary school is
insufficient educationally, and that instruction in biology should claim a
portion of the time available for science. Many arguments in favour of its
inclusion are given in the historical review.

There does not seem at present to be any very definite agreement whether
the biological part of the science course should come early or late in a child’s
school life. Many teachers would prefer it to be taken in the latter part of
their school life, so that an adequate foundation of physics and chemistry
can be assumed. Others think that at an earlier age the pupil’s interests
will be most easily awakened, and that the work will be less stereotyped
by shadows of impending examinations. In some schools a compromise
is effected between these two opinions—viz. that a considerable amount
of biology and nature study is advisable and possible in the earlier years,
between 11 and 13, and the subject dropped except for incidental refer-
ences in relation to both chemistry and physics until the age of 16, when
the child’s experience enables it to appreciate the more important lessons
biology has to teach.

The influence of examinations has been restrictive, so that in many school
intensive study of some parts of a subject has displaced the conception a
a more liberal scientific education.

There seems no reason to think that the introduction of General Science
into schools will render the science teaching more costly. q

GENERAL SCIENCE IN SCHOOLS 329

The chief causes of the neglect of Biology in schools are said to be:

(a) The apparent absence of any strongly expressed demand from
parents and others interested in education.

(6) Inertia and lack of initiative in the face of established custom in schools
in which only chemistry and physics are taught.

(c) A shortage of teachers who have studied biology during their
University career.

When a sufficiently strong demand develops there is plenty of evidence
that many teachers will be willing to acquire the necessary knowledge.
Some Local Education Authorities and other bodies have already organised
holiday and evening classes to meet this end.

Out-of-school activities form an important part of the science teaching
in many schools. It is satisfactory to note that the need for caution against
indiscriminate collecting of biological material is being emphasised and the
desirability of making adequate provision for such material encouraged.

Conclusions —We suggest that :

General Science should be taught in all secondary schools and on all
“ sides ’ of suchschools, inasmuch as a knowledge of General Science forms an
essential part of a liberal education. It should be regarded as an essential
element in a school curriculum, and after the lapse of an agreed number of
years no School Certificate should be granted unless the school is certified
as efficient in this respect.

A course should not be called General Science unless it provides a co-
ordinated survey of physics, chemistry and biology, using these words in
a wide sense. ‘The essential features of such courses should be constant
emphasis that Nature is not partitioned into special sciences but that prac-
tical problems can be attacked by a scientific method which is much the same
whether, for convenience, the problem is considered in terms of one or
other particular branch of knowledge. ‘The technique of the sciences must
often differ, but every teacher should take care to draw attention to their
essential unity of outlook.

So far as is practicable under the present system of School Certificate
Examinations, the teaching of General Science should take place free from
the restrictive influence of examinations. It is especially important that
when General Science is taken in all schools there should be wide liberty
of choice of emphasis so that teachers may follow to some extent their own
interests and make full use of the school environment. Care will be neces-
sary to avoid inexact and unscientific teaching when a very wide syllabus
is in use.

University authorities responsible for the conduct of University Entrance
Examinations in Science should demand that those candidates who propose
to proceed to a degree in Science should have received a preliminary ground-
work of General Science.

A more intimate system of co-operation between school and school might
overcome many of the difficulties of material and equipment experienced
by some schools in the teaching of biology.

There is a shortage, not so much of qualified botanists and zoologists as
of teachers who possess the particular kind of ability and training necessary
for the making of efficient teachers of biology.

General Science demands in a teacher wider knowledge and understanding
of scientific procedure than the specialist subjects do. To be effective and
stimulating the teacher must have real experience of the practical side of
all three main divisions of the subject—biology, chemistry and physics.

N

330 REPORTS ON THE STATE OF SCIENCE, ETC.

VII. THANKs.

For their valued assistance in supplying the necessary information the
best thanks of the committee are tendered to the—

(1) Heads and Science Teachers of individual Schools ;

(2) Assistant Mistresses’ Association ;

(3) Association of Women Science Teachers ;

(4) Assistant Masters’ Association ;

(5) Headmasters’ Conference ;

(6) Incorporated Association of Headmasters ;

(7) Science Masters’ Association.

SCIENCE TEACHING IN ADULT EDUCATION.

Report of Committee appointed to consider the position of Science Teaching
in Adult Educational Classes, and to suggest possible means of promoting
through them closer contact between Scientific Achievement and Social
Development (Prof. J. L. Myres, F.B.A., Chairman; Mr. C. E.
BROWNE, Secretary; Major A. G. Cuurcu, D.S.O., Dr. LILIAN
CLaRKE, Miss E. R. Conway, C.B.E., Prof. C. H. Descu, F.R.S., Sir
RICHARD GREGORY, Bt., F.R.S., Mr. S. R. HumBy, Miss H. Masters,
Mr. E. R. THomas. Co-opted: Mr. A. Clow Forp, Dr. C. W.
KIMMINS).

CONTENTS

I. Introduction. II. Abstracts from Replies to Questionnaire.
III. Suggestions and Recommendations. IV. Bibliography.
V. Appendix.

I. INTRODUCTION

OnE of the most direct reactions of general culture to industrialisation was
the establishment, in the greater centres of mechanical production, of
‘Mutual Improvement’ Societies, Literary and Philosophical Institutions,
and (rather later) of more specialised Field Clubs and Natural History
Societies, side by side with Archaeological and Architectural Societies, the
offspring of the romantic movement which was so closely linked historically
with the industrial. Most of these associations were literally for ‘ mutual
improvement’; the best informed or most voluble amateur lectured to the
rest ;, apparatus was home-made ; where a ‘ magic lantern’ was available,
the slides were hand-painted. London was far off. When the British
Association was founded in 1831 it was explicitly to bring leading scientific
men from London and the Universities into occasional conference with
local workers, as well as local workers with each other.

It was in the subsequent half-century of this movement, thus assisted by
the British Association, that quite naturally the great period of popular
awakening to the value of science took place. The great controversies of
the period, at times passionate and dramatic, fired popular imagination and
enthusiasm, and gave force and power to the claim that science should find

SCIENCE TEACHING IN ADULT EDUCATION 331

its way into the curricula of established teaching. 'The result was the
establishment of many new institutions with an almost exclusively scientific
outlook. To such an extent, indeed, has ‘ science’ been accepted as an
element in national life that some have actually asked whether the British
Association has not now fulfilled the function for which it was called into
being.

But such a view is facile : for while it is true that the establishment of the
younger Universities, University Colleges, ‘Technical Colleges, and so on,
offer facilities almost undreamed of in the half-century following the
foundation of the British Association, these facilities (along with which
must be reckoned also a great deal of ‘ science ’ teaching in schools of many
different types) by reason, perhaps, of one of their main virtues—the
insistence upon the rigour of exact laboratory methods—have failed to reach
effectively a large section of the population ; and notwithstanding these
great facilities, the number is probably still large who, by reason of geo-
graphical circumstances, of mental aptitude, of temperament, and of
upbringing, regard science and its works with casualness, suspicion, and
hostility—even with contempt.

. This body of people has long offered a field for investigation, and a problem

for which, perhaps, solution would not be easy; a field and a possible
problem, however, that come very definitely within the special purview of
the British Association. What can be done for those whose early training
left them uninterested in science, or critical of it, or whose daily work has
prevented them from actively maintaining their interest. by means of
institutions with laboratory facilities ?

Meanwhile, that older provision of ‘ mutual improvement,’ through local
societies and institutes has, for the most part, given place to modern urban
Universities and Technical Colleges. _What remains has been drained of
its energies by the concentration of scientific workers into centres of
endowed research; by improved access to London, ‘and the growth of
provincial public libraries; and unfortunately, also by the inclusion of
formal scientific studies, and even of what has come to be called ‘ nature
study ’ among ‘ school subjects’ ; voluntary work, and original observation
and experiment, have been domesticated and systematised ; and with other
social changes has come, in some field clubs, some restriction of the social
range of customary membership ; with the result that much accommodation
and even equipment is no longer put to full use, or even to its original
purpose of the ‘ mutual improvement’ of artisans.

There were positive reasons, too, for more rapid growth of organised
“adult education’ in literary, historical, and economic subjects than in
scientific With these the present inquiry is only concerned in so far as
they show that the number of adult classes in science is relatively rather
than absolutely small. Not many votes are needed to, decide whether
a centre shall devote itself to science or to an ‘ arts’ subject ; and the choice
of subjects is in practice much wider in ‘ arts’ than in ‘ science.’

There has evidently been, however, a general impression that scientific
subjects have not recently held the place in adult education that might
have been expected in view of the large (and ever-growing) influence of
scientific achievements on the general course of events, and especially on
social development.

The Place of Science in Adult Education has, indeed, been the subject of
several inquiries already. At Newcastle in 1916 the British Association
received and discussed the report of a Committee (appointed in June of that
year) on the Popularization of Science through Public Lectures; and its
Secretary, Sir Richard Gregory, pressed home the main argument of this

332 REPORTS ON THE STATE OF SCIENCE, ETC.

report in his Presidential Address to Section L at Hull in 1922. Meanwhile,
in 1921 the Board of Education constituted its Adult Education Committee,
and this Committee’s Report No. 8, on Natural Science in Adult Education,
appeared in 1927. The Sixth Annual Conference (1927) of the British
Institute of Adult Education dealt expressly with Science and Adult
Education and published its proceedings in full. In 1931 the Workers’
Educational Association, at its Annual Conference at Nottingham, considered
‘the possibilities of stimulating further interest in the study of science on a
non-vocational basis’; and its Executive Committee’s Report (Central
No. 198A) on this subject was presented in February 1932.

In addition to specific suggestions to its own District Secretaries, and
general recommendations as to wider use of films in science courses for
adults, that Committee strongly endorsed the opinion that ‘ within the
restrictions imposed by the interests of the students and the conditions of
work , . . the primary function ’ of science teaching in tutorial classes ‘ is
to make the student acquainted with the broad outlines of the great scientific
principles exemplified in familiar phenomena and applied to the service of
man.’ Further ‘ our classes in natural science should quite definitely be of
a character which will tend to attract the uninitiated. We do not wish to
cater for the members of scientific societies, etc., to the exclusion of the
ordinary citizen, who has little or no scientific knowledge. What we desire,
is to see our classes take the form more of a study of the action and reaction
between scientific knowledge and social life. We feel that it is only in
relation to the question as to how far and in what ways natural science
influences and affects society, that our classes can maintain their interest in
subjects of this character.’

During the summer of 1932 the Workers’ Educational Association
suggested to the British Association that some kind of joint committee might
usefully discuss the place of science in adult education, with a view to more
extensive work. At the York meeting the Educational Science Section
regarded this project as part of the larger question of promoting closer
contact between scientific achievement and social development, and
recommended the appointment of a Committee ‘ to consider the position of
Science Teaching in Adult Education classes, and to suggest possible means
of promoting through them closer contact between scientific achievement
and social development.’

The Committee’s first task was to ascertain by direct inquiry the amount
of progress made in the establishment of science classes during the six
years since the Board of Education published their Report on the subject in
1927. Accordingly, a questionnaire was sent to the Board of Education,
the Extra-mural Departments of the Universities of Great Britain, the
Education Department of the London County Council, the Workers’
Educational Association, the British Institute of Adult Education, the Young
Men’s Christian Association, and to many other institutions promoting and
controlling Adult Education, as well as to individuals interested in it. ‘The
main points to be ascertained were :

The present position of science teaching in adult classes for non-vocational
studies, and the conditions limiting or inhibiting increase in the number
of courses in natural science.

Particulars of the organisation and policy of various bodies controlling and
promoting such courses.

The methods usually adopted for obtaining teachers suited to adult teaching
of natural science.

Means adopted for popularising science studies among adult students. ~

The supply of science books, equipment, and materials.

SCIENCE TEACHING IN ADULT EDUCATION 333

Bibliography of science teaching in adult education.

Details of any interchange and comparison of field work and other observa-
tions conducted by adult classes, especially in regional studies and in
co-operation with existing Field Clubs and Philosophical Societies.

The replies were accompanied by many valuable memoranda, and in
addition the Committee have had access to two important surveys recently
completed :

(a) On Adult Education in London, undertaken by the London County
Council in response to a questionnaire from the Board of Education in
I93I and now incorporated in Paper No 11 of the Adult Education
Committee of the Board.

(b) On the Study of Science in Adult Classes, by a special Committee of the
W.E.A., published in 1932.

The Committee feel, therefore, they are in possession of the latest data
available, a digest of which is given below. They gratefully acknowledge
the valuable assistance they have received from many who have readily and
ungrudgingly responded to their requests for information. A complete list
of those from whom memoranda and letters have been received will be
found in the Appendix.

II. ABSTRACTS FROM REPLIES TO THE COMMITTEE’S QUESTIONNAIRE.

The replies to the questionnaire may be most conveniently dealt with
under the following headings :

1. The general organisation and control of adult education (p. 333).
2. The present position of science teaching in adult education (p. 335).
(a) The extent of the demand for science subjects.
(b) Explanation of the present small demand.
3. Conditions adversely affecting the adoption of science subjects (p. 337).
(a) The apparent remoteness of the exact sciences from everyday
experience (p. 338).
(5) The general absence of any real knowledge of science in the average
adult (p. 339).
(c) The difficulties of providing adequate accommodation and equip-
ment for practical work (p. 339).
(d) The difficulties of obtaining an adequate supply of suitable lecturers
and tutors (p. 341).
4. Teachers—lecturers and tutors.
Qualifications and characteristics desirable and methods of securing an
adequate supply (p. 342).
. Aims and purpose of science teaching in adult education (p. 344).
. Aims and motives of students attending adult science classes (p- 347).
. Propaganda and publicity (p. 348).
. The supply of (a) science books, (b) apparatus and material (pp. 351-2).
. Inter-comm»nal co-operation in the science work of adult classes (p. 353).
. Assistance from Local Scientific Societies (p. 353).

oMO ON DUN

Lal

1. The General Organisation and Control of Adult Education in
Great Britain and Northern Ireland.

_. The agencies through which Adult Education in this country is carried
on form a complex organisation, and vary remarkably in different districts.

334 REPORTS ON THE STATE OF SCIENCE, ETC.

There are three principal agencies : the Extra-mural Departments of Univer-
sities and of University Colleges, the Workers’ Educational Association, and
the Local Education Authorities. Working with these or independently are
other bodies, of which the chief are: the Young Men’s Christian Association,
the Educational Settlements Association, the National Industrial Alliance,
the Adult School Union, the Co-operative Union, and the National Federa-
tion of Women’s Institutes. Besides these a number of Colleges are
recognised under the Adult Education Regulations for grant purposes : the
Ruskin College, the Catholic Workers’ College, Fircroft College, Hillcroft
College, and Coleg Harlech for residential students ; the Working Men’s
College, and Morley College for non-residential students ; also Mary Ward
College, Toynbee Hall and others.

Co-operation between the principal bodies is through Joint Committees
consisting of representatives of the Universities, the W.E.A., the L.E.A., and
other associations or societies of a district.

The Adult Education Committee of the Board of Education exercises an
important coordinating influence, through its Adult Education Regulations
for the award of financial assistance. Local Education Authorities are more
and more directly promoting Adult Classes, in addition to assisting local
Joint Committees by grants of money or by providing rooms, teachers, and
equipment free of charge.

Full particulars of these bodies and their inter-relationships are supplied
by the Adult Education Committee of the Board of Education in its Paper
No.9, Pioneer Work and other Developments in Adult Education; Paper No. 10,
The Scope and Practice of Adult Education (1930) ; and Paper No. 11, Adult
Education in relation to the Local Education Authority (1933). ‘The last-
named contains an interesting history of the Adult Education Movement.
It traces the development from the earliest Night School at the beginning of
the nineteenth century to the complicated structure of Adult Education
organisation of the present time ; and describes fully the schemes under
which Adult Classes are organised and maintained in different districts
throughout the country.

The arrangements made for Adult Education within the University area
of Bristol will serve as an example of the co-operative organisation between
various bodies interested :

‘In the University area, which covers the cities of Bristol, Bath and
Gloucester, and the counties of Gloucestershire, Somerset, Wiltshire and
a part of Dorsetshire, there is a co-operative scheme between the various
Bodies concerned in Adult Education including the University of Bristol,
the Local Education Authorities, the W.E.A., the Y.M.C.A., the Adult
School Union, the Rural Community Councils and various Bodies. Under
this scheme any type of class can be provided from a single pioneer lecture
to a full tutorial class or extension lecture course. Some 80 short
courses of four to six lectures are given in villages, and the W.E.A. provides
over 100 terminal and one-year courses. During the present session there
are 18 University Lecture Courses and 30 Tutorial Classes financed by the
University.

‘There is a Consultative Committee composed of representatives of all
the Bodies concerned in each county. ‘Tutorial Classes are organised from
Bristol by a Joint Committee of the University’ and the W.E.A. Extension
Lectures are organised by the University directly.

‘The Courses for which the University is responsible are financed from
four sources : Grants from the Board of Education, grants from the Local
Authority, fees from students attending the Courses, University Grant -to
make up the deficiency.’

SCIENCE TEACHING IN ADULT EDUCATION 335

Two institutions which are concerned with adult classes for women only
have so far not considered the question of science teaching in any form,
viz., the Women’s Institutes and the Townswomen’s Guilds.

The instruction given in the Women’s Institutes has been mainly of
a practical character, but their aim is to develop a sense of citizenship and
spirit of social service. ‘The general secretary, the Hon. Frances Farrer,
expresses the view that as these aims become more fully realised there is
likely to be an increasing interest in and desire for further knowledge of
scientific developments in relation to social and practical matters. She
stresses the view that success would be likely to depend largely on the
ability of the lecturer to approach the subject from the practical aspect and
to deal with it in a non-technical and interesting manner.

The Townswomen’s Guildsare still in process of formation. It isintended
that they should take the place, in the towns, of the Women’s Institutes in
the country. A Central Committee divided into sub-committees for Civics,
Handcrafts and Homecrafts, is considering the question of programmes and
the publication of a monthly journal, The Townswoman. It seems possible
that these Guilds might in future provide a field which has as yet hardly
been touched for arousing an interest in science in relation to practical and
social problems. (See also Suggestion 9, p. 356.)

2. The Present Position of Science Teaching in Adult Classes.

In the Board of Education Report (1927) on Natural Science in Adult
Education it is noted that, ‘ compared with the growth of interest in English
Literature, Music and the Drama since 1921, there has been no corresponding
growth in the number of classes in Natural Science.’

Statistics collected in the course of the present inquiry show that there
is still a strange neglect by adults of this branch of study, compared with
such subjects as Literature, History, and Economics. The number of
Science Courses is not more than approximately 6 per cent. of the total
number. ‘Taking the Board of Education figures for the same period and
referring only to those courses accepted under the Adult Education Regula-
tions, the percentage of science classes for the whole of England and Wales
is 4-6 per cent. The Extra-mural Department of London University
reports :

“ Out of a total of 1,009 courses and classes in the years 1926 to 1932 only
4I were on science, viz., Biology 19, Anthropology 15, Astronomy 3,
History of Science 2, Physiology and Hygiene 1, and one course of a general
character, “‘ Science and Daily Life.” The average attendance at the
courses was small. In University Extension Courses in general an average
attendance of 60 to 70 is usual in the London district; but for science
courses within the same period named it was less than 40. The limited
interest shown by the public, even when a science course is provided,
undoubtedly discourages Local Committees responsible for the organisation
of University Extension Courses from choosing this subject.’

In Durham and District ‘ attempts to form classes for the study of
scientific subjects has met with little or no response.’

In 1930 the Co-operative Union included over 2,500 students of such
subjects as Industrial History, Economics, Public Health, Local Government
Taxation ; through their associated Guilds the Union is in touch with
a large field of educational work, e.g. the membership of the Guilds was in
that year 61,000 in England, and 27,000 in Scotland. The reply of the
Secretary of the Royal Arsenal Co-operative Society (Educational Depart-
ment) that ‘ there is no demand for science,’ suggests how little science is
considered as one of the determining factors in social developments.

336 REPORTS ON THE STATE OF SCIENCE, ETC.

2A. But while this may be true for a large number of districts, it is not
true of all. An Extension Lecturer of long experience believes that there is
everywhere a real demand for science, properly handled, and attributes the
falling off in attendance at University Extension Lectures since the war
largely to the financial stringency of the times. Other memoranda point to
a distinct awakening of interest in science studies. From Loughborough
College the report is optimistic :

‘ Statistics show there is a real demand for science classes and that it is
growing. Moreover, the comparatively high standard of attendance and
work attained by science classes is a marked feature of adult education in
Leicestershire. The study of science in our villages is likely to increase
considerably during the next few years, and every effort will be made to
provide the right kind of tutor.’

Mr. S. Myers, Head of the Deptford Men’s Institute, writes equally
emphatically :

‘I have thirteen years’ experience with further education amongst
working men in London following a year or two with similar groups of
working men in Lancashire behind my opinion that there is no lack of
interest in natural science. On the contrary, I have observed—particularly
since about 1920—a swing away from social, economic and political interests
towards scientific interests.’

A steady increase in the number of science classes is reported from the
Western districts of the W.E.A. organisation, of which the Universities of
Bristol and Glasgow are the respective centres, although relatively to other
subjects the numbers for science are still small. The Extra-mural Depart-
ment of Queen’s University, Belfast, also reports a steady and an increasing
demand.

‘ There is at present a substantial demand in the West of Scotland for
adult classes in natural and physical science, the only subject group in which
there is a markedly larger demand being English language and Literature ’
(Glasgow).

‘It is difficult to measure the exact extent of the demand for science
studies.’ In most classes, however, ‘ there are students who are interested
in such studies even where there are not a sufficient number of students to
justify the forming of a class. The demand (in Dorset) for science courses
of an elementary and general type exists quite definitely, and is probably
growing ’ (Bristol).

In the Y.M.C.A. organisation there is said to be a considerable demand
for presentation of scientific subjects in a non-technical and popular form.
‘This demand is being met mainly by popular lectures, either in short
courses or series, or in a programme of miscellaneous, popular lectures.’

Our general impression is that the actual demand for science teaching is
small in most districts, almost non-existent in some, but growing and
becoming quite considerable in several, especially in parts of the Midlands
and in the Western districts of England and Scotland.

2B. Many experienced observers record the opinion that a much larger
latent demand exists, but that there are limiting and inhibiting conditions,
not easily removed. In the W.E.A. Science Report (1932) it is suggested
that ‘ the lack of interest may be more apparent than real owing to the fact
that Courses in Natural Science have seldom appeared in the lists of possible
subjects, with the consequence that any potential interest in such subjects
has not been cultivated.’

A reason for this is given by other writers :

‘ The initiative in arranging classes is taken by one or two educated people

SCIENCE TEACHING IN ADULT EDUCATION 337

who are interested in adult education, and if they, as frequently happens,
have a purely literary outlook, science classes will not be chosen... .
The logical and experimental technique of science is now so specialised
that ordinary men and women tend to accept it as beyond their comprehen-
sion, and are discouraged by the circumstance that the point at which they
must begin their studies appears very remote from the results which arouse
their interest. . . . The reason for the comparative lack of development
of science studies in science classes in the country generally is, I think,
primarily the failure of those responsible to put the case to prospective
students. In spite of the tradition that the adult education movement exists
to satisfy the spontaneous demands of students themselves, groups are very
anxious to have suggestions made to them, and are apt to be influenced by
those suggestions. Since the organisers themselves are frequently interested
in economic and social problems, that tends to create a bias in favour of
those subjects. There are, however, difficulties connected with the teaching
of science which do not affect other subjects ; and that also must be regarded
as a reason for the backwardness of this side of the work. (Prof. R. Peers,
Nottingham U.C.)

A report on the position of science teaching in Adult Classes in the
United States of America shows a somewhat similar attitude on the part of
the general citizen. ‘The Secretary of the American Association for Adult
Education writes :

“I do not feel that the evidence is at hand to support the belief that there
is an actual indifference to natural science subjects on the part of American
adults. As a matter of fact, such evidence as exists points in the other
direction, for our science lectures, where offered, are usually extraordinarily
well attended and the interest expressed is keen. I feel quite sure that the
relatively unimportant place held by science subjects in the adult education
offerings in this country is attributable first, to lack of adequate financial
support; second, to the lack of availability of qualified teachers at the
secondary level ; and third, to the lack of interest in adult teaching on the
part of qualified teachers of science at the collegiate level. In the past the
attitude of the research staffs of our universities and scientific institutions
—the Carnegie Institution of Washington would be a notable exception—
has been to avoid adult teaching of scientific subjects wherever possible on
the ground that such “‘ popularization ”’ of necessity involved vulgarization
and consequent loss of dignity to the research profession.’

3. Conditions adversely affecting the Adoption of Science Subjects.

The poor response to science courses is probably due to many
conflicting causes. The chief of those adversely affecting the growth of
science teaching in Adult Education may be stated under the following
headings, but it must be realised that they are intimately linked in their
effect, and form a very complex problem for organisers.

(a) The apparent remoteness of the exact sciences from every-day
experiences, and the lack of mathematical training in many who are
interested.

(6) The general absence of any real knowledge of science in the average
adult, who therefore does not manifest much keenness about
attending u class owing to a tendency to regard science as a study for
* clever ’ people only.

(c) The difficulties of providing adequate accommodation and equipment,
even for ordinary demonstration experiments by lecturers or tutors ;
still more for any practical work by the student.

N 2

338 REPORTS ON THE STATE OF SCIENCE, ETC.

(d) The difficulties of obtaining an adequate supply of suitable lecturers
and tutors.

3a. Apparent Remoteness of the Subject.

It is becoming more generally realised that formal courses of work on
various branches of science, such as elementary physics or chemistry, are
misdirected and unattractive, lacking in essential elements of Adult
Education. They fail to awaken interest or understanding, and lead to an
entire misconception of the practical value of science studies. On the other
hand, in all cases when the approach is made along popular lines—when the
courses deal, frankly and simply, with the real issues of life, and touch the
everyday experience of the students—classes are well attended and high
enthusiasm is engendered. Indeed, the testimony of many experienced
teachers shows that starting with these simple natural interests the work
has frequently developed a high standard of study, and led to the forma-
tion of clubs and societies that have done good work along both social and
scientific lines in the most unlikely neighbourhoods, and often under
very discouraging conditions.

“The general public regards science courses as too technical and
specialised for them to understand . . . as too remote for ordinary life to
interest them. . . . The great majority of people are not interested in
botany qua botany, or in zoology qua zoology, but they are interested in the
human and social applications of botany and zoology. . . . Most people
are not interested in data, but in principles and generalisations. .. .
(Dr. Brierley, Reading).

Dr. Brierley further draws attention to the type of lecturer who tends to
kill interest at the outset by following too meticulously the details of
a subject, to the exclusion of the more general aspects, and by using academic
language or technical jargon in place of pictorial terms in which to translate
the messages of science. Compared with normal University education, he
says, ‘ the approach must be made with different ideals, from a different stand-
point, seen in a different perspective, and carried out witha different technique
. . . the general public is keenly interested and wants to know what science
can tell it, and what science cannot tell it of real life, but it has no use for
academic futilities and unreal issues, which are so often put forward in
answer to its demands.’

“The response to the science courses largely depends upon the method
of presentation. Students are invariably attracted by a scientific lecture if
care is exercised in the choice of title, and there is something to see as well
as to hear . . . the adult student, without guidance, is very prone to
select from those subjects offered which seem likely to throw light upon his
immediate problems of life . . . hence the choice of economics and allied
subjects in the first place.” On the other hand, ‘ If the scope of scientific
classes is put before prospective students with the same degree of persuasive
explanation that is commonly used with other subjects, then a greater
response would equally follow ’ (Dr. A. J. Grove, London).

‘The ordinary man in the street is afraid of science. He knows nothing
about the nature of science ’ (Dr. Norman Walker, Leeds). For this reason
he strongly urges the need to bring the students right close up to things, to do
experiments themselves and: so learn through their own interested observa-
tions the real meaning of science. His method is fully described in a paper
published by the British Institute of Adult Education in their Report of the
Conference held in 1927.

‘It is absolutely essential that every lecture should be illustrated either

SCIENCE TEACHING IN ADULT EDUCATION 339

by experiments or, when these are not possible, by plenty of specimens and
lantern slides. I am certain that the experimental illustrations are some of
the most important parts of the lecture, and the results obtained from them
fully compensate for the time spent in collecting the necessary materials,
for the difficulties of transporting everything required for the demonstration,
and of carrying out experiments without gas, electric light, or a water supply.
In districts where there is a considerable demand for science classes, and
where courses are standardised, it would be possible for sets of apparatus
and materials to be sent to each centre for the lecturer’s use throughout
the course, but this would not be worth while until the demand increased ’
(Dr. A. W. Chapman, Sheffield).

To remove the inhibiting effects of those conditions referred to in (a) and
(b) above, lecturers and tutors need to approach their task in a very different
manner from that adopted for the ordinary student of the university or
technical college.

3b. Lack of Elementary Knowledge.

There is often lack of previous preparation of the students. ‘Inadequate
or unsuitable previous education is a difficulty in the case of some subjects,
especially those requiring mathematics. This difficulty rules out Physics,
Astronomy, etc., except as subjects for popular classes. It is impossible to
have Tutorial classes in those subjects, since the work cannot be carried to
a sufficiently advanced stage. ‘The result is a tendency to concentrate on
two main groups of subjects—Biology and Evolution; and Chemistry,
Health and Hygiene, etc. A good deal might, however, be done to develop
the study of subjects such as Geology, Geography and Nature Study’
(Prof. Peers, Nottingham U.C.).

3c. Inadequate Accommodation and Equipment.

Many correspondents refer to the difficulties under which science labours
through inadequate accommodation and equipment. This was mentioned in
the British Institute’s Conference (pp. 332, 356),.as ‘ prejudicial to the growth
of the Adult Education Movement generally and to the increase in the
number of science classes particularly.’ The difficulty of securing satisfac-
tory accommodation is still a serious obstacle. ‘The want of suitable
accommodation is often an adverse factor in the arrangement of science
courses which require experimental illustration. Most courses and classes
are held on premises not intended nor suitable for science work, and there
are usually no facilities for the use or safe keeping of apparatus ’ (London).

Classes held in the L.C.C. Men’s Evening Institutes are almost exclusively
held in the evening, in premises occupied during the day, as a rule, by
elementary schools. The limitations due to lack of equipment and accom-
modation wiil be obvious. At best, there is a ‘ practical room,’ furnished
with tables and chairs instead of the more usual classroom desks, and
designed, not for science teaching, but for practical, or handwork of various
kinds. Assuming, therefore, that there were a demand for serious science
studies of a non-vocational type, this initial handicap would make it impos-
sible to satisfy it under present conditions.

This difficulty specially applies in country districts, with few exceptions.
It is only on University premises and in a few technical and secondary
schools that any provision is made. In London, for example, with its
Literary Institutes and well-equipped secondary schools under the L.C.C.,
the demand for facilities for science courses could easily be met for some

340 REPORTS ON THE STATE OF SCIENCE, ETC.

years to come. Similar advantages are found to some extent in other
University cities. But outside these centres the difficulty of securing suitable
accommodation and adequate supplies of apparatus constitutes a really big
limiting factor in the organisation of science classes for Adult Education.
In all the most active centres for science work this position is emphasised.

In Nottinghamshire, ‘ When classes in biology, chemistry, etc., can meet
in a laboratory, it is possible to do useful work, but facilities of this kind are
available only in the University towns or in towns which have a secondary
school : even then it is not always possible to obtain the use of laboratories
for adult classes. Many of the classes, however, meet in small towns or
villages, and such elementary requirements as running-water and gas are
rarely available in the classroom. ‘Tutors have to take all their own
apparatus, and work with buckets of water, spirit lamps, etc. It is little
wonder they fall back to a great extent upon lantern ‘slides, or occasional
demonstrations, and the chief value of science teaching is lost to the
students ’ (Prof. Peers).

In Leicestershire, ‘the provision of the necessary accommodation,
equipment, and material is still very difficult. Most of the classes have to
be held in village schools which are, of course, not designed to accommodate
adult science classes. The resources of Loughborough College, however,
are available for the classes held in Leicestershire, and we are now able to
provide microscopes, a projector, and other equipment for the use of the
tutors. Occasionally students have been brought in from a village class to
have a meeting in the College, where more adequate equipment for demon-
strations is available. Some of the tutors have cars, and carry a considerable
amount of equipment to their classes. The students also provide some of
their own materials for experiment’ (R. J. Howrie, Loughborough T.C.).

In Glasgow, provision is made to meet the demands for science ‘ largely
through classes meeting at the University where laboratories are available.
At most outlying centres it has not been found possible to meet it so fully,
most of the equipment found necessary, in so far as it could not be provided
by the students themselves, has been taken from Glasgow.’

At Bristol, ‘ there is a certain difficulty with regard to equipment. This
does not apply in Bristol, where University laboratories are available.
Outside Bristol, and other large towns, it is not easy to secure equipment,
except for courses where instruments and material of a portable kind can be
used.’

The result is a fundamental limitation to certain kinds, and aspects, of
scientific study. One W.E.A. worker in Birmingham writes :

‘The serious study of science by groups of working people is a new
development in Education, and its point of departure is different from that
in schools and Universities. . . . It is found desirable to begin, not as
physics or chemistry, or biology, but with a mixed elementary introduction
to all these. This, in itself, has proved difficult to fit in with the ordinary
supply of apparatus, as it neither is a specialised science course nor hygiene,
nor nature study. This kind of teaching makes different demands on
equipment from the ordinary school or college course. It does not demand
expensive apparatus, so much as different apparatus, with consequent need of
storage place and opportunity for preparation.’

Even in London only three out of the twelve Literary Institutes organised
by the L.E.A. for Adult Education attempt any classes in science, and only
two of these possess any equipment for the work.

SCIENCE TEACHING IN ADULT EDUCATION 341

3d. Difficulties in obtaining Supply of Suitable Teachers.

The Board of Education Report (1927), p. 29, noted that ‘ the greatest
difficulty which is likely to beset the adult education movement in this
situation, is that of finding teachers of wide knowledge who are capable of
inspiring interest in Natural Science as a study of the conditions of human
action.’

The late Dr. Harold Wager pointed out that ‘the success of science
classes for adult students depends in a special degree on the character of the
teaching and the personality of the teacher. It is more difficult to secure
the right sort of teaching for adult students in science than in such a subject
as Economics.’

From London, Mr. G. H. Gater (L.C.C.) writes :

* As regards teachers of science, it is found that, as is the case with teachers
of any subject, some of them appeal more strongly than others to adult
classes. ‘The good teachers become known and their services are largely in
demand. Others, through inexperience of the special problems, do not at
first gain their audience, but under the guidance from the inspectors and
heads eventually succeed. Others again have not the right appeal, quickly
lose their students, and themselves drop out of the work.’

This difficulty of securing a sufficient supply of suitable teachers is shown
by the evidence received by this Committee to be still a considerable factor
in holding up the desired advance in science teaching.

The Secretary of the Oxford Delegacy for Extra-mural Studies writes :
‘ We could advance more quickly and more securely if we could get a better
supply of really suitable tutors and lecturers for adult classes.’

Similarly the Secretary of the Cambridge Board (Mr. G. F. Hickson)
writes: ‘In adult education demand does depend to some extent on supply
(of teachers). It might be very well increased if there were more lecturers
and tutors capable of dealing with scientific subjects in a suitable fashion for
this purpose,’ but ‘ no special steps have been taken by the Extra-mural
Board to attract and secure the services of suitable teachers.’

The Registrar for the London Extra-mural Department says :

“The supply of lecturers available for, and capable of, giving science
courses intended for adult students for non-vocational purposes is
undoubtedly limited, and this in its turn reacts on the demand. . . . Most
science teachers of sufficiently high standing to attract the general public are
too specialised in their work to be prepared to offer a course of the kind
required.’

Prof. Peers (Nottingham U.C.) lays stress on the comparative scarcity
of suitable teachers for adult science classes. ‘Science teachers in
Universities are usually extreme specialists with little interest outside
their own subjects. In particular they usually lack human interests, and
the teaching, therefore, is apt to appear arid and meaningless to groups
of adult students whose interests are mainly social. Not only that,
but their lack of outside interests and contacts makes it difficult for them
to acquire the right technique of teaching. They are often less skilful
as lecturers than those who have to depend mainly on the spoken word
for the presentation of their subject. On the other hand, the possibility
of using experiments and demonstrations undoubtedly gives them an
advantage.’

Mr. G. C. Robson, British Museum (Natural History), ascribes the
decline of popular interest in science to :

(x) ‘ Lack of good lecturers, due (a) to increased specialisation, and (8) to

342 REPORTS ON THE STATE OF SCIENCE, ETC.

the increase in remuneration of scientific workers which may have made it
unnecessary for many to seek evening work to supplement their salaries.

(2) ‘ The rapid advance in all branches of science over the period under
review ’ which ‘ may have tended to make the scientific worker obsessed
with the pressing problems of his own job and little inclined to commit
himself to popular audiences ; willing to deal with specialised matter to
a University class, but not to a popular audience.’

On the other hand, those writing on behalf of the Local Education
Authorities of London and Leicestershire, of the Extra-mural Departments
of Bristol, Manchester, and Liverpool, of the Y.M.C.A., consider that at
present the supply of suitable teachers is adequate for the demand.

With these conflicting opinions it is difficult to arrive at a just estimate,
but it may be noted that on one side reference is mainly made to the
supply of teachers to meet an increased demand; on the other, to the
supply of existing demand for science studies. Another opinion is that
there is a wider and more numerous field for the selection of teachers where
only lectures are required, than where tutorial work is to be undertaken ;
a man who is quite a successful lecturer may not necessarily be so happy in
the more intimate and less formal work of a tutorial class.

From the Extra-mural Delegacy at Oxford, Rev. F. E. Hutchinson
makes the practical suggestion that :

“A panel of teachers suitable for adult classes in various sciences might
be drawn up by the British Association, and that the University Committees
should be allowed to communicate with the secretary of the panel when
particular demands arise.’

4. Qualifications and Characteristics of Teachers suitable for Adult Classes.

Much evidently depends on what are considered to be the characteristics
and qualifications of a suitable teacher. It is always possible to get plenty
of teachers of various types, but it is another matter to attract men or women
of the exceptional type required for the successful handling of science
courses in Adult Education. Dr. Brierley (Reading U.) requires ‘ a man
of personality and imagination, with a gift of speaking, and wide human
interests in addition to his equipment of scientific knowledge, capable of
always interesting a public audience even if discussing quite technical
problems, of seeing things from their angle and in their perspective, possess-
ing the power of speaking accurately, yet rather pictorially in simple,
every-day language, always illustrating by facts and phenomena of everyday
life and common experience, of speaking clearly and articulating his words
distinctly, and of presenting his matter in a simple, logical form, so that
connecting links are always clear.’

Dr. A. J. Grove (London) expresses similar views in a slightly different
way :

“The tutor of a tutorial class has to be something very much more than
a mere purveyor of facts, scientific or otherwise. His business is not so
much to instil facts into the students’ minds as to cultivate an attitude of
mind. A purely academic attitude on the part of the tutor is worse than
useless in adult classes. In addition to a wide knowledge of his subject
and a facility of presentation, it is important that he should have a wide
experience of men and affairs, an outlook beyond the scope of his immediate
topic, and be keenly alive to points of contact between the matter he is dealing
with and everyday life.’

The problem is how to find such men, and when found how to induce
them to devote their services to the Adult Movement. The problem

SCIENCE TEACHING IN ADULT EDUCATION 343

involves the consideration of career and finance, and turns on the question
whether science teaching in adult classes should be a whole-time occupation
or part-time. One aspect of the situation from the young graduate’s point
of view is that since such work does not lead to a career in itself it leads to
a constant conflict of interest between the tutorial work whereby he gets his
living, and the research work on which his future depends.

It is further suggested by Dr. Brierley (Reading) that :

‘The whole-time teacher, separated as almost inevitably he must be
from active research, or intimate contact with such research, would tend to
lose his inspiration, and to become simply something of a gramophone
record.’ ... On the other hand, ‘most scientists holding posts in
Universities, or in research institutions, already find their lives over-full,
and have not the time and energy to devote to the type of missionary work
required in adult education.’

Some difference of opinion has been expressed as to the best kind of
experience and training for those who undertake adult classes. Oxford
opinion is decidedly in favour of high university qualifications, and experience
in university teaching, rather than in the employment of science masters,
or of amateurs.

At Bristol : ‘ For University classes the standard adopted should be that
lecturers and tutors should hold a good honours degree in the subject
taught.’

At Glasgow: ‘A high standard of knowledge of the subject, such as
may be looked for in members of a University staff, while almost indis-
pensable, is not the only essential. It is essential that tutors should be
inspired by enthusiasm for their subject and should be capable of presenting
it in such a manner as to arouse the enthusiastic interest of laymen. They
must be capable, too, of appreciating the questions and the point of view of
their students, remembering that neither interest nor the equipment of the
adult student is ordinarily the same as that of the professional scientist, or
of the University or Technical College student.’

At Liverpool ‘the staff is selected by the University; at present all
members are of the internal University staff. The engagement is for one
year and renewed for whole courses.’

On the other hand: ‘The most suitable teacher is of the “‘ general
practitioner ” type rather than the highly specialised. It is most important
that lecturers should have kept abreast of modern developments in science ’
(City Literary Institute).

‘The outlook and qualifications of the teacher of adults will differ very
considerably from those of the internal University teacher ’ (Dr. Norman
Walker, Leeds).

“On the whole, it is probable that secondary school masters are more
hopeful material than university lecturers ’ (L. A. Fenn, Birmingham).

The choice of teachers is the more important because, as Dr. A. J. Grove
(London) puts it : ‘ The wrong kind of tutor can do so much harm. How
to find the right one, is not easy to answer. If only our primary and second-
ary education was more concerned with “ educating ” and not so much
with imparting erudition, then not only would there be many more adult
students, but the right kind of tutors would be forthcoming. At present,
apart from a radical change in scholastic and academic teaching, it is difficult
to see how this problem is to be solved.’

One of the recommendations accepted by the Council of the W.E.A .
and put forward by their special Committee of Inquiry, is that ‘ District
Secretaries should prepare a panel of scientific lecturers and tutors in their
areas who would be prepared to undertake either Tutorial Class work,

344 REPORTS ON THE STATE OF SCIENCE, ETC.

One-Year Class work, Extension work, or popular lecture work in Natural
Science.’

Many men possessing the qualities desired would, no doubt, readily
respond to an invitation to take charge of science courses, if the remuneration
was sufficiently attractive and assured. ‘The remuneration can be provided
if the classes are sufficiently well organised and attended, because they can
then earn the grant under the Board of Education regulations. But attend-
ances depend on the extent of the demand for science. Hence follows the
quandary—on the one hand it is the supply which creates the demand, and
on the other that the supply cannot be provided until there is a sufficient
demand to make it worth while.

5. Aims and Purpose of Science Teaching in Adult Education.

Several correspondents deal with the ‘ popularisation of science ’ in adult
classes. In this connection it is important to understand what are the aims
of those who are already teaching science, as well as of those who wish to
see the study of science more widely adopted in these classes. It is equally
important to know what are the desires that prompt (or might prompt) an
adult student to take up the serious study of any branch of Natural Science.
These two factors—the aim of the teacher, and the purpose of the student
—must meet somewhere in sympathetic co-operation, if a true appreciation
of science by people generally is to be assured.

The Committee is not primarily concerned with the provision for
vocational or technical training, but more particularly with the systematic
presentation of scientific methods and results, both pure and applied. But
it is realised that these two kinds of teaching often overlap in the same
course and also that the aims and motives of teachers and of students vary.

“'The purpose of the science lectures and classes in the evening institutes,
and in other institutions referred to, is purely cultural. "The aim is to
foster the good use of leisure and to satisfy the wishes of those who seek
to know something about science, what it has done for mankind and its
practical application in matters of daily life’ (G. H. Gater, L.C.C.).

‘If the important part taken by the Adult Education Movement in the
national life is to be shaped in the light of the rapidity of the changes which
are taking place owing to the increased application of scientific invention to
modern production, it is essential that the education which it provides
should be wide and liberal, and assign an adequate place in its scheme for
the teaching of science. The Adult Education Movement cannot afford to
neglect scientific thought and knowledge. Ignorance of the influence of
science should belong to the past, and we can only be confident of future
progress if we understand all the forces which are contributing to the
re-shaping of social life ’ (W.E.A. Science Report, 1932).

“The purpose of science teaching in adult classes is obviously not to
turn out specialists or experts; it is to make the student intelligently
interested in the world in which he lives and to enable him to understand
the fundamental facts of life. If he is taught to regard the world merely
from the economic and political point of view, his thinking will be one-sided
and incomplete. And the so-called ‘ cultural ’subjects, with no background
of scientific method, frequently lead to slovenly thinking, and a smug self-
satisfaction, which needs to be broken down by the discipline of scientific
study ’ (Prof. Peers, Nottingham U.C.).

‘From the point of view of the organisers, science classes, like all other
classes held under the Adult Education Regulations, are, in the words of

SCIENCE TEACHING IN ADULT EDUCATION 345

the Board’s Regulations, ‘ designed for the liberal education of adults.’
Such education must be something more than the imparting of information
about particular topics, and in the case of science teaching, as distinguished
from the teaching in literature and art, the purpose seems to be primarily
to cultivate systematic, accurate and impartial study of natural phenomena.
The teaching of science is concerned with the application of scientific
method to the explanation of a particular group of phenomena, but the
scientific attitude of mind is valuable in all studies, and the influence of
science teaching extends beyond the limits of formal classes in science’
(R. J. Howrie, Loughborough T.C.).

‘The aim which I feel should guide science courses of this type is to
arouse an interest in scientific outlook and method, to show what the
application of science has done to afford a better understanding of the world,
and a change in the conditions of human life, and to explain the function of
the scientist in modern society ’ (Dr. A. W. Chapman, Sheffield).

‘ Regarding the purpose of the science teaching in these classes, I do not
find that there is any marked divergence in the views of the organisers,
tutors, lecturers and members of the classes. In some instances, however,
an aim is implicit rather than explicit and a student who originally enters
a class with one purpose in view becomes interested as his study proceeds
in some other purpose which it serves. There is, too, a varying emphasis
on the different aims as between one tutor and another, and as between
different individuals within the class. The various purposes served by
study in these classes are:

‘(1) the provision of knowledge likely to be of interest throughout life,
either through equipping the student for a leisure-time occupation, or by
giving a wider meaning to the student’s own vocation, e.g. where a golf-
green keeper or park gardener studies general botany.

‘(z) the apprehension of science as a great co-operative enterprise of
mankind, the interest in science being part of the interest in human activity
leading to the satisfaction both of the curiosity and of the gregarious
characteristic of human nature. The study of science from this motive is
likely to promote social solidarity, giving to each a sense of unity with his
fellow.

*(3) through the study of scientific method to reveal thought processes
and the need for and method of exercise of powers of observation, criticism
and diagnosis. The achievement of this purpose is manifestly of great
importance enhancing the value of the student both individually and
socially.

*(4) to develop intellectual activity and to establish true self-confidence.

*(5) to trace the part which science and scientific achievement and
method have played and may play in moulding human society of to-day.

*(6) to furnish experience which each individual may correlate with his
whole experience to form his philosophy of life.

*(7) to form a bond breaking down barriers between different sections
of society and different ages. Parents frequently take these classes to
enable them the better to understand matters in which their children are, or
may become, interested.

*(8) in some cases to promote efficiency in vocation.

“This last aim, while not the primary purpose of these classes, is quite
justifiable, but it must occupy a subordinate place in adult education, and
should not be allowed to determine the course to the detriment of the other
purposes of such education. In this there may be a divergence in purpose
between tutor and organiser and some members of the classes. Mention
should be made of the equipment of students to play more efficiently their

346 REPORTS ON THE STATE OF SCIENCE, ETC.

part in working-class movements, an aim which has been present in the
minds of many associated with the Adult Education Movement. But this
purpose is achieved in the case of science through the other purposes, such,
for example, as (2), (3), (4) and (5) above. Ability to understand the point
of view of others which may well be fostered by such studies, may be con-
sidered as akin to (2), (3) and (7) above’ (D. M. Stewart, Glasgow).

Mr. S, Myers, Head of the Deptford Men’s Institute, writing in the light
of many years’ experience, and entirely as a matter of personal opinion, says :

‘ At the L.C.C. Men’s Institutes we adopt a special angle of approach.
We have found it not only sound but essential to proceed from the immediate
interests of the students or prospective students, and to build round them
a progressive educational course. A few examples may make the attitude
clear.

“(1) We have classes in ‘ Wireless.’ These have their origin in the fact
that most working-class homes possess a wireless set. Men talk wireless in
their workshops, in public-houses, and elsewhere. Realising this, we invite
men to meet a wireless expert once a week, thus focusing the wireless
interest in a class. A syllabus is framed to ensure that the class makes
a sound theoretical study of the subject.

‘ (2) The ownership of a motor-cycle leads to an interest in internal
combustion engines, magnetos, carburettors, electric lighting, etc. Here
again, men who own motor cycles or cars, or who aspire to own them, or
who drive other people’s cars, are drawn to classes in petrol engines (with
car lighting, ignition, and starting) held in the Men’s Institutes. ;

“(3) The widespread use of photographic apparatus leads in the same
way to an interest in lenses, light, colour, and the chemicals used in the
preparation of sensitised film and plates, and in the developing and printing
of photographs. Hence classes in “‘ The Chemistry of Photography ”’ at
several Men’s Institutes.

“(4) Poultry, rabbits, cage-birds and domestic pets are extensively kept
—by way of a hobby—in working-class districts. If fifteen or twenty men
can be brought together by a desire to know more about these creatures,
we open Poultry Keeping, Care of Animals, and similar classes.’

“In all these classes the instruction is at once practical and scientific.
Rule-of-thumb is discouraged, and the object is—as my examples may
indicate—to proceed from practice and observation to general principles
and thence to the application of principles. The effectiveness of the
instruction in poultry-keeping, for example, is observable in the extra-
ordinary success of these ‘‘ backyard poultry-keepers and breeders in com-
petition with the poultry industry at the appropriate national open
competitions and laying tests.’

Though vocational science is outside the terms of reference, the scientific
basis of industry offers a promising field of adult education. Professor
Julian Huxley writes that ‘ industrial work should be more directly linked
up with its scientific basis; scientific work and invention should be
encouraged among workers in factories, and knowledge of the scientific basis
of the processes on which they are employed should be made more accessible
to such workers.’

‘The aim of the Adult Biology Class is not to produce naturalists—not
more than 1 in 20 average adult student has the makings of a naturalist in
him—but to make intelligent citizens capable of a scientific attitude towards
public questions and their own personal matters’ (Dr. Norman Walker, Leeds).

The Joint Committee in Belfast, representing the Extra-mural Depart-
ment, Queen’s University, and the W.E.A., ‘seeks to give its students
knowledge which will enable them to utilise their leisure time in the best

SCIENCE TEACHING IN ADULT EDUCATION 347

possible way, and lead to the application of the scientific method to all
problems of life.’

At Liverpool the teaching is ‘ purely non-vocational, and for purposes of
wider culture.’

At Cambridge, in the Extra-mural courses: ‘ The teaching of lecturers
and tutors is non-vocational in character and, broadly speaking, their aim is
to interpret science to the layman and to relate scientific developments to
daily life.’

Another aspect of the problem was discussed by Dr. Charles Singer (London).
He traces the ‘ current distaste for science ’ to defects in the history teaching
of ourschools. Starting from the agreed proposition that every adult should
know the main results of science he specifies particularly the differences
science has made, (a) in our way of thinking, and (5) in our way of living.
These he characterises as the most important events in the history of the
last 300 years.

He regards teaching of the nature of these differences or changes as one
of the prime duties of a teacher of history, a duty which, in his opinion, the
teacher grossly neglects.

The remedy for this distaste he considers ‘to consist primarily in
reforming the teaching that goes by the name of history, and making it
essentially the history of civilisation. Until history teachers teach that the
most important event of the last 300 years is the rise of science, they will
continue to teach false history.’ As this aspect of the problem is beyond
the scope of this inquiry, he suggests that much might be done ‘ by attractive
adult teaching on the nature and origin of scientific discoveries, and by
making lectures centre round such personalities as Descartes, Harvey,
Boyle, Galileo, Newton, Pasteur, Darwin, Davy, Faraday, Helmholtz,
Fraunhofer, and so forth.’ He advocates such ‘ lectures in which simple
historical experiments could be repeated and their meaning developed in
the field of more modern knowledge. Such historical experiments would
give a human interest to science.’

To render these experiments most effective he suggests that ‘ arrangements
might be made for lecture-demonstrations to last 14 or 2 hours rather than
t hour, and that the experiments be performed by an assistant in the middle
of the hall and away from the lecturer. Thus the audience might gather
from time to time round the experimenting table and then return to their
seats.’

6. Aims and Motives of Students attending Adult Science Classes.

The aims and motives of the students attending adult classes are less
definite, and more difficult to interpret. They are probably very mixed,
and change as their interest and knowledge increase.

“The motives which lead students to enter classes naturally vary. Some
come from purely intellectual curiosity, others because they believe that
science has an important contribution to make towards the understanding
and control of modern civilisation ’ (Bristol).

“The average Literary Institute student has neither time nor energy for
acquiring a thorough knowledge of any science. He is interested rather in
the conclusions which have been reached and in the theories which are
being tested. He seeks to coordinate and synthesise his knowledge so as
to reach an interpretation of experience which is satisfying to himself. It
is impossible for him to follow out the detailed processes whereby the
conclusions of science are reached, but he is intensely interested in scientific
generalisations, which he can link up with his experience of life. This view

348 REPORTS ON THE STATE OF SCIENCE, ETC.

is common to organisers, lecturers and members of classes’ (City Literary
Institute).

‘Students are attracted to science classes by many different interests,
and any generalisation about motives is likely to be more or less false. For
instance, some come to biology classes because they are interested in the
theory of evolution, probably from a philosophical angle ; some want.to
know something about plant or animal life ; others are chiefly interested in
personal hygiene. In every case, however, what the students need is
a grounding in scientific method’ (R. J. Howrie, Loughborough T.C.).

‘ Biology is by far the most attractive of scientific studies to members of
Tutorial Classes, and, this being so, we have sought to find out why. We
are of opinion that the particular attraction which Biology has for the adult
student is due to the fact that it deals with matters within the student’s own
experience and observation, and have a close bearing on his daily life’
(W.E.A. Science Report, 1932).

Animportant aspect of biological study is noted by Mr.S. Myers (Deptford
Men’s Institute) : ‘ Interest in, and the growing practice of, contraception
has given rise to a keen interest in generation and pre-natal development, in
inheritance and in allied matters. Other causes may contribute to this
result. I am not concerned with the ethical aspect of birth control, but
I am definitely of opinion that married men need some expert guidance in
what may be called the hygiene of married life, and that this should take the
form of courses of lectures on biology conducted on lines much less oblique
in relation to sex matters than the courses generally available under. this
name, i.e. biology. ‘The working-class wife and mother probably suffers
more from ignorance—her own and her husband’s—than has yet been
realised. We have left the most sacred things in human life, as far as they
concern our poorer neighbours, to the academy of the gutter whose pro-
fessors do their work tragically well.’

7. Propaganda and Publicity.

The problem of stimulating the demand for science studies in Adult Classes
is a matter for those who realise the importance of the subject to the com-
munity generally and understand the serious danger to social stability that
accompanies ignorance of the facts of science, or of scientific method. It
is for those to suggest means for awakening interest in these studies and put
them in operation. Several witnesses bear testimony that behind the
apparent indifference to science suggested by the comparatively small number
of classes, men and women are keen to learn when given the opportunity,
and when they see that what is offered has practical bearing on the problems
of life.

Since 1921 there has been very little active propaganda on behalf of
science. Most organisers of Adult Education are concerned with providing
what is asked for, and can hold no brief for any one subject. Such bodies
as the Local Education Authorities, and the Boards of Studies of the
Universities, naturally act for the most part, on the principle that, if and
when demand for science courses arise, they will do their best to meet it,
and will provide the necessary facilities.

“It has been the policy of the Council to meet the demand on the part of
students for classes in any suitable subject. For some unknown cause
science is, relatively speaking, not popular at present and, therefore, there
has not been the same demand for science classes as for some other subjects.
It is thought that an increased demand can only arise as the effect of science
teaching in secondary and other schools becomes more marked and as

SCIENCE TEACHING IN ADULT EDUCATION 349

science is popularised by wireless talks, press articles, and so on. It will be
realised that the present call for economy in public expenditure renders it
necessary to go slowly as regards enlarging the scope of the Institutes, but
the Council never refuses to provide classes where students in sufficient
numbers present themselves’ (G. H. Gater, L.C.C.).

‘ Apart from the usual discussion of subjects with Extension Centres and
prospective classes, no special propaganda has been undertaken in favour of
scientific studies ’ (Cambridge University Extra-mural Board).

§ We have no definite scheme for extending scientific work in Adult Classes.
As the demand arises we endeavour to secure teachers in the subjects asked
for’ (W.E.A., Western District).

‘ Advertisements of special courses are issued and notices are sent out and
meetings held, and groups likely to be interested are specially interviewed in
the various centres with a view to the formation of classes and the organisation
of courses of lectures ’ (Manchester University).

Success in promoting Adult Education in science in the region served by
a University depends much less on formal organisation than on the mis-
sionary efforts of individuals. In many parts of the country, especially in
the North, successful classes in literary subjects have been built up, and
a connection with the University thus established, so that means are avail-
able for introducing science into a community where the habit of study has
already become familiar. In one instance a lecturer in the English Depart-
ment of a University had been remarably successful in his efforts to establish
classes under the W.E.A. over a large area, attended mainly by coal miners
and metallurgical workers. He had a great personal influence on these
groups, and at his suggestion colleagues from the scientific departments of
the University were from time to time invited to lecture on their own
subjects and always found large and attentive audiences. From these
occasional lectures there has grown a more systematic scheme of scientific
lecture courses, although practical work by the students has not yet been
attempted.

Lectures on the history of local industries make an appeal to audiences in
such districts. A group of miners will listen to and appreciate an account
(illustrated by lantern slides and specimens) of the development of mining
since ancient times, whilst steel workers can be similarly interested in the
history of metallurgy. If care be taken to show the connection between the
progress of an art and social conditions, the interest of industrial audiences,
which usually leans towards the side of economics, can be aroused, and
a bridge is thus provided leading to the teaching of science proper. It is
possible that the social history of agriculture might be used similarly in some
districts as an approach to biology. Compare what has been quoted above
(p. 347) from Dr. Charles Singer as to the historical approach to science
generally.

A teacher imbued with the missionary spirit, and having an influence on
the extra-mural students in his region, can enlist the help of his university
colleagues in the teaching of science. It is best that the first steps should be
entirely informal. The panel of lecturers should be chosen by a few who
know the region, and not by a committee or a public authority. The
W.E.A. scheme is elastic, and the extra-mural side of the universities is not
usually greatly hampered by redtape. The teachers selected must, however,
have a real evangelical fervour, if they are to succeed. Sometimes it may
be a senior man who has become impressed in the course of his experience
by the urgent need of more scientific knowledge on the part of the public ;
sometimes it may be an enthusiastic junior lecturer who has the gift of
popular exposition, who will best fill the place. Such men are not common

350 REPORTS ON THE STATE OF SCIENCE, ETC.

at present, but the experiment must be made slowly, and when a demand
has once been established, an increased supply of suitable teachers may be
expected.

‘ Pioneer work in the form of lectures, either single or in the form of
a series, by the right kind of tutor, always attracts a number of potential
students. And having got their interest, never let it flag. 'The subject-
matter dealt with in these lectures must be of the right kind and be of imme-
diate interest in relation to everyday things. "The method of presentation
must be simple, but scientific (not popular) and calculated to whet the
appetite for more’ (Dr. A. J. Grove, London).

‘ More propaganda among voluntary organisations engaged in some form
of adult education would encourage the development of scientific teaching.
For instance, the study of the drama has been fostered by the Rural
Community Council. There seems to be no reason why this and similar
organisations might not foster the study of scientific subjects. ‘This observa-
tion also applies to the special interest in social subjects on the part of the
W.E.A.’ (R. J. Howrie, Loughborough T.C.).

‘ There is need for expository lectures of a non-technical type as a means
of propaganda for more intensive work ’ (Bristol).

‘ A demand can perhaps more easily be stimulated in the first instance for
such a subject as Nature Study than for a more specialised branch of science.
In the University staff the specialisation necessary on the part of those
engaged in science teaching makes it somewhat difficult to get tutors who
will deal satisfactorily with this subject, but tutors may probably be obtained
from other institutions where a more generalised treatment of science is
combined with requirement of a suitably high standard of attainment. Like
Nature Study, Astronomy is a subject likely to prove suitable for introduction
in a centre where a demand for science classes for adults has not yet revealed
itself.

Broadcasting, journals, and other media of propaganda have also a part
to play in extending interest in the study of science. So also have contacts,
largely of an informal type, e.g. in outings, with various organisations which
are interested in younger adults. Mechanical aids may be of considerable
value in making a lecture more attractive, a point of particular importance
in a pioneering lecture. But the enthusiasm of a competent lecturer is, in
pioneer work, an asset for which no adequate substitute can be found. Full
publicity must, however, be given to any lectures intended to stimulate
interest in science, and contacts with all existing groups likely to be interested
should be established. The part which local societies may play in sustain-
ing interest is to be noted. Both in propaganda lectures and in classes,
demonstration experiments—which should, however, not be too numerous
—have proved really useful features ’ (D. M. Stewart, Glasgow).

Mr. G. C. Robson, British Museum (Natural History), believes there is
not enough local publicity, and recommends that ‘ Local institutions and
secretaries might do far more in the way of advertising courses and stimulat-
ing local societies to support them.’ He further suggests that ‘ in view of
the keen interest evident in the social implications of Biology, it might be
fostered and developed if the potential teachers and lecturers (University
graduates) were made aware of this demand. It is, perhaps, not sufficiently
made apparent to a man during his University training that biology has
a humanistic side. ‘The acute specialisation must have the effect of with-

drawing the average graduate from contact with popular needs and
interests.’

SCIENCE TEACHING IN ADULT EDUCATION 351

8. The Supply of Science Books, Equipment, and Materials.

A. Books,

An adequate supply of science books is an important consideration in the
equipment of a science class. ‘The Committee have received several useful
suggestions in reply to their inquiry in this direction. General library
arrangements are very fully discussed in Paper No. 11 of the Board of
Education Committee (p. 93-113). There is theoretically no limit to the
facilities which exist for supplying the individual students with whatever
books they require, through the co-operation of the County, or Borough
Public Library scheme, the National Central Library, and the Extra-mural
Libraries of the Universities. In practice, however, it depends very much
upon the County or Borough authority concerned ; in some districts a library
regulation restricting the use of a book by a borrower to fourteen days
prevents its use for class purposes; in other districts the Library Com-
mittee is distinct from the Education Committee, and there is some lack of
co-operation. ‘The fact that a class needs several copies of one book is
another difficulty when the Public Library’s stock is not sufficient.

In addition to the Public Libraries, many voluntary bodies, such as the
Y.M.C.A. centres, possess fairly well-equipped libraries. The Working
Men’s College contains some 10,000 volumes. The University of London
Library allows students to become borrowing members of the library, and
also issues travelling libraries of the books needed during a course, for the
special use of the class during the whole of its progress. Such travelling
libraries are provided in connexion with all Tutorial Classes, and are sent
to those University Extension Centres which apply for them.

The Education Library at County Hall has a science section upon which
science teachers can draw.

The City Literary Institute Library is not supplied with textbooks, but
possesses a fair supply of general scientific literature.

The following replies indicate some dissatisfaction with the type of
book available :

“Many of the books recommended by tutors for students’ reading are
written mainly for the university undergraduate, and are unsuitable for
adult students. There is little between these and the popular book on the
wonders of the universe, which, while it may serve to stimulate interest,
does not serve the needs of students. We need more books of the type of
Dr. Firth’s Chemistry in the Home, which was produced as a result of work
done in this Department’ (Prof. Peers, Nottingham).

“Lack of small ‘‘ popular ’’ books on elementary science—books which
are not school textbooks but which are really readable—is a serious drawback.
At present the Dorset County Library is not well supplied with such books ;
there is a lack of duplicate copies ’ (Resident Tutor, Dorset).
ih is an urgent need for science primers for adults’. (Glasgow,

.E.A.).

In most districts the general arrangement for books seems to be
satisfactory.

“There are a great number of popular science books available, and no
difficulty has been experienced in finding suitable books for reading’
(Dr. Chapman, Sheffield).

‘Science books are at present provided by the University, through
travelling libraries ’ (Liverpool).

‘ Books have generally been obtained from Burgh and County Libraries,
the supply being supplemented where necessary from the Scottish Central

352 REPORTS ON THE STATE OF SCIENCE, ETC.

Library and from the resources of societies. A selection of books is placed
at the disposal of the class throughout the class period, and this arrangement
has proved very satisfactory ’ (West of Scotland Joint Committee).

In the Adult School Union, special handbooks are published by the
Union. These handbooks have a circulation of about 23,000 copies per
annum, and the material is used as the basis for discussion throughout the
whole Adult Schools in the country.

88. Equipment, Apparatus and Materials.

References to equipment and to apparatus have been made under sec-
tion 3c. The general situation appears to be that except for classes held in
or near University or Technical Colleges the supply of apparatus and material
is quite inadequate for lecture demonstrations, and still more so for class
work of individual students. Hence many science classes have to depend
upon lantern slides for the greater part of the work, with occasional help
from films. Even in Oxford we are informed that ‘ it is seldom possible to
have the use of a laboratory, or for members of a class to have access to one
for practical work except during lecture hours.’

In Cambridge ‘ some Tutorial Classes (e.g. in Biology) have been able
to meet in laboratories, but this depends on local circumstances (e.g. offer
from a local school). In most cases a few microscopes have been supplied
by the Extra-mural Board as part of the travelling library.’ ‘ Two classes
have been granted facilities by the University ; one has met for three years
in the Biochemical Laboratory, and another for the same period in the
Psychological Laboratory.’

In Manchester ‘some material and equipment could be borrowed
under guarantees from University departments. The laboratory accom-
modation in towns outside the University is the main difficulty.’

In Glasgow ‘in some instances students have constructed their own
equipment—one, for example, during a period of unemployment made an
electrical machine to provide electricity to facilitate his experimental study
of the subject. A nature study class gave an exhibition of collected speci-
mens, and students habitually bring along specimens for discussion. Both
University and Museum University departments are indebted to adult
students for additions to their collections.’

In London from the point of view of the Local Education Authority,
‘No difficulty appears to have arisen in the way of teachers and students
finding such equipment and materials as are required for classes of the type
under consideration. All the institutes are provided with lanterns and
epidiascopes and the Council’s magnificent collection of lantern slides is
available for use by science as well as other lecturers. Many of the teachers
have private equipment and in some instances are also able to draw upon
resources provided by professional bodies and their daily occupations.’

From the point of view of one of the chief Literary Institutes in which
science courses are taken and where there is practically no equipment for
science teaching the position does not seem quite so simple. In one
reply it is stated: ‘ With regard to classes in science conducted at the
Institute, no public’ funds are expended on material, except for courses in
Photography. Even here students themselves already supply a very con-
siderable quantity of equipment and material. In general little com-
sumable material is required, but whereas equipment such as microscopes,
spectroscopes, and telescopes would be useful, one hesitates to press local
Education Authorities to.expend considerable sums for the provision, of
these, in view of the need for economy.’

SCIENCE TEACHING IN'ADULT EDUCATION 353

Of all Institutions for adult classes, the Working Men’s College seems to
be best supplied with apparatus and material for science work. The
equipment there seems to be quite adequate to the demand.

9. Inter-communal Co-operation in the Science Work of Adult Classes.

One of the most attractive and useful features of science work is the feeling
it affords of a personal participation in the search for truth. In an attempt
to obtain knowledge of things for oneself there is no limit to interest and
enthusiasm. Even if it results only in gaining knowledge already known to
other people, it is nevertheless research. Besides there are always new
aspects of nature to be studied and when they are presented in the form of
problems for investigation in which the student plays an active if not the
principal part, science becomes a fascinating subject and a source of never
failing interest.

This side of science work must not be overlooked in the future planning
of science courses for adults; for this intrinsic interest of scientific
research has a part here to play equally with the interpretation of scientific
results in their application to modern life and social developments. One of
the most fruitful methods of procedure is that of team work, wherein most
or all of the students contribute, by their observations, towards a common
objective, and thereby collect sufficient date in a comparatively short time
to justify at least tentative conclusions almost impossible for the individual
student to reach in the short time available. ‘This is equally true where the
results of field work and observations made by other groups of students in
the same district can be pooled and utilised for wider generalisations.
Useful survey work of a regional type may be undertaken by adult classes
in subjects connected with agriculture, horticulture, flora, fauna, soil and
climate of a district. Joint meetings should be organised for general dis-
cussions of results. Such an objective stimulates independent reading
serves as an incentive to continuous work, and broadens the outlook of the
students.

Very little in the way of such interchange has hitherto been attempted,
and little in the way of regional survey. This is probably because co-opera-
tive effort of this kind has not been considered possible. It is urged that
inter-communal co-operation of the kind suggested would lead to more
serious studies of the conditions affecting the welfare of the people, and
assist in establishing a wider appreciation of the value of science to the
community.

10. Assistance from Local Scientific Societies to Adult Classes in their District.

The active agents in promoting this inter-communal activity would
naturally be a committee of lecturers and tutors of the district. Professor
Julian Huxley suggests that ‘local scientific societies should, possibly
under advice from some central body, work out plans by which natural
history, geological and survey work in the area could be profitably organised,
and point out ways in which adult education classes and those interested
could take part in such work.’

Similarly the Director of Extra-mural Studies in the University of
Manchester suggests that ‘it might be useful if the Extra-mural Depart-
ments of Universities, and the District Secretaries of the W.E.A. co-operated
from time to time in calling local conferences of Field Clubs, Natural
History Societies of various kinds, with a view to closer co-operation and

354 REPORTS ON THE STATE OF SCIENCE, ETC.

the development of facilities. Possibly some of the Societies would be
willing to give practical assistance in this, and from time to time a one-day
*‘ School in Science ’’ might be arranged through the hospitality of one or
more such Societies. ‘There has been a considerable revival of interest in
Local History under the stimulus of the Rural Community Councils .. .
perhaps in co-operation with these bodies a good deal might be done for
geology, botany, and zoology studied locally. The Conferences arranged
in Derbyshire and elsewhere have further stimulated interest and increased
the knowledge of local history. ‘The same thing might prove true if con-
ferences of groups engaged in the study of natural history under local
conditions were arranged in county or district areas.’

From the City Literary Institute, Mr. G. T. Williams sends similar
suggestions. (1) Scientific societies might place their material occasionally
at the disposal of classes, by means of travelling exhibits bearing on the work
of particular groups which are conducting their studies in the Institutes.
(2) Societies interested in promoting the study of some particular science,
or aspect of science not usually comprised in the curriculum of Institutes,
should formulate and circulate specimen syllabuses with reading lists,
suggestions for equipment, and some indication as to method of approach.
Institutes might be encouraged to offer in their programme classes which,
without such suggestions, would ordinarily not have occurred to them as
within the bounds of possibility. (3) Scientific societies that possess special
equipment would allow groups from Institutes to meet for special demon-
strations in their laboratories.

It is generally reported that Local Field Clubs and Scientific Societies
are sympathetic and helpful. In Belfast ‘ classes are linked in an unorga-
nised way with the local Naturalist Societies, i.e. many members of the classes
pass to membership of these societies, and lectures attended thereat are often
discussed in class,’

Many Committees for Adult Classes publish handbooks in which the
programmes of the various scientific societies are included . . . as they
realise that ‘ the help of local scientific societies in stimulating the demand
for scientific study would be extremely valuable.’

The only district, according to the information supplied to the Com-
mittee, in which interchange of observations and the results of field work
has been carried out, is in the Western (or Glasgow) District of Scotland.
Here the Joint Secretary of the Extra-mural Education Committee reports
that ‘ Contact has been maintained as far as possible between adult classes
and local societies dealing with Astronomy and Natural History, to mutual
advantage. ‘The societies afford a field in which the adult students are able
to carry further and to apply the knowledge gained by them in classes,
while the classes afford to some of the members of the societies an oppor-
tunity of making their knowledge more systematic. . . . Nothing has
been done yet in the way of interregional meetings of adult classes for com-
parison of local observations, but a beginning has been made with regional
survey by adult classes, more particularly at Kilmarnock and at Dumbarton
as part of the West of Scotland survey of plant and animal life, stimulated
by the visits of the British Association. . . . It is hoped that from the
nature study class at Dumbarton a local Natural History Society may
develop. The astronomy section of the Paisley Philosophical Institution
resumed meetings and activity after a long interval as a result of the contact
of interested persons provided by an adult class.’

SCIENCE TEACHING IN ADULT EDUCATION 355

JII.—SuGGESTIONS AND RECOMMENDATIONS.

The Committee has not found it possible, during the current year, to deal
with all the problems covered by its terms of reference. ‘They have there-
fore decided to report in the first place on the ‘ position of science in Adult
Education,’ reserving for subsequent discussion the problems dealing with
the improvement of the position of science, with the various modes of
approach, with types of syllabuses, with the function of lecture courses, and
of tutorial classes, and with other matters affecting the steps that ought to be
taken for making science, not only a popular study, but a valuable and
indispensable part of the education of an adult.

Suggestions to that end have been submitted to the committee by various
correspondents, and several of these have already been quoted.

From the statements made to the Committee, it would appear then that,
in general—

(1) The demand for science teaching among adults varies at present
directly with the supply of competent teachers.

(2) The man is more important than the subject, and the subject than
elaborate or expensive equipment.

(3) Apart altogether from systematic vocational training (which is outside
the scope of this inquiry) the approach must be from popular everyday
applications of scientific method on practical occasions and common
experience, to the discovery of principles, and from such discoveries,
in detail, to the formulation of a systematic body of knowledge. It
is the scientific outlook, not a multiplicity of scientific experiences,
that is to be achieved: as it has been expressed to the Committee
* you are not making science students ; you are preaching a gospel’ ;
and providing what has also been described as ‘a useful adjunct to
philosophy.’

(4) This difference of aim and procedure, between science teaching for
adults, and systematic science-teaching in Universities, or even in
schools, goes far to explain the dearth of teachers qualified to conduct
this sort of course. For here the teacher’s own systematic knowledge
can only be applied effectively by reversing academic procedure, and
guiding (or provoking) the process of rediscovery, and of generalisa-
tion from facts actually observed by the pupil or the class in some
episode of daily life.

(5) While the historical approach to scientific problems provides, through
its foundation in such experiences the most direct approach for adult
classes, the prevalent neglect of the history of discovery among
professional teachers of science is an important reason why teachers
competent to teach science to adults are so rare.

(6) Much adult science, which hardly goes even so far as such rediscovery
and generalisation, has nevertheless its value as a conscious contribu-
tion to learning, through regional observation, and is capable of
enhancement, and refinement of technique, especially when it is
pursued as team work, in conjunction with other workers.

(7) Here is the proper field of what was formerly called ‘ Natural History,’
as an outdoor occupation primarily, though it presumes the leisured

oe revision and comparison of the notes and collections of field workers,
under the guidance of an experienced naturalist, who need not have
academic or tutorial qualifications at all.

356

REPORTS ON THE STATE OF SCIENCE, ETC.

(8) This is where the adult class may reasonably appeal for help to the

local Field Club or Natural History Society, and also to the local
Museum. Both institutions stand to gain by enlargement of their
range of field observers and voluntary collectors of regional material.

(9) The value of the work which is being done by certain voluntary

and non-academic organisations should not be overlooked. More
particularly the Women’s Institutes in the country and the newly
formed Townswomen’s Guilds inthe towns are bringing together large
numbers of women unlikely to be touched by other bodies dealing with
adult education. Up till now the instruction given in this connection
has been mainly of practical character, but if lecturers with suitable
outlook and interests were available much might be done through
these organisations to stimulate an interest in achievement of science
in relation to practical and social questions and to encourage a more
scientific attitude of mind towards such matters.

IV. SELECT BIBLIOGRAPHY OF SCIENCE TEACHING IN ADULT EDUCATION.

‘ Popularisation of Science through Public Lectures,’ Report of British

Association Committee (1916)

‘ Natural Science in Adult Education,’ Board of Education Committee,

Paper No. 8 (1927).

‘ Science and Adult Education,’ Conference Papers, Oxford (1927), British

Institute of Adult Education.

‘Science, Industry and Human Life,’ Sir John Sankey, Conference

Address, Oxford (1927), British Institute of Adult Education.

Articles from the Journal of Adult Education :—

* Geology as a subject for Adult Classes,’ by D. A. Allan, 1929.

‘ Some notes on Science and Adult Classes,’ by M. I. Cole, 1930.
‘The Need for the Popular Lecturer,’ by A. Clow Ford, 1930.
‘Physics and Adult Classes,’ by G. Cochrane (1931).

‘ Astronomy for Adult Classes,’ by T. L. Macdonald (1931).

The Social Function of Science, by Professor C. H. Desch, F.R.S. (1931),

Sheffield University.

‘Science in Adult Education,’ by T. L. Macdonald. The Tutor’s

Bulletin of Adult Education, No. 2, 1931.

‘Biology and the W.E.A.’ by Dr. Norman Walker. The Highway,

October 1932.

‘ Study of Science in Adult Classes,’ Report of Executive Committee of

Workers Educational Association (1932).

“Science and the Radio,’ by Austin E. Clark. Scientific Monthly (1932).
“Memorandum on the W.E.A. Report on Science Study,’ by Scottish

Tutors, in No. 7, Bulletin of the Association of Tutors in Adult Education,

I

933.
“A Tutorial Class in Physics,’ by A. Cochrane, reprinted from the Journal

of Adult Education, Vol. VI, No. 2, published by Sidgwick and Jackson,
London, 1933.

V. APPENDIX.

The Committee wish to acknowledge their great indebtedness to all those

who have been so good as to reply to the questionnaire and supplied: memo-
randa which have formed the basis of this report. They desire to offer

SCIENCE TEACHING IN ADULT EDUCATION 357

their very hearty thanks for the information received and to express their
deep appreciation of the help so ungrudgingly given in this inquiry by—

(1) The Board of Education.

(2) London University: Mr. John Lea, Extra-mural Department ;
Prof. Julian Huxley, King’s College; Dr. A. J. Grove; Mr. G. C.
Robson, British Museum (Natural History).

(3) London County Council, Education Department, Mr. G. H. Gater
and Mr. E. M. Rich; City Literary Institute, Mr. G. T. Williams ;
Deptford Men’s Institute, Mr. S. Myers ; Bec Literary Institute,
Mr. W. J. Gale.

(4). British Institute for Adult Education, Mr. J. W. Brown.

(5) Workers Educational Association, Mr. A. S. Firth.

(6) Y.M.C.A., Mr. A. Clifford Hall.

(7) Arsenal Co-operative Society.

(8) Working Men’s College, Mr. C. Chapman.

(9) Morley College, Westminster, Mr. S. T. Cottrell; Mary Ward
Settlement, Mr. Horace Fleming.

(10) Oxford University, Rev. F. E. Hutchinson, Extra-mural Department.

(11) Cambridge University : Mr. G. F. Hickson, Extra-mural Depart-
ment; Mr. G. P. Bailey.

(12) Reading University, Dr. W. B. Brierley, Extra-mural Department.

(13) Bristol University : Mr. John Nicholson, Extra-mural Department ;
Mr. A. E. Douglas Smith, Resident Tutor, Wiltshire; Mr. W. R.
Straker, Secretary, W.E.A., Western District; Mr. S. H. Can,
Resident Tutor, Somerset ; Miss M. R. Dacombe, Dorset:

(14) Midlands: Mr. L. A. Fenn, W.E.A., Birmingham ; Loughborough
College, Mr. R. J. Howrie, Extra-mural Department ; Nottingham
University College, Prof. R. Peers, Extra-mural Department.

(15) Sheffield University : Dr. A.W. Chapman, Extra-mural Department ;
Prof. C. H. Desch.

(16) Leeds University, Dr. Norman Walker, Extra-mural Department.

(17) Manchester University, Mr. H. P. Turner, Extra-mural Department.

(18) Liverpool University, Mr. E. Hickinbotham, Extra-mural Depart-
ment.

(19) Durham University: Rev. E. G. Pace, Extra-mural Department ;
Mr. T. B. Tilley, Director of Education.

(20) Glasgow University : Mr. D. M. Stewart, Extra-mural Department ;
Mr. C. Cochrane; Mr. T. L. Macdonald, W.E.A.

(21) Belfast, Mr. H. J. Eason, Queen’s University, Extra-mural Depart-
ment.

(22) Women’s Institutes, and The Townswomen’s Guilds, Miss Masters.

(23) National Adult School Union, Mr. G. Peverett.

_ (24) American Association for Adult Education, Mr. Morse A. Cart-
wright.

(25) Kent, Mr. Salter Davies, Director of Education.

(26) Dr. Charles Singer.

(27) Sir H. Frank Heath, G.B.E., K.C.B., Universities Bureau of the

J British Empire.

_ (28) Lancashire, Mr. P. E. Meadon, Director of Education.

358 REPORTS ON THE STATE OF SCIENCE, ETC.

INLAND WATER SURVEY.

Report of Committee appointed to inquire into the position of Inland Water
Survey in the British Isles, and the possible organisation and control of
such a survey by central authority (Original Members : Vice-Adml.
Sir H. P. Douctas, K.C.B., C.M.G., Chairman; Lt.-Col. E. GoLp,
D.S.O., F.R.S., Vice-Chairman; Capt. W. N. McC ean, Secre-
tary; Mr. E. G. Bituam, Dr. Brysson CuNNINGHAM, Prof. C. B.
Fawcett, Dr. A. Fercuson, Dr. Ezer GrirFiTHs, F.R.S., Mr.
W. T. Hatcrow, Mr. C. C. SmirH, Dr. L. DupLey STAmp,
Brig. H. St. J. L. WintersotHaM, C.M.G., D.S.0. Co-opted
Members: Mr. T. Suirtey Hawkins, O.B.E., Mr. W. J. M.
Menzies, Mr. Henry Nimmo, Dr. A. Parker, Mr. D. RONALD,
Capt. J. C. A. Roseveare, Dr. BERNARD SMITH, F.R.S., Mr. F. O.
STANFORD, O.B.E., Capt. J. G. WITHYCOMBE).

CONTENTS OF REPORT.
I. Introduction.
1. Appointment of Committee and terms of reference.
2. Appointments of Chairman and Sub-committees.
3. Earlier demands for a survey.

Il. Position of Inland Water Survey.
4. Scope of survey.
5. Existing organisations.
6. Water users.
7. Absence of co-ordination.

III. Possible Organisation and Control of an Inland Water Survey by Central
Authority.
8. Examples of organisations in other countries.
g. Systems of measurement.
10. Ideal to be aimed at for this country.
11. Review of available data.

IV. Conclusions and Recommendations.
12. Conclusions.
13. Recommendations (omitted in accordance with practice).

Appendix : Memoranda.

I. INTRODUCTION.

1. Appointment of Committee and terms of reference.— Following the
meeting of the British Association held at York in September 1932, the
General Committee, on the recommendation of Sections A (Mathematical
and Physical Sciences), E (Geography), and G (Engineering), appointed a
Research Committee for the following purpose :—

‘To inquire into the position of Inland Water Survey in the British
Isles, and the possible organisation and control of such a survey by central
authority.’ :

A list of the members of the Committee so appointed is given at the
head of this report.

2. Appointments of Chairman and Sub-committees—The first meeting
of the Committee was held on November 9, 1932, when Vice-Adml.

INLAND WATER SURVEY 359

Sir H. P. Douglas was elected Chairman, Lt.-Col. E. Gold, Vice-
Chairman, and Capt. W. N. McClean, Secretary. A number of additional
members, whose experience in various branches of work connected with
the subject would be of assistance to the Committee, were co-opted.

The Committee appointed two Sub-committees, viz. the Data Sub-
committee to collect information relating to the first part of the reference,
and the Schemes Sub-committee to investigate the second part. Their
work is referred to below.

3. Earlier demands for a survey.—Demands and suggestions for a survey
of the water resources of the country, and for a central water authority,
have been made on many occasions inthe past.?_ It is necessary, at the outset,
to draw a clear distinction between an organisation for carrying out a water
survey and a central authority or National Water Board for the administra-
tion and control of the national water resources. It is with the former
only that this Committee is directly concerned. It is of interest to recall
that the British Association identified itself with the earliest of these demands.
In 1878, at a meeting of the Association in Dublin, a paper was read by
Mr. J. Lucas, F.G.S., advocating a hydro-geological survey of England ;
and a discussion took place in the Mechanical Science Section at which
Mr. Easton, the President of the Section, suggested the formation of
watershed boards.?

In the same year, at a Congress of the Royal Society of Arts, a paper was
read by Mr. C. Slagg in which the suggestion was made that a State record
of the surplus water flowing from high and uncultivated lands should be
regularly kept. A paper was also read by Sir J. Clarke Hawkshaw,
M.Inst.C.E.,* on the subject of ‘ River Conservancy.’

In 1902 the Salmon Fisheries Commission ® expressed the opinion,
identical with the suggestion made by Mr. Easton at the British Association
Meeting in 1878, that the time had arrived when the Government should
cause a survey and estimate of the water supplies available in all watersheds
throughout the kingdom to be made for the use of the proposed watershed
boards.

Before leaving the historical aspect of the subject, reference should also
be made to the work of Mr. C. E. De Rance ® in which he referred to a
Research Committee appointed by the British Association in 1874 on the
subject of the underground circulation of water, and to the above-mentioned
Congress of the Royal Society of Arts. In this work, which may well be
regarded as the forerunner of a water survey, the author describes the
character and quantity of the existing water supplies, the area of the principal
geological formations, with the amount of rainfall in each of the river basins
delineated in the catchment basin map of the Ordnance Survey.

_ Inmore recent years the demand has been repeated, and instances, which,
however, are by no means exhaustive, are quoted in Memorandum D (1);
a few of the principal examples are briefly enumerated as follows :—

A Joint Select Committee of both Houses of Parliament, in 1910, ex-

pressed the opinion that there was need for a comprehensive survey of the
_ water supply of the country.
__ In the same year Parliament ordered a Return as to water undertakings

* Forbes and Ashford, Our Waterways, chap.i. (Murray, 1906.)
_# Ann. Report, B.A., 1878, pp. 689, 692. 5 Report of Proc., 1878, p. 112.

* Journal, vol. 27, p. 623. 5 Report, pp. 12, 49-51, 61.

® C. E. De Rance, Assoc.Inst.C.E., F.G.S., The Water Supply of England and
Wales, its geology, underground circulation, surface distribution and statistics. (E.
Stanford, 1882.)

360 REPORTS ON THE STATE OF SCIENCE, ETC.

in England and Wales. This was compiled, and issued by the Local
Government Board in 1914, as a first instalment of the comprehensive in-
vestigation which had been recommended by various Royal Commissions
and Committees.

Subsequently, the Ministry of Health, the successors of the Local
Government Board, appointed an Advisory Committee on Water who
from time to time have issued various reports,

In 1921 a Committee of the Board of Trade on Water Power Resources
issued their Final Report, which contains the results of extensive investiga-
tion as to the water power resources available for industrial purposes. The
Committee recommended the establishment of a Water Commission
(para. 32) whose primary function would be to compile a record of the
water resources and water requirements of the country (para. 37).

In 1927 the Institution of Water Engineers in general meeting passed
a resolution that there was urgent need of an organisation which would
ensure a continuous record of the flow and storage of surface and under-
ground water.

The passing of the Reservoirs (Safety Provisions) Act, 1930, and the
establishment of Catchment Boards under the Land Drainage Act, 1930
(see Memorandum D (2) appended), have drawn attention anew to the
subject as a matter of immediate urgency, particularly as regards the
gauging of streams and rivers to provide reliable data on which to base
estimates of flood flows; as instances of this may be quoted the Annual
Report of the Ministry of Health, 1930-31 (pp. 14-15), and the draft Report
of the Committee of the Institution of Civil Engineers on floods in relation
to reservoir practice.

Finally, after the lapse of fifty-four years since the meeting at Dublin, the
same demand has been repeated at the meeting of the British Association
at York in 1932. The discussion, inaugurated by Capt. W. N. McClean,
and supported by thirteen representative engineers and scientists, showed
a unanimous opinion that the setting up of a national organisation for water
survey was indispensable (The Times, September 7, 1932).

II. PosiTIoN oF INLAND WATER SURVEY.

4. Scope of survey.—Water conservancy has been defined by the President
of the Mechanical Science Section of the British Association, at the Dublin
Meeting in 1878,’ as ‘ the treatment and regulation of all the water received °
in these islands from its first arrival in the shape of rain and dew to its final
disappearance in the ocean.’ This involves several branches of science :—

Meteorology, as regards the precipitation from the clouds, the primary
source of all water supply, of rain, snow and hail; the condensation from
the atmosphere of water in the form of dew or hoar frost ; and as regards
also evaporation by which a portion of the water is returned to the
atmosphere. These, in their turn, are related to other meteorological
factors, such as temperature and wind, and to geographical conditions, such
as proximity to the sea or mountain masses ;

Geology, as regards the absorption by the soil or rock of a portion of the
water, its storage and flow in the underground strata and its return to the
surface in the form of springs and seepage ;

Topography, as regards the surface flow and storage of so much of the
precipitated water as is neither evaporated nor absorbed. This includes

7 Report, 1878, p. 679.

INLAND WATER SURVEY 361

both the geographical conditions which affect the climate and the land
surface conditions which determine the size and shape of catchment basins
and the courses of streams and rivers.

It remains for the engineer engaged upon the control of water ‘ for the
use and convenience of man’ to give these sciences their practical applica-
tion. It is for this purpose that he requires a quantitative survey, giving
actual measurements of the volume of water available or to be discharged,
as data for his schemes and designs.

The scope of a water survey necessary to meet these requirements of civil
engineers and others interested in water conservancy should include observa-
tions and measurements and the preparation of continuous records in
standard form, in connection with rainfall, surface storage and flow, and
underground storage and flow—in conjunction, in each case, with the
physical and geological characteristics of the area. The records from all
sources should be collated, brought into harmony and made available.

5. Existing organisations—The foundations of such a survey already
exist, in part, in the work of well-established Government departments
devoted to the special branches of science mentioned in the previous
paragraph.

The published maps of the Ordnance Survey (Ministry of Agriculture
and Fisheries) are so well known and appreciated that any description here
is unnecessary.

The Geological Survey (Department of Scientific and Industrial Research)
has made substantial contributions to our knowledge of underground
water resources in its published maps and memoirs. The information thus
collected is admittedly incomplete (see Memorandum E appended).

The British Rainfall Organization (Air Ministry), described in Memo-
randum C appended, having grown from small beginnings as a private
enterprise until it was ultimately taken over by a Government department,
provides the indispensable information as to rainfall on which engineers
hitherto have had largely to depend for waterflow data.

There is, however, no such existing department or central organisation
to deal with direct hydrological measurements of the amount of water
derived from rainfall.

6. Water users—The following table is a summary of the principal
users of water with the purposes for which direct measurements of water
are required in connection with their operations and the nature of the
measurements and records thus involved.

Many of the bodies concerned, it is known, have measurements taken
and recorded according to the needs of their particular interests and the
special avocation of the engineer. In addition, certain scientific societies,
including the Royal Geographical Society, and private undertakings, such
as River Flow Records, have done much work on these lines. In some few
cases, reports have been published (as the appended Bibliography indicates),
but only a superficial knowledge of the subject can be gleaned from a study
of these reports.

It may be anticipated that many will in due course extend this work.
The consumption of water per head of population for domestic purposes
has a steady tendency to increase, due to improved standards of sanitation
such as the laying on of piped water supplies into houses in rural areas, the
substitution of water-closets for privies, and the provision of baths and hot-
water supplies. Thus the growth of population and the requirements of
industry continually increase the demand on water supply resources through-
out the country.

°

362 REPORTS ON THE STATE OF SCIENCE, ETC.

Measurements
and Records.

Memo.

appended. Users and Purposes.

D (1) Surface Water Supplies for Domestic and | Gaugings and levels

Industrial Purposes. of springs,
Available reliable yield; droughts and streams, rivers,
floods ; compensation water for ri- lakes and reser-
parian interests ; and waste water. voirs ; discharges

and overflows.

D (2) Catchment Boards.
Land drainage ; floods and flow control. | Ditto.

D (3) Hydro-electric Stations.
As (1) above, in relation to available water | Ditto.
power for generating electricity.

D (4) Electricity Stations.

Feed and condensing water for steam | Ditto.
plant ; cooling water for oil- and gas-
driven plant.

D (5) Canals and Canalised Rivers.
Navigational uses and losses by evapora- | Ditto.
tion, leakage, etc.

D (6) Fishery and Pollution.
Fishery interests; pollution problems | Ditto.
and dilution of sewage and trade

effluents.
E Underground Water. Gaugings of springs
Available supplies from springs, wells as (1) above ; con-
and bores. tinuous. or peri-
odic water, levels

in wells and bores.

While the amount of water required is thus increasing, and large volumes
run to waste, unused, to the ocean, the quantity available from suitable
sources capable of maintaining the supply through times of drought is not
inexhaustible. "The most conveniently situated sources, whether of surface
or underground water, have been to a large extent already appropriated,
and it has long been recognised that a comprehensive survey of the national
water resources is necessary to enable water conservancy to be placed on
a basis of fact.

Again, with regard to rivers, it is said by an American author ®: ‘ The
damage from floods is increasing ; occasioned more by the increased occupa-
tion of areas that are sometimes flooded than by any increase in the volume
of flood flows.

8 A. Hazen, Flood Flows. (Wylie & Sons, 1930.)

INLAND} WATER SURVEY 363

‘ The land along any river may be divided into three parts :—

‘ (1) The river channel, which all agree ought not to be encroached upon.

“(2) The middle land, usually dry but sometimes flooded.

“(3) The high land above all floods.

“It is the increased occupation of the middle land that causes most of
the trouble.’

This statement is largely applicable to this country, although conditions
are different in many respects. Reliable data as to the volume of flood
flows in past years are lacking in the case of all but one or two rivers. | It is
well known that. river channels have been affected by artificial works, and
that in many places houses have been built on land liable to occasional
flooding. If any material alleviation is to be afforded to such areas by the
River Catchment Boards a thorough study of the river flows is a first essential.

47. Absence of co-ordination—The foregoing gives a general indication
of the diversity of interests concerned with water conservancy in some
form. Numerically there are believed to be, in round figures, over 800
local authorities and joint boards for water supply ; some 300 water com-
panies and over 1,000 private proprietors; 46 catchment boards at
present established ; and over 500 electricity stations, in addition to canal
authorities, pollution boards, fishery boards and hydro-electric under-
takings.’ Private interests, such as mills and riparian owners generally,
are innumerable.

As has been mentioned, some of these bodies take gaugings and measure-
ments and. keep records for their own purposes, but, so far as it has been
possible to ascertain, these form a small minority, and in general there is
an entire absence of co-ordination or of any organisation for systematic
recording of data.

III. Posst1BLE ORGANISATION AND CONTROL OF AN INLAND WATER
SuRVEY By CENTRAL AUTHORITY.

8. Examples of organisations in other countries —National water survey
organisations have been in existence in many countries for a number of
years. The practice abroad, so far as is exemplified in that of four
representative countries reviewed in Memorandum B of this Report, is,
however, by no means uniform. In three out of four cases the observation
of rainfall is the function of a meteorological survey which is not only
separate and distinct from that of stream and water storage measurements,
but is itself the subject of diverse arrangement ; in Italy alone, with a very
recent organisation on national lines, is the whole series of duties combined
in a single service—the Servizio Idrografico Italiano. In Canada meteoro-
logical observations are associated with and controlled by the Department
of Marine ; in the United States the Weather Bureau is attached to the
Department of Agriculture, while in Switzerland there is a Station Centrale
de Meétéorologie, or Meteorologische Zentralanstalt. Stream measure-
ments and gauging are undertaken in Canada by the Dominion Water
Power and Hydrometric Bureau, which is a branch of the Department of
the Interior. In the United States the duties are undertaken by the
Geological Survey, similarly a branch of the Department of the Interior,
as one of a group of activities carried on by five co-ordinate branches. In
addition to this, measurements of river levels are made in certain cases by
the Weather Bureau, which also issues flood warnings. In Switzerland
there is a special Service des Eaux (Amt fiir Wasserwirtschaft) which devotes
itself entirely to hydrometry and the economics of water development.

364 REPORTS ON THE STATE OF SCIENCE, ETC.

Particulars of the services in) other countries might be cited,® but the fore-
going instances suffice to show the diversity of the systems in vogue on the
Continent of Europe and in North America:

9. Systems of measurement.—As described in para. 8, above, the
authorities in other countries have adopted the direct method of measuring
the flow itself and obtaining positive data for the study of such subjects as
flood flows, their frequencies and magnitudes.

In this country, however, the collection of rainfall statistics has been
highly organised, but the direct method of measuring the flow has not been
widely developed, with the result that the engineer who requires to know
the yield of the rainfall, whether the quantity of water available or the
maximum flood flow, is usually left in the position that he must make an
approximate estimation of this by empirical formulz based upon the rainfall.

It thus arises that, while engineers in other countries have at their command
a store of data extending over many years for a scientific analysis of the
subject, committees of British engineers, engaged upon the consideration of
such important subjects as the assessment of compensation water and
floods in relation to reservoir practice, have had to confess themselves
hampered by an insufficiency of such data; and the engineers of catchment
boards responsible for the control of rivers, to whom measurements of the
river flow over a series of years are of primary importance, have, in many
cases, to begin taking river gaugings practically de novo.

10. Ideal to be aimed at for this country.—The organisation of a survey
for the purpose of providing hydrometric data in connection with water
conservancy must be considered in its broader aspects in relation to the
general conditions and requirements of the particular country concerned.
The various systems adopted in other countries have been referred to as
affording some useful guidance from their example and experience rather
than to enable a model which can be copied to be selected. ‘The conditions
differ very materially; for instance, irrigation, which is vital in some
countries, is of minor importance in Great Britain ; hydro-electric develop-
ment is a necessity in many countries and is of increasing importance here ;
floods on British rivers do not compare in magnitude with those experienced
in some parts of America ; and in many cases there remain in those countries
very extensive water resources as yet undeveloped.

In Great Britain, on the other hand, the predominant interest is the ever-
increasing need of public water supply for domestic and trade purposes,
while, to a very large extent, the more economically available and accessible
sources have already been appropriated and developed. Second only to
this in importance are the problems of drainage, floods, motive power,
navigation and fishing.

Though the organisations of other countries, therefore, do not afford a
model, their experience, particularly that of the United States, points to
two important principles: (a) that the investigational activities of a survey
should be segregated from those related to construction and administra-
tion ; and (6) that continuous and reliable records can be collected only by
the State; ‘those collected by other agencies, however meritorious and
serviceable in themselves, will be liable to lack of continuity, will not be
generally available to the public, and will be open to suspicion as to
reliability.’ °

If these principles be accepted, as in the opinion of the Committee they
should, it necessarily follows that the organisation of a water survey should
be a national undertaking. The ideal to be aimed at for Great Britain,
therefore, is a Government department (or section of a department) working

® Trans. of First World Power Conference, vol. i. 10 See Memorandum B.

INLAND WATER SURVEY 365

as a central hydrometric authority in the closest co-operation with the
Rainfall Organisation and the Geological and Ordnance Surveys, and
independent of any interest concerned with the use or control of water.

This ideal implies that the authority, conducting a scientific research for
the benefit of the community, should be financed by public funds and
provided with necessary powers. The Committee consider that this should
not prove to be an impossibility in view of the very different attitude now
adopted by the Government towards scientific research compared with that
of fifty years ago, provided the need is made sufficiently clear and the
demand adequately supported by those directly concerned.

11. Review of available data—With a view to exploring this position the
Sub-committee appointed to collect data has obtained a number of memor-
anda from members of the Committee and others representative of the
various interests. These are annexed as an Appendix to this Report.

A.—The bibliography indicates the very diverse sources which have to
be consulted in order to obtain the limited amount of information on the
subject at present published.

B.—Contains brief particulars of the organisations for water survey in
the United States of America, the Dominion of Canada, Switzerland and
Italy.

C.—Describes the existing organisation and the work of the British
Rainfall Organisation. Sub-memorandum :—
C (1).—Describes the rainfall information needed in relation to inland
water survey and the arrangements necessary to obtain the data.

D.—Deals generally with the problem of water survey as regards surface
water ; the routine of the necessary measurements and observational work,
and its application to the various water interests. Sub-memoranda :—

D (1).—Summarises the present position in regard to public water
supplies in England and Wales, and is supplemented by D (1) (a) in
regard to the records of water supply authorities.

D (2) and D (2) (a).—Give a detailed account of the catchment
boards recently established, and are supplemented by D (2) (8), (c) and
(d), which describe the gaugings taken in three typical instances.

D (2) (e).—Describes the work as regards river gauging of a typical
rivers board dealing with pollution.

D (2) (f).—Describes the interest taken in the subject by the Motor
Boat Association, representing the views of the owners of motor boats
who use the rivers for pleasure purposes.

D (3).—Indicates the water records kept by hydro-electric companies
ae points out the importance to them of long-period records of river

ow.

D (4).—Explains the water requirements of the generating stations of
authorised electricity undertakings, and is supplemented by D (4) (a)
and (bd), giving particulars of the gaugings in two typical instances, and
by a schedule of the flow of some fifty rivers.

D (5).—Describes the water requirements generally with regard to
canals and navigable rivers.

D (6).—Deals with the question of river gauging in relation to water
pollution from the point of view of river boards and fishery boards.

E.— Contains suggestions as to observations and measurements necessary
in regard to underground water, and describes the work of the Geological

366 REPORTS ON THE STATE OF. SCIENCE, ETC.

Survey in connection with water supplies, It is supplemented by E (a),
(8), (c) and (d), which give particulars in respect of four typical under-
ground sources.

F'.—Describes, generally the operations of river gauging and is supple-
mented by two typical instances in F (a) and (0).

These memoranda cover a wide field and are representative of the more
important interests directly concerned with water conservancy, and generally
they may be said to indicate the need and utility of a survey.

IV. CoNcLUSIONS AND RECOMMENDATIONS,

12. Conclusions.—The conclusions at which the Committee have arrived
as a result of their investigations are :

(i) That, with regard to the first part of the Committee’s reference, the
position of inland water survey in the British Isles is far from
satisfactory and that a systematic survey of the water resources of
Great Britain is urgently required ; and

(ii) That, with regard to the second part of the Committee’s reference, the
survey, to be of maximum utility, should be conducted by a central
organisation, preferably under a Government department, inde-
pendent of any interest in the administration, control or use of
water.

The Committee have further given consideration to the steps by which
the work of the survey could be most expeditiously begun. ‘They have
formed the opinion that it would not be feasible in the first instance, under
present conditions, to move for the immediate establishment of an organisa-
tion to be financed by public funds, but rather that a beginning should be
made in a comparatively small way, financed by subscriptions from indi-
viduals and bodies interested, with the prospect of being ultimately
incorporated in a Government department.

With this in view the Committee have approached the Council of the
Institution of Civil Engineers and have been gratified to learn that the
Council will be prepared, if they are so requested by the British Association,
to appoint a Committee to investigate the feasibility of carrying out the
objects outlined in this Report on a self-supporting basis.

13. Recommendations. —

In submitting this Report the Committee desire to place on record their
high appreciation of the services rendered by Capt. W. N. McClean, the
Hon Secretary.

INLAND WATER SURVEY 367

APPENDIX: MEMORANDA.
INDEX.
Main Memorandum A.—Bibliography :—arranged by J. Glasspoole.
Main Memorandum B.—Organisations in Certain Foreign Countries—
Brysson Cunningham.
Main Memorandum C.—British Rainfall Organization—E. G. Bilham.
Sub-Memorandum C (1).—Rainfall Data in Relation to Inland Water
Survey—E. G. Bilham.
Main Memorandum D.—Surface Water—W. N. McClean.
Sub-Memorandum D (1).—Water Supply Authorities—F. O. Stanford.
Appendix (a).—Records of Water Supply Authorities (Gravitation)—
C. C. Smith.
Sub-Memorandum D (2).—Catchment Boards—J. C. A. Roseveare.
Appendix (a).—Paper on Land Drainage in England and Wales—
J. C. A. Roseveare.
5} (b).—Thames Conservancy—G. J. Griffiths.
(c).—River Trent Catchment Board—W. H. Haile.
(d).—Great Ouse Catchment Board—O. Borer.
(e).—West Riding of Yorkshire Rivers Board—J. H. Garner.
a (f).—Motor Boat Association—C. Horton (Secretary).
Sub-Memorandum D (3).—Hydro-Electric Companies—W. T. Halcrow.
Sub-Memorandum D (4).—Electricity Stations —H. Nimmo.
Appendix (a).—River Severn at Ironbridge—E. F. Hetherington.
x (b).—River Aire at Esholt—T. Roles.
bs (c)—Low Flows of Twenty Selected Rivers—H. Nimmo.
Sub-Memorandum D (5).—Canals—T. Shirley Hawkins.
Sub-Memorandum D (6).—Water Pollution—A. Parker.
Main Memorandum E.—Underground Water—Bernard Smith.
Appendix (a).—Water Level in the Chalk at Compton—D. H. Thomson.
(b).—Methods for obtaining Water Levels in Wells and Bore-
holes—F. J. Dixon.

”

5 (c).—Pumping Tests at New Borings for Water. Gauging
over Long Periods from Wells in the Chalk—R. C. S.
Walters.

(d).—Notes on Rainfall, Rest Levels and Pumping Levels—
A. E. Cornewall-Walker.
Main Memorandum F.—River Gauging—W. N. McClean.

Appendix (a) —Gauging of the River Severn at Bewdley—S. M. Dixon.
(b).—Gauging of the River Thames—G. J. Griffiths.

”

Main Memoranpum A.
BIBLIOGRAPHY OF THE More IMPORTANT PAPERS DEALING WITH
INLAND WATER IN THE BRITISH ISLES.
; 1. GENERAL.
(a) Return as to Water Undertakings in England and Wales, published by the
Local Government Board, 1914.

This publication of 642 pages gives details as to every water undertaking
in England and Wales, with particulars as to the various sources of supply

368 REPORTS ON THE STATE OF SCIENCE, ETC.

in each case, whether from lakes, rivers or streams, upland surfaces, springs
or underground sources.
(b) The Final Report of the Water Power Resources Committee, 1921.

A summary of the report is given in pp. 72-86. Appendix L (p. 146
onwards) contains details of a system by which the compilation of records
can be effected.

(c) The Final Report of the Water Power Committee of the Conjoint Board of
Scientific Societies.

(d) ‘ Report on Stream Flow and Underground Water Records,’ Trans.
Inst. Water Eng., vol. xxxiv, 1929.

(e) Annual Reports of the Water Pollution Research Board of the Department
of Scientific and Industrial Research.

Recent reports have stressed the importance of systematic records of river
flow in considering problems of the disposal of sewage and trade effluents.
(f) Ministry of Health Advisory Committee on Water. Reportof the Technical

Sub-committee on the Assessment of Compensation Water, 1930.

The conclusions set forth in the report are based on records from a
number of catchment areas, which are not available to the general public.

Some comments on this report are given in the Report of the British
Waterworks Association, 1930.

(g) Water Pollution Research. Technical Paper No. 2: Survey of the
River Tees. Part I : Hydrographical, published by the Department
of Scientific and Industrial Research, 1931.

This report gives the results of measurements of current flows in the
tidal estuary of the river Tees during 1929. It also includes measurements
of freshwater flow at different levels. "These measurements were made in
surveying the river Tees in connection with pollution problems. Additional
measurements were continued until about June 1932, and it is expected
that these will be included in a Final Report of the Survey, to be published
during the next year or two. The measurements have not included
continuous records of water level.

(h) British Waterworks Year Book and Directory, with statistical tables,
published by the British Waterworks Association.

The third edition, for 1930-31, contains useful information respecting
871 water undertakings. The information deals with such subjects as
sources of supply, filtration, distribution, hardness of the water, total
quantity supplied and estimated population.

2. THE MEASUREMENT OF STREAM FLow.
(a) Report on Current Meters for use in River Gauging, 1922.
(b) Report on River Gauging (dealing with methods and appliances suitable
for use in Great Britain), 1925.

These two reports were prepared by M. A. Hogan for the Committee on
Gauging Rivers and Tidal Currents, of the Department of Scientific and
Industrial Research. The former deals with the information available as
to the conditions affecting the design and use of current meters, and gives
a description of those types in use.

(c) The Gauging of Rivers, statement on pp. 14 and 15 of the rath Annual
Report of the Ministry of Health, 1930-31.

This statement in reference to the more systematic gauging of rivers and
underground waters is based on the work of a Committee set up by the
Minister of Health to consider the subject and to act as a Sub-committee
of the Ministry’s Advisory Committee on Water.

INLAND WATER SURVEY 369

3. REcoRDS OF STREAM FLow.

(a) The Investigation of Rivers, Final Report, by A. Strahan, N.F. Mackenzie,
H. R. Mill, and J. S. Owens (published by the Royal Geographical
Society, 1916).

This report and the four interim reports, published from 1908 to 1911, deal
with the discharges of the rivers Severn, Exe, Culm, Creedy and Medway,
and contain a report on the rainfall of the Exe Valley.

(b) Monthly Reports of the Thames Conservancy.

These give daily values of the natural flow and rainfall over the Thames
Valley above Teddington Weir. The Annual Reports of the Metropolitan
Water Board, published since 1903, give monthly totals as above.

(c) ‘ Gauging and Recording the Flow of Streams,’ by S. C. Chapman.
Trans. Inst. Water Eng., vol. xv, 1910, p. 147.

(d) ‘The Yield of Various Catchment Areas in Scotland,’ by W. C. Reid.
Proc. Inst. Civil Eng., 1913. Paper No. 4048.

(e) ‘ The Measurement of the Flow of the River Derwent, Derbyshire,’ by
E. Sandeman. Proc. Inst. Civil Eng., 1913. Paper No. 4056.

(f) ‘ Investigations into the Flow of the River Dee,’ by C. H. Roberts.
Trans. Inst. Water Eng., vol. xxiv, 1919, p. 60.

(g) ‘ Notes upon the Average Volume of Flow from Large Catchment Areas
in Ireland ; the probable duration of stated rates of flow, etc., deduced
from gaugings on the River Shannon at Killalow,’ byJ. Chaloner Smith.
Proc. Inst. Civil Eng., Ireland, January 1919.

(h) Annual Reports of the West Riding of Yorkshire Rivers Board.
Some data relating to the flow of rivers have been given in these reports,
e.g. in that on the river Don, issued in 1923 (Special Report No. 755):

(i) Quarterly Reports of River Flow Records, Ness Basin, Rivers Garry and
Moriston, 1929-31, by W. N. McClean.

Continuous records of water level are kept at seven or eight principal
points on the Ness Basin of 700 square miles, and the flows of the rivers
Garry, Moriston and Ness have been measured for all water levels between
ordinary low water and ordinary flood level. The reports give daily
comparison of rainfall, water level and flow. The records are being main-
tained and are prepared for publication when the opportunity occurs.

A paper on this subject by W. N. McClean was published in the
Geographical Fournal, vol. lxxvi, 1930, No. 1, pp. 39-49.

(j) ‘ The Lochaber Water-Power Scheme,’ by W. T. Halcrow. Proc. Inst.
Civil Eng., 1931. Paper No. 4796.

4. LAKES AND RESERVOIRS.

(a) ‘ Bathymetrical Survey of the Fresh-Water Lochs of Scotland,’ by
Sir John Murray. Geographical Journal, vols. iv, ix, xv-xviii, xxii-
XXVili, Xxx, xxxi, and xxxvi.

(b) ‘ The English Lakes, with Bathymetrical Maps and Illustrations,’ by
H.R. Mill. Geographical Fournal, July and August 1895.

(c) Some statistics as to storage capacities of the various water undertakings
are given in the Section on Waterworks Statistics in the Water
Engineers’ Handbook and Directory, 1932, and in the Return as to
Water Undertakings in England and Wales, published by the Local
Government Board, 1914 (see 1, a).

o2

370 REPORTS ON THE STATE OF SCIENCE, ETC.

5. FLroop LEVELs.

(a) ‘ Floods in England and Wales, 1875,’ by G. J. Symons. Proc. Inst.
Civil Eng., 1876. Paper No. 1464.

(b) ‘ Floods of May, 1886,’ by W. Marriott and F. Gaster. O.7.R. Meteor.
Soc., vol. xii, 1886, pp. 269-282.

(c) ‘ Floods inthe West Midlands,’ byHenry Southall. Q.7.R.Meteor. Soc.,
vol. xxi, 1895, pp. 28-39.

(d) ‘ November Floods of 1894 in the Thames Valley,’ by G. J. Symons
and G. Chatterton. Q.7.R. Meteor. Soc., vol. xxi, 1895, pp. 189-206.
These papers give details of the heights attained by certain rivers during
floods, which can be taken as typical of the information of this character
available.

(e) ‘ Report on Thames Floods,’ by A. T. Doodson, and the ‘ Meteorological
Conditions associated with High Tides in the Thames,’ by J. S. Dines,
published by the Meteorological Office, Geophysical Memoir No. 47,
1929.

An investigation carried out after the disastrous floods in the Thames,

January 6—7, 1928, as to the causes of such floods.

6. LAND DRAINAGE.

(a) The Land Drainage Act, 1930.

Part II, section 5, provides for the preparation of maps of catchment
areas. In certain cases these have already been prepared, under Capt.
Withycombe, by the Ordnance Survey.

Part V, section 43, p. 41, refers to ‘ powers of Drainage Boards to enter
and survey lands.’

(b) ‘ Land Drainage in England and Wales,’ by J.C. A. Roseveare. Trans.
Inst. Water Eng., vol. xxxvii, 1932.

(c) ‘ Present Conditions of Arterial Drainage in some English Rivers,’ by
R. F. Grantham. Proc. Inst. Civil Eng., 1916. Paper No. 4184.

7. UNDERGROUND WATER.

(a) Water Supply Memoirs and publications on Wells and Springs of certain
counties, published by the Geological Survey of Great Britain.. These
give records of sinkings and borings ; each volume, dealing with a
particular county, includes a detailed bibliography.

The Water Supply Memoirs include those of Berkshire and Oxon., Bucks
and Herts, Essex, Hampshire, Kent, Nottingham and Lincolnshire, London
Wells, Bedfordshire and Northamptonshire, Norfolk, Suffolk, Surrey,
Sussex, Yorkshire (E.R.), Cambridge, Huntingdon and Rutland; and
Memoirs on Wells and Springs of Somerset, Sussex, Leicester, Derby and
Dorset have already been published.

(b) Various papers published in scientific and technical journals, including
especially the publications mentioned on pp. 415, 420, and 421 of
this Report.

8. RAINFALL.

A short bibliography of papers relating to the rainfall of the British Isles
is attached to the Memorandum on the British Rainfall Organization.

INLAND WATER SURVEY 371

Main Memoranpum B.

ORGANISATIONS IN CERTAIN FOREIGN COUNTRIES.
By Brysson CUNNINGHAM.

The following particulars of organisations of water survey in foreign
countries are derived from information which has been courteously supplied
from official sources in response to inquiries.

I. UNITED STATES OF AMERICA.

The collection of basic information on water, its quantity, quality and
utility, is made in the United States by two Federal bureaus: the Weather
Bureau and the Geological Survey. ‘The Weather Bureau collects informa-
tion with respect to meteorological phenomena, including rainfall, snowfall,
temperature, wind movement, etc., and also obtains records of stages and
makes flood predictions for certain of the rivers which have sufficient
length to permit of the forecasting of floods a considerable time in advance
of their actual occurrence. The Geological Survey collects information
on the quantity, chemical quality, availability and utility of water, both
surface and underground, with reference to its control by reservoirs or
levees, and to its utilisation for various purposes.

Administratively, the Geological Survey is grouped with other bureaus
in the Department of the Interior, and consists of five co-ordinate
branches: the Geologic Branch, the Topographic Branch, the Alaskan
Branch, the Conservation Branch, and the Water Resources Branch.

The Water Resources Branch, which is primarily concerned with the
collection of data relating to water, is, in turn, made up of five divisions :
Division of Surface Water, Division of Ground Water, Division of Quality
of Water, Division of Power Resources, and Division of Water Utilisation.
The Water Resources Branch maintains at the present time 2,900 river
gauging stations, of which about 2,000 are equipped with recording gauges.

Records of systematic observations in meteorology are published by the
Weather Bureau. Similar observations in regard to water, both surface
and underground, are published by the Geological Survey.

The cost of collecting the data and maintaining the above services is
divided between the Federal Government and the several States. The
Geological Survey conducts the major part of its investigational work in
regard to water supplies in co-ordination with about 40 out of 48 States.
This co-operative work is paid for jointly, but is supervised and controlled
by the Geological Survey.

The Director of the Geological Survey, who furnished the foregoing
information, makes a striking comment which must be quoted in full :-—

* One of the phases of our organisation, which may be of sufficient interest
to justify me in mentioning it specifically to you, is the segregation of the
investigational activities from those related to construction or adminis-
tration. This segregation seems to us in this country to be of considerable
importance because of the human tendency to protect in times of stress
only those activities that are of greatest interest to the controlling officials,
and because of the suspicion as to integrity or reliability of records that
arises if the responsible agency in their collection has ex parte interests in
the records.

“It has been, I believe, well demonstrated here that continuous and
reliable records needed as a basis for sound development or for satisfactory

372 REPORTS ON THE STATE OF SCIENCE, ETC.

administration and adjudication can be collected only by the States or
the Nation. Records collected by other agencies will be liable to lack of
continuity, will not be generally available to the public, and will be open
to suspicion as to reliability.’

Finally, it is to be noted that boundaries of districts in which the field work
of the Surface Water Division is carried on, are made along State lines in
order to simplify arrangements for State co-operation. In general, each
district covers an area of one or more States.

II. DoMINION OF CANADA.

Observation of rainfall in Canada is the function of the Meteorological
Service of Canada, which is a branch of the Department of Marine. ‘The
Service maintains over 700 climatological and other stations making con-
tinuous records of pressure, humidity, cloudiness, wind, precipitation and
evaporation. Records are published monthly, and information is supplied
free of charge.

The measurement and recording of stream flow is undertaken by the
Dominion Water Power and Hydrometric Bureau, which is a branch of
the Department of the Interior and is carried on in each province by virtue
of co-operative agreements between the Department and the respective
provincial governments, under which the Department is responsible for
the basic investigations with the requisite staff and equipment, while the
provinces contribute to the cost of the field work but not on a uniform
basis. The organisation has been developed over a period of years dating
back to the end of last century, when stream measurement work was begun
in Alberta in 1898. The scope of the hydrometric survey now includes
every province in the Dominion, and the Bureau obtains and publishes all
essential data on basic problems relating to stream regulation, flood control,
navigation, water-power, irrigation, drainage, municipal water supply and
other uses of water. The number of gauging stations throughout the
Dominion at present in use is 451: others, having served their purposes,
are discontinued. Many discharge measurements are made at points
where no regular gauging station is established. There is a flood warning
service to those districts where serious floods are liable to occur.

Storage reservoirs to control stream flow have been constructed in
many parts of Canada, principally to secure a regulated flow for water
power development ; these structures have been mainly the result of private
enterprise, but some have been built by the Dominion and provincial
governments for various purposes. The policy of governmental assistance
to water power development has been carried out on a large scale in the
province of Quebec under the direction of the Quebec Streams Commission.

III. SwiTzZERLAND.

In Switzerland there are two independent organisations concerned with
the collection of data relating to water. Rainfall and meteorological
observations come under the jurisdiction of a Central Station of Meteorology
at Zurich, while the collection of hydrometric data and the supervision of
hydraulic development throughout the country fall within the domain of
the Federal Water Service (Service fédéral des Eaux).

Hydrometric observations include the levels of water in the lakes and
important watercourses, estimation of discharges, the taking of profiles
along and across certain watercourses, the soundings of lakes at certain
points—in front of their outlets and of deltas, for example—the contouring
of basins emptying into watercourses, etc.

INLAND WATER SURVEY 373

For the observation of water levels there are about 300 stations on
different watercourses and lakes, and the levels are read from one to three
times a day by observers who receive a modest remuneration. More than
half of the stations are provided in addition with automatic apparatus for
recording the levels graphically. ‘These observations are reported according
to their importance every day, every week, or every month. The most
important stations only are permanent ; secondary stations are abandoned
when observations have been taken for a sufficiently long period, generally
from ten to fifteen years, and the apparatus removed to a fresh position. As
regards hydraulic development, the Federal Water Service has supreme
supervision over the utilisation of hydraulic power from all watercourses,
public or private, and to this end they examine projects of hydraulic electric
developments on the basis of a rational utilisation of the force as a whole.
They investigate also cognate questions such as the regularisation of the
flow from natural lakes, the creation of storage basins, the steps to be taken
for reserving the exercise of river navigation, etc.

IV. ITALY.

The present Italian Hydrographic Service (Servizio Idrografico Italiano)
is of recent formation, having been instituted at the close of the Great
War, though it was preceded by two important regional bodies, the
Hydrographic Office of the Royal Magistracy of Waters, located at Venice,
and the Hydrographic Office of the Po, at Parma. In 1917 there were
added to these two northern districts eight other regions throughout the
country, and in 1923 the Italian Government placed them all under a
central authority at Rome—the Third Section of the Consiglio Superiore
dei Lavori Pubblici.

The functions of the Service are twofold, comprising duties of a per-
manent character and special research work.

The permanent duties comprise :—

(a) Meteorological observations, including temperature and rainfall.

(b) Observations and measurements of surface water, covering levels of
watercourses and lakes, the discharge of watercourses, the amount of
sediment in suspension, the temperature of watercourses and lakes,

(c) Observations and measurements of subterranean water.

(d) The periodical publication in the Hydraulic Annual of the results
of the above observations and measurements ; and

(e) Collaboration with the Department of Civil Engineering in developing
water utilisation concessions and in investigating important schemes of
hydraulic works.

The hydrometrical organisation at the end of 1930 had a total of 1,199
observation posts, of which 748 were hydrometric stations and 451 stations
for measuring discharges.

Main Memoranpum C.

THE BRITISH RAINFALL ORGANIZATION.
By E. G. BitHam.

The Organisation was founded about 1860 by G. J. Symons, and remained
a private enterprise until 1919, when the accumulated records were acquired
by H.M. Government, and the Meteorological Office, Air Ministry, assumed
responsibility for continuing the work. The agreement under which the

374 REPORTS ON THE STATE OF SCIENCE, ETC.

transfer was effected provided for the annual publication of British Rainfall
in the same form as in the past, and for the continuance of other work
done by the Organization ‘in like manner.’ This agreement has been
scrupulously observed, with the result that cordial relationships have been
maintained with the band of voluntary observers, and with engineers and
others who were accustomed to look to the Organization for guidance in
questions relating to the supply and interpretation of rainfall data.

At the time of the transfer the Organization was rightly described by
the retiring Director, Dr. H. R. Mill, as ‘ having no parallel in any country.’

OUTLINE OF THE ORGANIZATION.

In its present form the Organization forms a section of the British
Climatology Division of the Meteorological Office, an arrangement which
ensures that the resources of the Organization may benefit to the fullest
extent from the large amount of rainfall data included in the climatological
returns rendered to the Meteorological Office by voluntary and official
stations. 'The Meteorological Office has been since 1919 attached to the
Air Ministry, and its general policy is guided by a Committee, the
Meteorological Committee, appointed by the Air Council, on which the
Royal Society, the Royal Society of Edinburgh and various Government
departments are represented. Full details will be found in the Report of
the Meteorological Committee for 1920.

The aim of the Organization is to encourage private persons and local
authorities to supplement the work of paid Meteorological Office observers
by making reliable observations of rainfall, to preserve such records for
public use, and to publish the data as fully as possible in the annual volume
British Rainfall. In pursuance of this object the Organization is at pains
to get into touch with all persons who are known to possess rain-gauges
and to invite them to forward a copy of their readings at the end of each
year on a register (Form 1090 for inch measurements, Form 1091 for
millimetre measurements) supplied gratis. A pamphlet, ‘ Rules for Rainfall
Observers,’ originally drawn up by G. J. Symons, sets out the approved
procedure for measuring rainfall and gives advice on the selection of a site
and the type of gauge to purchase. This is sent gratis to observers, actual
or prospective.

The Observing Stations fall into a few well-defined categories :—
Approximate
Numbers
(1) Official Meteorological Office stations—i.e. stations where
the observers are whole-time or part-time employees of

the Meteorological Office 4 : : : : 50
(2) Climatological stations—i.e. stations where rainfall is

measured as part of the routine of general climatological

work f 2 : : : i : ; 300
(3) Stations maintained by public authorities (mainly water

engineers) or companies concerned with water supply or

water power : { 4 } ; " ‘ 1,000
(4) Stations maintained by other authorities, mainly private

persons. : ; 4 A : i 4,000

The observers in category (1) are paid for their observations and returns
by the Air Ministry. In a few other cases where a voluntary observer is
not available a small annual payment is made for observations of rainfall,
and in a few additional cases the observer takes readings without payment

INLAND WATER SURVEY 375

from a gauge lent by the Office. With these few exceptions the Organization
relies for its data on returns made voluntarily by persons who have purchased
instruments themselves.

In general, daily readings of rainfall are furnished by all observers, but
for many stations in remote parts of mountains or moors only the monthly
total is available. All stations in categories (1) and (2) and selected stations
in other categories forward monthly reports of daily rainfall, for use in
drawing the rainfall map published in the Monthly Weather Report. At
the present time the number of stations reporting monthly is about 1,400.
For about 600 of these stations the monthly total is printed either in the
Monthly: Weather Report or the Meteorological Magazine, and for a large
proportion of these the percentage of or difference from average is also
given. The remaining stations render an annual return only.

Most stations in category (1) and a few in other categories, maintain
recording gauges, from the records of which data in regard to rainfall
duration and the intensity in heavy falls are evaluated. Eighty-one such
records were available in 1931.

LocaL RAINFALL ORGANISATIONS.

In many parts of the kingdom local interest in rainfall is fostered by
organisations, often forming. a part of a local scientific society, which collect
observations from their correspondents and publish the readings in various
forms, usually in the newspaper Press. These organisations have no
official status, but they represent some approach to a regional system of
dealing with rainfall data. They vary much in regard to the scale of their
activities, At one end of the scale we have an organisation in Ayrshire
under the control of Mr. W. Dunbar of Kilmarnock, who publishes shortly
after the close of each month a duplicated report containing readings for
100 stations, together with a map showing the distribution of rainfall over
the area. At the other end of the scale would be a small group of observers
sending in records once a month to a secretary for insertion in the local
paper. In some cases it is found possible to utilise the services of the local
organiser to deal with questions of the exposure of gauges and reliability
of readings, but such services are not utilised in any general or systematic
way. A list of local organisations known to the British Rainfall
Organization is appended :—

Hertfordshire Natural History Society and Field Club (Mr. C. P. Sinclair).

Northamptonshire Natural History Society (Mr. R. H. Primavesi).

Norfolk Rainfall Organisation (Col. H. C. Copeman).

Barnstaple Atheneum (Miss Young),

Mid-Wessex Rainfall Association (Rev. F. P. Synge).

Cornwall Rainfall Association (Mr. A. P. Jenkin).

Manchester and Stockport Rainfall Organisation (Mr. A. A. Barnes).

Irish Rainfall Association (Mr. E. W. M. Murphy).

Mr. A. J. Jenkins of Jersey, Miss Cordelia Marshall of Ambleside, and
Mr. W. Dunbar of Kilmarnock also collect rainfall statistics regularly.

EXTRACTION, CHARTING AND PUBLICATION OF Data.

Monthly and annual totals for nearly all stations are plotted on maps,
from which the charts of rainfall distribution published in British Rainfall
on a greatly reduced scale are drawn. Maps are also prepared showing
the annua] number of ‘ rain-days’ and ‘ wet-days.’ The monthly and
annual total fall for every station is entered on a ‘ ten-year sheet.’ Stations

376 REPORTS ON THE STATE OF SCIENCE, ETC.

are classified geographically, first by Districts (groups of counties), then
by River Divisions. Ten-year sheets for stations in the same River
Division are filed in sequence, the file thus forming, when completed, a
ten-year history of the rainfall in each River Division of a District. This
arrangement makes it possible readily to turn up the rainfall at any station
in any month and year.

For the great majority of stations the space allotted in British Rainfall
is a line in Part III giving the diameter of the gauge, the height of ‘its
rim above ground, the height above sea-level, the average rainfall (if known),
the year’s total, the number of rain-days and the number of wet-days.
Such data were published for 5,329 stations in 1931, 5,316 in 1930, and 5,180
in 1929. The number has been in the neighbourhood of 5,o00 for the
past twenty years. Unfortunately the distribution of stations is very
uneven, the sparsely populated districts being poorly represented. "The
number of records per 100 square miles of area is as high as 28 in Middlesex,
but is under 1 in parts of Scotland and Ireland. About 300 new stations
are enrolled every year, and about the same number terminate. The
average ‘ life’ of a station is therefore about eighteen years. A frequent
cause of the cessation of a record is the death of the observer or his removal
to a new district. In some cases it is possible to arrange for the record to
be continued by a relative or the new resident, and every effort is made to
ensure such continuity, more particularly in the case of long records.

The records for all stations are scrutinised in relation to ‘ heavy falls on
rainfall days’ (British Rainfall, Part II, Section 7), but selections of stations
are made for the purpose of studying the special aspects of rainfall dealt
with in other sections of the volume. For example, 100 stations are used
for the purpose of Part II, Section 2 (number of rain-days and wet-days),
Section 3 (droughts), and Section 4 (rain-spells), 400 stations for Section 8
(monthly rainfall, Table XX), and 150 stations for Tables XXI and XXII,
giving the monthly and seasonal fall as a percentage of the average.

RAINFALL DATA IN OTHER PUBLICATIONS.

Reference has already been made to the Monthly Weather Report and
the Meteorological Magazine. Other Meteorological Office publications
containing rainfall data are the following :—

The Weekly Weather Report gives weekly and seasonal totals of rainfall
at each of sixty stations, together with the heaviest fall in each week and
the relation of the weekly total to the normal. General values !! for Districts
are also given.

The Observatories Year Book contains hourly values of rainfall at the four
Observatories: Aberdeen, Eskdalemuir, Richmond and Valentia; also
monthly totals of duration in each hour. For Richmond, Surrey, daily
values of water level in a well are given.

The Book of Normals (M.O. 236, Section V) contains monthly and
annual values of average rainfall for the period 1881-1915 at 578 stations,
and also general averages for the British Isles and its major divisions.
Monthly averages of the number of rain-days at certain stations will be

11 In the nomenclature of the British Rainfall Organization ‘ general value’
means the average for an area. In the Weekly Weather Report the quantity
represented by the weekly (or seasonal) general value for a District is the space-
average of the percentage of normal rainfall in a given week (or season) at five
selected stations in that District. This value is briefly referred to as the ‘ District
value. .

INLAND WATER SURVEY 397

found in the Book of Normals, Section I. Section II contains weekly,
monthly, quarterly, half-yearly, seasonal and annual normals for Districts.
Section III contains small-scale maps showing the monthly and annual
average distribution of rainfall over the British Isles. Section IV includes
tables showing the range of variation of rainfall and of the number of
rain-days at twenty-eight stations.

Mention should also be made of the Rainfall Atlas of the British Isles,
published by the Royal Meteorological Society. This contains monthly
and annual maps of average rainfall, two maps showing the distribution of
rainfall in the wettest year (1872) and the driest year (1887), and a series
of maps showing the distribution of rainfall as a percentage of the normal
in each year from 1868 to 1923. ‘The Introduction, by Dr. H. R. Mill,
gives the history of the British Rainfall Organization and contains a valuable
discussion of the data represented in the charts.

AVERAGES.

The standard period for which averages are calculated is 1881-1915.
One of the aims of the Organization is to produce a map of Annual Rainfall
for the whole of the British Isles, on the scale 2 miles = 1 in. The
importance of completing this map was stressed by the Water Power
Resources Committee in paragraph 276 of its Final Report. The position
(December 1931) is now as follows :—

England and Wales 1881-1915 (Rainfall Survey) maps completed for
about two-thirds of the area; work now in progress on Cumberland,
Leicestershire, Rutland, Gloucestershire, Bucks, Berks, Herts, Middlesex,
London and Cornwall. Remainder of area already mapped by Dr. H. R.
Mill, but not for standard period.

Scotland 1881-1915 maps completed for about half the area. Of the
remainder about half has already been mapped, but not for standard period.

In drawing these maps all available information is used, averages for
stations with short records being weighted to the standard period by com-
parison with nearby stations having standard averages. The averages so
computed are included in Part III of British Rainfall. Reduced copies
of specimen maps and a description of the method used in their preparation
are given in articles published in Part IV of British Rainfall, 1928 and 1929.

It should be emphasised that the Rainfall Survey maps are not regarded
as representing the ‘ last word’ on the subject of the rainfall of a specific
small area. If required to produce a map, e.g. for the purpose of a water
supply scheme, the British Rainfall Organization would prefer to go over
the ground again, and in its final form the map might differ slightly from
the original Survey map, where the lines are naturally somewhat generalised.
Ad hoc maps for such purposes can usually be prepared at short notice even
for areas not yet covered by the Survey.

RUN-OFF.

The British Rainfall Organization is not, in present circumstances,
officially concerned with run-off. The volumes of British Rainfall contain,
however, certain data which are related to this aspect of hydrology. Each
volume contains a chapter on evaporation and percolation records. British
Rainfall, 1931, contains values of rainfall, percolation and calculated
evaporation at four stations, and of evaporation measured from a free
water surface in a tank at twelve stations.

378 REPORTS ON THE STATE OF SCIENCE, ETC.

PROFESSIONAL WORK.

The Organisation is frequently consulted in connection with the evaluation
of rainfall for water supply or water power purposes, and any such evaluations
included in Water Bills generally rest on the authority of the Organization.
Work of this character is regarded as ‘ professional work’ and is performed
under the terms set out in an official form (Form 928) which requires the
applicant to sign a form of agreement (Form 927). Inthe form of agreement
it is definitely stated that ‘ the opinion and advice shall be limited to con-
sideration of rainfall, and shall not extend to such matters as evaporation,
percolation, run-off, or other cognate questions.’ In brief, the Organization
is prepared to accept responsibility for estimating the average amount of
rain that may be expected to fall on an acre, but is not prepared to estimate
how much of it may be available for purposes of consumption or power.

OTHER INQUIRIES.

The records of the Organization may be consulted free of charge at the
Meteorological Office, Exhibition Road, S.W. 7, between the hours of
10 A.M. and 4 P.M. on Mondays to Fridays, 10 A.M. to I P.M. on Saturdays.
Replies to inquiries which can be dealt with by reference to the files of
rainfall data are furnished at a small charge to cover the cost of the clerical
work involved.

RESEARCH WORK.

Original papers on rainfall and associated subjects are included in Part IV
of British Rainfall. Recent volumes have included important papers on
the exposure of rain-gauges by F. Hudleston, M.Inst.C.E. Lists of
published papers will be found in the volumes for 1925 and 1900. A short
bibliography of the more important papers on the rainfall of the British
Isles which have appeared in British Rainfall and elsewhere is appended.

Syort BIBLIOGRAPHY OF PAPERS RELATING TO THE RAINFALL
OF THE BriTISsH ISLES.

M. ve Carte S. SALTER: The Rainfall of the British Isles. University of
London Press, Ltd.

C. E. P. Brooks and J. GLassPpooLe : British Floods and Droughts. Ernest
Benn, Ltd.

H. R. Mitt: ‘ Mean and Extreme Annual Rainfall over the British Isles,’
Proc. Inst. Civil Engineers, 1903.

H. R. Mitt and M. bE CaruE S. SALTER: ‘ Isomeric Rainfall Maps of the
British Isles,’ O.¥.R. Meteor. Soc., vol. xli, 1915, pp. 1-39.

J. GrasspooLe: ‘ The Fluctuations of Annual Rainfall,’ British Rainfall,
1921, pp. 288-300.

M: pe Carte S. SALTER and J. GLAsspooLe: ‘ Fluctuations of Annual
Rainfall considered Cartographically,’ O.7.R. Meteor. Soc., vol. xlix, 1923,
pp. 207-225.

J. GuassPoote : ‘ A comparison of the Fluctuations of Annual Rainfall over
the British Isles,’ British Rainfall, 1922, pp. 260-266.

J. GiassPooe: ‘ Fluctuations of Annual Rainfall: A comparison of 35-year
Rainfall Averages over the British Isles for different groups of 35 years
falling in the period 1868 to 1921,’ British Rainfall, 1923, pp. 238-256.

J. GrassPooe: ‘Fluctuations of Annual Rainfall, Three Driest Consecutive
Years,’ Trans. Inst. Water Engineers, vol. xxix, 1924, pp. 83-110.

INLAND WATER SURVEY 379

J. Giasspoo_e : ‘ Fluctuations of Monthly Rainfall,’ British Rainfall, 1922,
PP. 234-259.

J. GuasspooLe: ‘ General Monthly Rainfall over the British Isles, 1881
to 1924,’ British Rainfall, 1924, pp. 256-266.

W. N. McCiean: ‘An Analysis of Scottish Rainfall Records. Rainfall
of the driest periods of one month and upwards,’ Trans. Inst. Water
Engineers, vol. xxx, 1925, pp. 95-118.

J. GuassPooLe: ‘ Average and Extreme Seasonal Rainfall over the British
Isles,’ Trans. Inst. Water Engineers, vol. xxxiii, 1928, pp. 51-69.

J. GiasspooLe: ‘ The Distribution over the British Isles in Time and
Space of the Annual Number of Days with Rain,’ British Rainfall,
1926, pp. 260-279.

F. HupLeston: ‘ Experiments with Rain-gauge Shields at Hutton John,
Penrith.’ Reports areincluded in British Rainfall, 1926, 1927, 1928, 1929,
1930 and 1931.

J. Giasspoore : ‘ Areas Covered by Intense and Widespread Falls of Rain,’
Proc. Inst. Civil Engineers, 1930.

J. GuasspooLe: ‘ The Reliability of Rainfall over the British Isles,’ Trans.
Inst. Water Engineers, vol. xxxv, 1930.

J. GuasspooLe : ‘ Heavy Falls of Rain in Short Periods (two hours or less),’
Q.3.R. Meteor. Soc., vol. lvii, 1931, pp. 57-64.

A. A. Barnes: ‘ Rainfall Reviewed, A Common Long-average Period for
each Country of the British Isles,’ QO.¥.R. Meteor. Soc., vol. lviii, 1932,
pp. 126-142.

Sus-MEMoRANDUM C (1).

RAINFALL DATA IN RELATION TO INLAND WATER
SURVEY.

By E. G. BitHam.

In Memorandum C the arrangements for dealing with rainfall data, as
they exist at present, are briefly described. It is now proposed to consider
the particular aspects of rainfall which call for attention in relation to
inland water survey. The subject may be treated conveniently under two
main headings :—(I) The type of data needed, and (II) The arrangements
necessary for supplying the data.

I. THe Type or DATA NEEDED.

In any study relating to inland water, whether surface water or under-
ground water, the rainfall is of primary importance because it represents
the starting-point in the sequence of physical operations, the final result of
which is seen in the variation of river flow, of lake level or underground
water level. One may assume that when an Inland Water Organisation
comes into existence it will have two main aims : (a) the determination, by
direct measurement, of the amount of water that finds its way into streams
or goes into underground storage; (b) the investigation of the relationship
between such amounts of water and the amounts which are deposited on
the catchment area in the form of rain. ‘The first essential, so far as (b) is
concerned, is that there should be sufficient rain gauges in the catchment
area and that they should be so exposed and distributed that reliable
estimates of the general rainfall over the area during a given period can
be made. Since the rise and fall of river level at a given gauge point

380 REPORTS ON THE STATE OF SCIENCE, ETC.

represents the integrated effect of the drainage over the whole catchment
area above the gauge point, we must assume that changes of level in the
river will be related to the general rainfall over the area, and the scheme of
operations must be planned in such a way that the general rainfall can
readily be evaluated as a matter of routine.

It may be remarked, in passing, that at any given season the fraction
of the rainfall, incident on a given area, that finds its way into a stream
depends on the geological characteristics of the area. This is of course
quite well known, and the object of mentioning it here is to point out
that in areas where there are wide variations of geological structure it may
be necessary to make separate evaluations of the rainfall for subdivisions
of the area based on geological considerations. This would be a point
to bear in mind when selecting sites for rain gauges.

The next point that arises is the question as to how often it is necessary
to read the gauges. For certain purposes, particularly the investigation of
flood levels, it would be necessary to have continuous records of rainfall
furnished by recording gauges, at least at a few points within the catchment
area, but we must assume that the majority of gauges will continue to be
ordinary gauges of the type in which rain is collected in a receiver and
read by eye in a graduated measure. Hitherto it has been customary, in
systematic studies of rainfall and run-off, to deal with calendar monthly
values. That is, for example, the method adopted by the Thames
Conservancy, whose reports show in parallel columns the total discharge in
the month over Teddington Weir, and the general rainfall in that month
in the Thames Basin above Teddington Weir. If that scheme were
standardised as the normal procedure under the Inland Water Survey
Organisation, it would suffice, therefore, if monthly totals of rainfall were
available for all stations. In practice daily readings of rainfall are made
by the majority of observers contributing returns to the British Rainfall
Organization, the monthly totals being arrived at by summation of the
daily readings. At certain stations, particularly in remote spots on
mountains or moors, it is impracticable to read the gauge every day and
the rainfall is, at such stations, normally allowed to accumulate for the
whole month and then read. ‘There is no evidence to show that a monthly
total measured directly in this way is not on the whole as reliable as a
monthly total obtained from separate daily measurements. If the month
is adhered to as the major unit of time for Inland Water Survey purposes,
no need arises therefore for any change from existing practice in regard to
rainfall measurements.

Captain McClean, however, has on more than one occasion expressed
the view that a fixed interval such as a month is inappropriate, and that
for such studies as are contemplated the days should be grouped into
“rain periods’ and ‘ dry periods.’ In this Memorandum we need only
consider the pros and cons of that view in so far as they bear on rainfall
data. From the observing point of view the only stations affected are those
where gauges have hitherto beenread onlyonceamonth. Captain McClean’s
proposal involves either reading such gauges daily or making use of some
form of recorder, the chart of which when removed at the end of the month
would yield readings foreach day. The latter solution presents considerable
difficulty, which will be realised when it is remembered that the instrument
would have to work for a month without attention and would have to be
fitted with some form of heating device to prevent its being thrown out

12 At certain stations the gauge is read weekly, fortnightly or at irregular
intervals, depending on the weather, as well as on the first of each month. %

INLAND WATER SURVEY 381

of action by frost. Experience shows, however, that if daily readings are
available from a number of gauges in a given area, the monthly total measured
in a mountain gauge can be apportioned with fair accuracy among the wet
periods occurring in a given month. The loss of precision due to the
absence of daily readings from particular localities would therefore not
be very serious.

Given a sufficient number of stations with daily readings, supplemented
by monthly totals at stations inaccessible for daily readings, the evaluation
of general rainfall for rain periods presents no serious difficulty. ‘The most
accurate method of making such evaluations is to draw large-scale rainfall
maps, measure the areas with falls between given limits, and thus arrive
at the space-average or general fall. A quicker and only slightly less
accurate method is to make a selection of stations, well spaced within the
area, and determine by a preliminary investigation the relation between
the arithmetical average of the falls of these stations and the general
rainfall determined from maps. When this has been done the selected
stations can be used for the routine evaluations and the maps can be dis-
pensed with.!* The number of stations need not be very great provided
they are well distributed and the gauges are well exposed. It is found,
for instance, that the arithmetical average of the falls measured at twenty-
four selected stations in the Thames Basin gives a very close approximation
to the monthly general rainfall deduced by a planimetric method from a
rainfall map based on readings from over two hundred stations in the basin
and its vicinity. Six stations suffice to yield an equally close approximation
in the Lea Basin. When dealing with shorter periods than a month rather
more gauges would be desirable in order to ensure that localised heavy
rains were not missed, but it would appear unnecessary, in routine work
on run-off problems, to deal with daily readings from more than a dozen
or so gauges in each catchment area, the number depending of course on
the size of the catchment. A close preliminary study of the rainfall in
the area would, however, be necessary before the gauges whose records
were suitable for such routine use could be selected. Such a survey would
necessitate reference to the records from many more gauges than would °
suffice for routine evaluations of general rainfall, and it should be made
clear that the British Rainfall Organization would always regard it as essential
to collect records from all available gauges for the purpose of rainfall study
in general.

Returning to the question of the time interval, my considered view is
that while the study of rain periods may possess substantial advantages
for dealing in detail with the run-off data for single catchments (such as
might form the subjects of special memoirs), it would be necessary to adhere
to definite calendar periods such as months, or groups of months, for the
purpose of any regular periodical publication containing results from all
the catchments participating in the scheme.

In regard to the use of recording gauges, I do not regard it as necessary
to have many in each catchment area. For detailed study of particular
falls, especially falls associated with floods, the records from one or more
continuously recording gauges with daily charts would undoubtedly prove
useful if not essential. Any such gauge should be in the charge of a com-
petent employee, who could be relied upon to give it the necessary attention,

*and it would be necessary, in each case, to take daily readings for check
purposes from an ordinary 5-in. gauge close to the recording gauge.

18 The routine evaluations could, if necessary, be revised at a later date by the
British Rainfall Organization, using the cartographic method.

382 REPORTS ON THE STATE OF SCIENCE, ETC.

Since the study of run-off involves questions of evaporation and per-
colation, it would be desirable to set up evaporation tanks and percolation
gauges in each area. The word ‘ desirable’ is employed because I think
it would be well to encourage but impolitic to press water supply authorities
and other participants to incur the expense of such installations, the value
of which is problematical. I feel sure, however, that investigators would
feel the need of some direct measurements—even rough measurements—of
evaporation and percolation. In seeking the co-operation of authorities
in any general scheme for Inland Water Survey, the desirability of installing
evaporation tanks and percolation gauges, at least in a few of the more
important areas, should therefore be borne in mind.

II. THE ARRANGEMENTS NECESSARY FOR SUPPLYING THE DATA.

The British Rainfall Organization has always relied for its information
mainly on data contributed voluntarily by interested persons. Among
these, authorities directly connected with water supply have always formed
a very important section. I assume that it will be the policy of any
organisation formed for the purpose of Inland Water Survey to follow the
lead of the British Rainfall Organization in this respect. If that is done
I have no doubt that the Survey Organisation will have no difficulty in
obtaining the rainfall data that it needs without expenditure other than
perhaps a few small annual payments to observers in remote and thinly
populated areas.

Except in so far as it will be necessary in some cases to improve the
distribution of gauges over the catchment areas, it may be said that the
means for supplying the rainfall data already exist in a fairly complete
form. 'The need for more gauges in certain areas becomes very evident
when it is recollected that in more than one recent water bill it has been
necessary to make provision for the determination of the rainfall of the
catchment area as a preliminary to the final assessment of compensation
water. One of the first steps to be taken in any river basin where gauging

“operations are contemplated is to go over the ground for the purpose of
ensuring that such rain gauges as already exist are giving satisfactory results,
and to arrange for starting such additional records as may be necessary
to secure satisfactory evaluations of general rainfall.

The gathering grounds under the control of existing water undertakings
are, in the majority of cases, reasonably well furnished with rain gauges.
Normally, therefore, it will be necessary to invoke the aid of private persons
in extending the distribution of gauges into areas where the representation
is unsatisfactory, and the fact has of course to be faced that the absence
of human habitations makes it impossible in some areas to obtain readings
through the usual channels. ‘The Meteorological Office has itself installed
gauges in certain remote areas, e.g., in the region above Borrowdale in
Cumberland, and at Newbridge and Cranmere Pool on Dartmoor, and
arranged for a monthly visit to be paid to the gauges by a local resident.
In some cases a small annual payment is made for such services.

Whatever form the organisation for water survey may eventually assume,
it is quite obvious that it will have to maintain a close liaison with the
British Rainfall Organization. ‘The liaison should extend to all matters
relating purely to rainfall and should include : °

(1) Advice by the British Rainfall Organization in regard to the selection
of sites for new gauges and in regard to the reliability of records
from existing gauges.

INLAND WATER SURVEY 383

(2) Advice by the British Rainfall Organization in association with the
Instruments Division of the Meteorological Office, in regard to
instruments, including evaporation gauges and percolation gauges.

(3) The selection by the British Rainfall Organization of stations whose
records should be used for routine evaluations of general rainfall.

(4) Co-operation with the British. Rainfall Organization in obtaining
additional observers where necessary.

(5) Avoidance of overlapping in regard to publication of rainfall data.

In regard to (5) it may be pertinent to point out that twenty years ago
there were, in the British Isles, four separate bodies concerned in collecting
and publishing meteorological data, viz. :—

The Meteorological Office.

The British Rainfall Organization.
The Royal Meteorological Society.
The Scottish Meteorological Society.

There is now only one such body, the Meteorological Office, of which
the British Rainfall Organization forms a constituent part. This unification
of control has taken years to achieve, and has proved advantageous to all
concerned. Any arrangement made for the supply of rainfall data to the
Water. Survey Organisation should be such as to comply with the general
principle of unification. It should not prove difficult to formulate a scheme
under which the British Rainfall Organization maintained general super-
vision of the rainfall data, so that reports rendered by voluntary observers
remained reports to the British Rainfall Organization, although the scheme
might involve their passing through the hands of Water Survey officers at
some stage.

Such are the general principles which should, I suggest, be kept in
mind when framing an actual scheme for Inland Water Survey on a national
scale.

Main Memoranpum D.

SURFACE WATER.
By W. N. McC.ean.

1. MEASUREMENTS AND RECORDS IN OTHER COUNTRIES.

In many other countries measurements and records of river flow appear
to be better organised than similar work in the British Isles. Probably this
is due to the particular problems to be solved and to the lack of rainfall
records, such as those of the British Rainfall Organization.

‘The existing organisation of Inland Water Survey in other countries is
dealt with in Memorandum B.

2. MEASUREMENT AND RECORDS IN THE BRITISH ISLES.

All over the country a great many surface water measurements have
been made, and in many cases there are long records of flow, or of water
levels. Almost all of these measurements and records arise out of com-
mercial developments of water and, as is only natural, the measurements
made have been such as each development required. The measurements
of a water supply authority are generally those of the actual supply, and of
the water required by law to pass down the stream or river; and there are
usually no measurements of total run-off from an area.

384 REPORTS ON THE STATE OF SCIENCE, ETC.

Water power undertakings, canals, electricity power stations, pumping
stations, etc., practically measure only the water that they use, or may require
to use. Even with river boards, the total flow of the river has not been
dealt with seriously. At most ports and harbours will be found automatic
tide gauges recording the rise and fall of the tide; but there are few of
these to be found on any of our rivers, and generally a daily reading over
a weir gives the estimate, by a laboratory formula, of the day’s flow. If a
questionnaire went round to all water authorities and river boards, the
answers would probably indicate a host of measurements and quite a
number of records, dependent on some semi-appropriate formula.

In these days, instruments and apparatus of considerable accuracy and
efficiency exist for the measurement of river or stream flow. Measurements
can be made in various ways, some of which, no doubt, require more
experience for perfecting. The improved methods of measurement
should be adopted, and with their adoption would come the keeping of
continuous records of water level and flow at many important sites on our
rivers ; and, in addition, records of rises and falls in lake levels, total flows
from supply catchment areas, and water used daily in canals to cover
evaporation, leakage and traffic.

From the measurements and records the engineer would be assured of
the correct values of available water on which to base his scheme and to
design the works.

Water authorities, corporations and individuals are in a position to keep
the necessary records. Fishery boards, mill owners and water power
companies, water supply authorities, canal and river authorities, boating
associations, etc., have their data only in such a form as is sufficient for
their own purposes. Every one of these individuals and authorities
should be encouraged to see that, in the future, their measurements show
not only what they themselves take but, when possible, how much they
leave for others.

In the closely-woven pattern of water utilisation in our crowded country,
no single interest can take away, divert, pollute, hold up, or change the flow
of our rivers without affecting the interests and rights of other users. This
country has, therefore, reached that stage when a comprehensive system of
records of total flow is required in order that the quantities available may
be known.

3. WaTER SURVEY IN RELATION TO LAND SURVEY.

The catchment areas of streams and rivers, the areas and depths of
lakes, reservoirs, canals, etc., the lengths and sections of rivers, the sites
of springs and the capacity of flooded areas are all ordinary survey work,
and can be recorded on the Ordnance sheets or on suitable plans and
tables. They are the static measurements of surface water, and once
done only require keeping up to date.

All these measurements require accuracy, and if not actually made by
our Ordnance Survey should at least be supervised by that authority.
The Ordnance sheets to-day give the boundaries or river catchments, the
sources of streams and rivers, and the sites of lakes, canals, etc., and some
springs. On the Scottish maps the depths of all lakes are given, and of
some of the English lakes the depths are known. Flooded areas are denoted
to some extent on Ordnance sheets, and on main rivers the limit of tidal
flow is shown. Subsidence areas require to be included where subject
to flooding. The general slope of river beds requires some representation
by longitudinal section, with the marking of critical points and the addition

INLAND WATER SURVEY 385

of some standard sections of the river ~ likely points for water-level records
and on typical reaches.

These static measurements are the foundation work on which to build
the continuous records of water level and flow.

4. RAINFALL, STORAGE, AND FLow IN RELATION TO SURFACE
WATER AND ITS MEASUREMENT.

(A) Rainfall—The measurement of rainfall by rain gauges distributed
over a catchment area provides the primary assessment of potential flow
in the stream or river. In the absence of flow measurements, the total
flow during any period is estimated from such assessment of rainfall by
deducting certain assumed losses. Those losses are, in fact, the estimated
difference between rainfall and run-off derived from some specimen areas
where rainfall and run-off have been measured over a long period of years.

In these specimen cases, the assessment of rainfall on the area depends
on the method of working out the distribution, and must be uncertain unless
there are a great number of gauges. In practice, the rainfall assessment is
generally made for the year, and sometimes for each month. Even if the
gauges are numerous and read daily, it would hardly be practical to make
a daily assessment. On the other hand, the run-off measurement is a
concentrated measurement which, with the proper apparatus, may be of
great accuracy, and may be tabulated for any desired time interval—half-
hour or three hours or the day. Owing to the present limitations of the
rainfall assessment there is only an annual estimate of losses, and it is
necessary to proportion this loss over the months of the year on the basis
of the evaporation losses measured in a tank.

This method of estimating run-off from the rainfall has been developed
on the foundation of our long rainfall records, and in certain directions it
has been standardised and accepted as a legal measure of run-off, It is
recognised that this indirect measurement of surface water run-off is un-
satisfactory and productive of very erroneous results.

For accurate measurement of water, for any purpose, it is the actual
continuous records of flow past a measuring point which are essential, and
rainfall and other measurements then fall into their correct places for use
in correlation to the measured flows.

The point emphasised here is that, in fact, the measurement of surface
water has been dispensed with in practice, because there exists a cheap
method of estimating flow from rainfall.

As one example of the danger of such an approximation one may take
the example of the assessment of compensation flow (Ministry of Health
Advisory Committee on Water: Report of Technical Sub-Committee on
the Assessment of Compensation Water. H.M. Stationery Office, 1930).
As other examples, one may take the cases of water power schemes, etc.,
where erroneous estimates of flow may make the scheme and wreck valuable
existing interests or, conversely, may wreck a valuable scheme.

(B) Storage.—Dealing with the whole of a river catchment area, storage
may take many forms, but, in its widest sense, storage is represented by
certain natural and artificial physical characteristics of the area which
modify the intensity, duration and volume of the flow. The need for
continuous measurement of storage, in its relationship to flow, becomes
at once apparent.

: ae forms of storage affecting surface water may be described as
ollows :—

386 REPORTS ON THE STATE OF SCIENCE, ETC.

*

(a) Snow and ice, increasing the flows of the late spring and. causing,
during a thaw, sudden heavy floods in the lowlands.

(b) Ground saturation, causing quicker run-off in floods and a slower
fall after the cessation of rain.

(c) Tarns, lakes, reservoirs and canals, holding up and prolonging the
floods and having varying effects on low flows.

(7) Flooded areas, ditches, etc., in the lowlands, reducing the peak
intensity of flood flows.

(e) The capacity of the river channel and artificial channels in the low-
lands, and of coastal embanked areas which keep out tidal flow.
All of these affect the water levels and water slopes.

The measurements of evaporation and condensation, etc., are subsidiary
to the main measurements and, in fact, cannot be ascertained except through
analysis of the completed records.

The capacity for storage of different portions of a catchment is one of
the principal factors governing intensity and duration of flood flows. When
rainfall ceases, there are all descriptions of storage in action and, as the
rainless period extends, the aggregate flow since rain ceased comes nearer
and nearer to the measure of total area storage. An area will drain off in
very similar fashion after each flood, subject to certain variants such as
saturation or melting snow, etc.

Therefore, after rain ceases, the aggregate flow measures, firstly, the
flood capacity of the river and some flooded areas: a most valuable
measurement combined with land survey and river-bed survey and water
levels. Later, the aggregate flow measures the de-saturation of the area.
The rains which fall in summer and do not run off are also a measure of this
de-saturation volume.

The continuous record of water level at carefully selected sites is the
foundation of all problems connected with the various forms of storage.

When the areas of lakes and reservoirs are known at different water
levels and the outflow is known, the rate of change in water level of such
areas yields the inflow value.

When, on a river, the inflow to and outflow from a flooded area has
been measured, the capacity of such flooded area can be estimated.

The times of concentration at various points on streams and rivers are
a measure of area storage. This is particularly applicable to reservoired
areas, when the interposition of a reservoir lengthens the period of concen-
tration according to its volume and its weir dimensions.

In the control of floods, water level information on all these storage areas
throughout the catchment and the knowledge of the times of filling and
emptying such storages are of the first importance.

The bearing of storage on the maintenance of good low flows is obvious
and probably requires no further comment here.

(C) Flow.—The River Basin is the obvious unit of area for the records
of flow, and the general characteristics of the area will indicate the sites
at which flow measurements should be made and at which continuously
recorded water levels should be maintained. Gauge post water levels at
numerous other sites will complete the picture.

The principal object should always be the measure of aggregate flow as
obtained by continuity of water level records. The actual measurements
of flow, for all water levels, at a selected site should be done once and for
all with the utmost accuracy.

The aggregate flow which passes a gauging site during a flood or series
of floods is only in a secondary manner affected by the configuration of

INLAND WATER SURVEY 387

the river—sundry minor losses will vary according to the duration of the
floods and the extent of flooding. ‘Thus the aggregate flow of flood periods
is a definite figure which may be compared with the rainfall; it is inde-
pendent of the temporary effect of storage areas and of critical blocking
points ; it is a figure alike of natural and of controlled flow, to be amended
only by definite figures of impounded storage and by figures of remaining
or residual off-flow down to some standard low-water level.

The peak flows and their times at various points are due to configuration,
natural or artificial, and their investigation gives the information required
for river improvement or any required modification of storage and intensity
of flow.

The characteristics of the river reaches which determine the selection
of the actual flow gauging site are better left to the Memorandum on River
Gauging; it is the characteristics of the whole river basin which indicate
the general position at which flow measurements are required. It may
be that artificial works will create a site for flow measurements. ‘The values
of flow ‘at well-chosen sites will be the best basis for estimates of flow at
intermediate points.

The selection of these sites and the continuous records of water levels
should clearly come under the Catchment Boards; the actual measure-
ments of flow at principal points should be carried out by trained men
with the very best apparatus that can be devised.

A river basin may be subdivided in a general way as follows :—

(a) The uplands, mountain streams, tarns and springs and artificial
reservoirs.

(6) Main tributaries and main rivers in narrow valleys with, generally,
a considerable water slope and no extensive flooded areas.

(c) The same, passing through wide valleys with winding courses and
sometimes lakes, and often with other considerable feeding streams.

(d) Lowland plains at the junction of tributaries or in the final estuary
of the main river.

(a) Streams and springs are measured generally by weirs, preferably at
the outlet of pools.

These measurements are made at present only in connection with water
supply and water power schemes, and the records are often discontinued
after the completion of the works. With regard to other springs and
streams it is unlikely that much will be done at this stage, and knowledge
of rainfall and of measured streams will suffice.

In any organisation of water measurements and records it is clear that
water supply and water power authorities should instal apparatus for
providing complete records of total run-off from their catchment areas.

Undoubtedly these water supply and water power areas afford an
excellent theatre for complete water measurement. A great number of
rain gauges may be installed with daily readings and possibly others of a
recording type.

With suitable apparatus for the recording of water levels and flow, not
only may the total flow be ascertained for any short or long period of time,
but, in addition, accurate values of flow over different weir crests may be
ascertained. Also, valuable data will be obtained, on the reservoirs, of
the period of concentration of floods on upland areas.

* All this data has already been called for by the Floods Committee of the
Institution of Civil Engineers in order that a knowledge of flood flows may
allow of correct design of reservoir spillways. Such data will eventually

388 REPORTS ON THE STATE OF SCIENCE, ETC.

place the settlement of compensation water on a proper footing and save
considerable outlay on works.

(6) The narrow valleys where the river is confined during floods are
distinctly suitable for flow measurements, especially if a pool reach is
available or can be made by inserting a sunken weir. Such sites are well
adapted to accurate current meter gaugings.

(c) The open valleys and lake areas are eminently suitable for water level
records which, coupled with flow measurements at the outlet from such
areas, will give valuable information as to storage effect.

(6) and (c) will provide the principal flow measurement sites before the
river emerges on the final lowlands. ‘The continuous water level records
may, in many cases, be maintained by canal undertakings or electrical
power stations or river water supply stations or other works.

(d) Lowland plains: The flow in these lowland plains may be difficult
to correlate with water levels as the water slopes will vary considerably
with rising and falling floods and general backing-up effects. It would
seem more advisable to concentrate on measurement of channels, and so
forth, and on the installation of well-situated water level stations.

Improvements in storage capacity and, consequently, in water slope in
these lowland areas appear to be the key to improved drainage ; and the
fen areas are an example of what has been effected in this way. With
increased capacity in the lowlands and with control of tidal inflow, quicker
run-off through higher reaches may be aimed at without causing floods
in the lowlands.

The difficulties of control of tidal inflow on a navigable river are present
in the problem of the Thames floods below Teddington.

5. THE ROUTINE OF SURFACE WATER MEASUREMENTS (EXCLUDING
RAINFALL).

Section (3) deals with the land survey side of areas, lakes, reservoirs,
waterways, river channels, etc. ‘These may be termed static measurements
and the records of such measurements will lie, firstly, on the 6-in. or other
scale Ordnance maps and, secondly, on such detailed plans and tables, etc.,
as may be necessary.

The routine of water measurements covers the following procedure :—

(a) Observational work on water levels.

(b) Checking and filing of observational work.
(c) Compiling the records on standard lines.
(d) Analysis and publication.

The measurement of river flow at gauging sites does not come under
this routine work (see Memorandum F). The table of flows resulting
from this measurement is used for the conversion of water levels into
flows, at stages (b) or (c) of the above routine.

It is, however, quite likely that at some gauging sites the continuous
measurement of maximum velocity will be additional to the water level
measurements. ‘There is need of a suitable recorder for this purpose.

(a) Observational work: Water levels —Gauge posts read once or twice
daily or occasionally.

Automatic water level gauges. Charts changed weekly. Clock winding.
Checking of graphs with gauge post readings.

Returns to filing office with any comments.

INLAND WATER SURVEY 389

Arrangements have to be made, in some cases, for payment to observers,
for local repairs and maintenance, and for some system of supervision.

Storage and flow controls.—At locks, weirs, etc., on canals and rivers and
reservoirs the openings of sluices and gates, etc., and times thereof, have
to be recorded, in addition to water levels.

(6) Checking and filing at the filing office-——When the observers’ returns
come in, there is considerable routine work necessary in suitable tabulation
of readings and in the completion of graphs with the necessary gauge post
checks, etc. ‘There will also be conversion of water levels into flows and
the compiling of records from all the returns.

(c) Forms of records——The main record will be a table of water levels
and flows; and, generally speaking, it will be necessary to tabulate the
water level and flow for each three hours of the day and to average these
flows for the day.

During principal floods, on the smaller areas, a second table will be
required, dealing with half-hour periods, the values for each half-hour
being averaged before filling in the 3-hourly values on the principal table.

Total flows will be arrived at between one low water and the next low
water, and these will be amended by any changes in reservoir storage and
by values of remaining flow down to a standard low water; these latter
values will emerge from the records in the course of a few years.

In some cases a diagram of water levels may be a convenient form of
continuous record.

(d) Analysis and publication : Analysis of records (Summary) :

(i) Dry weather fall of a river, residual flow after cessation of rain
and temporary storage on area. Estimates of low flow for
extended droughts.

(ii) Concentration times, rates of rise and fall, peak intensities and
duration of floods.

(iii) Aggregate flows of long periods. Impounded storage and over-
flow of reservoirs.

(iv) Relation of flow to rainfall during flood periods and analysis of
losses.

(v) Comparison of gaugings at various points on a river and on
similar rivers.

(vi)) Frequencies of flow magnitudes.

Publication Generally, the publication of records is in the form of an
abbreviation of the full records kept.

A usual publication is a graph for the year, giving the day-to-day flow
above a horizontal time scale.

Another form of publication is that of the daily frequencies of flow
magnitudes for each month or year.

A more complete form of publication, amenable to analysis, would give
the aggregate flow from some selected date and the residual flow and amounts
of impounded storage at low-water levels.

6. APPLICATION OF ROUTINE TO THE VARIOUS WATER INTERESTS.

One requires to visualise this routine work in action with the present-day
organisations.

In what follows I am trying to visualise, in my own way, those little
modifications and additions to existing measurements and records which
will change the individual work of the several water interests into something
which will embrace the whole survey of surface water in its passage to the

390 REPORTS ON THE STATE, OF SCIENCE, ETC.

sea. It does not pretend to cover all points. It is intended to show that
the quiet improvement, step by step, of our recording systems comes first,
with only the helpful guidance of an. advisory organisation such as might
be developed out of the beginnings of my ‘ River Flow Records” if it were
strengthened by a small Council or by formation of an Association to deal
only with surface water.

Fishery Boards—Fishermen on all our lakes and rivers have their gauge
posts and sometimes recorder instruments ; and observers are available.
It is only necessary to arrange for the data to come into a local office for
checking and tabulating. One would like to see, eventually, the preparation
of monthly diagrams of water levels. Fishery Boards could often organise
this basic work of water levels on our rivers.

Boating Associations—The statement sent to the Committee by the
Motor Boat Association is another indication of what may be done on the
observational side, and here it would seem that the records should go’ to
the Catchment Board offices.

This statement is long, and is very briefly summarised in Appendix D (2) (f).
It has been compiled with much care, and there is no doubt that these
associations are able to carry through very good work, as is exemplified by
the charts of small harbours produced by the Cruising Association.

The Motor Boat Association might be a very useful body to assist in
connection with records.

Riverside towns and villages —Here again there should be no difficulty
with the observational side. Supervision may be very necessary, as such
centres often view this type of thing from a popular aspect.

Private estates—There are often good opportunities for observational
work on private estates ; and experience shows that the best observers are
those with a routine job throughout the year.

Water Supply Catchment Areas.—These areas are suitable for complete
measurements and records, but the design of works and the control of
flow and the diversion of water from natural catchments complicate the
problem, and records of total flow are not often maintained.

The changes in incidence of flow, due to impounding, etc., do not in
any way falsify the records of aggregate flow ; and analysis of the records
will give natural flow figures when required. In order that records of
value may be obtained from these areas, the lay-out of the works should
be designed for complete measurement, and the keeping up of records
afterwards should be no side issue.

Eventually, it is likely that systematic arrangements for measurement
of total flow will amend, with advantage, present-day measurements of
water authorities.

The observational work covers rainfall, storage and flow. The checking
and filing would fall to the authority’s office; where also the presentation
of records in suitable form would be dealt with and certain investigation
would be carried out. Even some additional filing and recording of
neighbouring stream or river sites might become attached to these centres.
They would form the proper centre for dealing with the upland records of
river catchments. Supervision and: direction of these records should be
under some superintendent of a central water survey authority.

- Water Power Authorities —On the observational side, these are in similar
case to water supply areas, and they should not be inferior in the routine
work of records; but here again, when the works are finished, routine
measurements should be properly maintained although they may not be a
commercial necessity.

:
|

INLAND WATER SURVEY 391

Canals and waterways and locked rivers.—Lock-keepers are naturally
the observers, and the canal engineer’s office is obviously the place for
checking and filing of the observational. records. Final tables of flow
should be prepared in somewhat similar manner to those of the rivers.
If the routine were once established, the somewhat complicated details
would soon be collected into suitable form. Without more investigation
into canal work I am not prepared to suggest any special form of record.
It is, however, important to realise that the lock of a canal or river is an
accurate measurement tank which will give valuable information of the
actual flow through sluices as efficiently as the tank below the Assuan Dam.

The other record work which falls within the scope of canal measurements
is the keeping of neighbouring water level records and sometimes flows
on the rivers and streams used or affected by canal water supplies.

Electrical Power Stations and other abstractors of river water.—At
present these stations appear to be only concerned with low flows, whereas
they will be, in the future, dependent for their supply on natural or artificial
storage somewhere on the river system. It is rather insufficient that they
should only make a few low flow measurements of their own: they should
be responsible for the water level records at all stages of flow, and their
records should go to the Catchment Boards. The measurements of river
flow should be supplied to them by the river authority, and their own
flow measurements should be only those of the water abstracted from
the river.

Other users of water would likewise be responsible for maintaining
continuous water level records under the direction of the Catchment
Boards. The Catchment Boards should supply them with necessary
flow values, and they should supply the Catchment Boards with continuous
water level records and with the figures of their own supply or diversion
of water.

Catchment, Conservancy and River Boards —There might be a Committee
of a few of these catchment board engineers to outline briefly how their
measurements and records may be developed on lines which will make
their offices the central record office for the water survey and records of
their respective river basins. If these boards do not make the whole river
survey a matter of first importance, there is the real danger that their
measurements and records, like those of other bodies, will be developed
only for the solution of their own urgent problems of drainage and pollution.

SuB-MeEmoranpum D (1).

WATER SUPPLY AUTHORITIES.

NOTES ON THE PRESENT POSITION WITH REGARD TO PUBLIC
WATER SUPPLIES IN ENGLAND AND WALES.

By F. O. STanrorp.

PREFACE.

The provision of a supply of pure and wholesome water for public
purposes has by its very nature a prior claim on the water resources of
the country, and the following notes are intended to indicate, though very
roughly, the manner and extent to which this claim is exercised.

The Ministry of Health, as the predominant authority (under Parliament)
in this respect, has compiled a large amount of data and statistics on the

392 REPORTS ON THE STATE OF SCIENCE, ETC.

subject, latterly with the voluntary co-operation of the British Waterworks
Association ; and through the Advisory Committee on Water has conducted
investigations of special branches of the subject.

To this extent the original demand of the Select. Committee in 1910,
referred to below, for reliable information has been met.

As regards the essential subjects of topography, geology and rainfall; the
Government has provided a special department for each, and the Ministry
has the benefit of their assistance and advice when required.

All recent consideration of the subject, however, points to the fact that
the available data are deficient in two important respects, which are becoming
increasingly urgent: viz. reliable information as to the volume of water
obtainable and available for public supplies in different areas—(a) from under-
ground sources, and (d) from surface sources. As the former become used
up or diminish, increasing reliance must be placed on the latter.

DEMAND FOR A WATER SURVEY.

Demands for a comprehensive inland water survey have been made so
frequently that it is hardly necessary to recapitulate them, but one
authoritative statement on the subject may be quoted as a starting-point.
A Joint Select Committee of both Houses of Parliament appointed to
consider the Water Supplies Protection Bill, 1910, stated, inter alia, that
“in view of the lack of reliable information as to water supply, especially
from underground sources, and the manner in which local supplies were
utilised, there was urgent need for a comprehensive survey of the water
supply of the country and for the adoption of measures to conserve and
dispose of water to the best advantage.’

As the result of the Committee’s report, no further action was taken on the
Bill, but later in the same year a return as to water undertakings in England
and Wales was ordered by Parliament.

RETURN AS TO WATER UNDERTAKINGS, 1914.

This return was compiled by the Local Government Board, as the result
of over 3,000 schedules sent out during 1911-13, and the information was
for the most part correct up to January 1914. Amongst the particulars
which could not be checked, however, are ‘ the quantity of water derived
from each source and the additional amounts obtainable.’

With this return the Local Government Board issued a Preliminary
Memorandum, from which these notes are largely derived.

In this return the undertakings are arranged in five sections, and the
numbers of undertakings were as follows :—

: » Oe : No. of
Section. Description of Undertaking. Undertalivigs:
ik Separate Local Authorities . 786
II. Joint Boards and Joint Committees of Local 34. and

Authorities J | M.W. Bd.
III. Companies with Statutory Powers “ ‘ 200
IV. Companies without Statutory Powers . . 84
Vv. Private Proprietors . y ; 3 é 1,055

INLAND WATER SURVEY 393

This return is now nearly twenty years old. For the provision of reliable
and up-to-date statistics arrangements exist between the Ministry of
Health and the British Waterworks Association, under which the Associa-
tion now collect and publish statistical information. The third edition of
the British Water Works Year Book and Directory contains a large amount
of useful information respecting 871 undertakings, including Ireland.

Since 1914 very extensive developments of waterworks have taken place
throughout the country, and are constantly taking place, but though some
new undertakings have been established, these developments are chiefly in
the nature of extensions of existing undertakings, and the above figures
sufficiently indicate the magnitude of the subject.

The 1914 Memorandum states that ‘ out of 12,869 parishes in rural
districts, 4,874 had a piped supply to some at least of their houses.’ This
number has since been very largely increased, especially by comprehensive
schemes for groups of parishes ; but much yet remains to be done to keep
pace with the increased demand consequent upon improved standards of
sanitation, such as W.C.’s, baths and hot and cold water supplies laid on to
houses, which have greatly increased the consumption per head throughout
the country.

The same memorandum states : ‘ the Return may be regarded as the first
instalment of the detailed and comprehensive investigation of the whole
_ subject of surface and underground water supplies which has been recom-
mended by various Royal Commissions and Committees.’

MINIstry OF HEALTH WATER SURVEY AND ADVISORY COMMITTEE.

The outbreak of the war shortly after the publication of the 1914 Return
put a stop to further investigation for the time being.

Following the First Report of the Board of Trade Water Power Resources
Committee, published in 1921, the Ministry of Health established a Water
Survey for the compilation of data relating to water undertakings in greater
detail than in the 1914 Return, including gaugings of springs where avail-
able. This, though of great use in the department, is of limited scope and
confined to data obtainable from the respective undertakings, no special
staff being available for making special investigations. ‘The survey is not
available in any published form.

The Minister also appointed an Advisory Committee on Water who have
published a number of Reports, including :—

(a) On Measures for the Protection of Underground Water (1925).
(6) Report of Legislation Sub-committee (1929).

(c) On Rural Water Supplies (1929).

(d) On the Assessment of Compensation Water.

The Committee, in 1930, appointed a Sub-committee on the subject of
river gauging ; the work of this Sub-committee is, however, at present in
abeyance owing to the urgent need for national economy.

The subject of underground water, on which the Select Committee of
1910 laid emphasis, is dealt with in a separate memorandum, by Dr. Bernard
Smith, and it is only necessary here to mention the chief points referred to
in the above Report (a), viz. the interference with underground water
caused by mining operations and pumping; the waste of water arising
from such pumping and from overflowing boreholes ; and the need for the
protection of underground water from contamination.

As regards legislation, the chief point affecting a water supply is probably
that relating to the powers of a local authority operating under the Public

P

394 REPORTS ON’ THE STATE OF SCIENCE, ETC.

Health Acts to acquire water rights and abstract water. The powers are
thus stated in the 1914 Memorandum previously referred to :—

‘Common Law. . In England and Wales under the common law every.
landowner has the right to use water flowing in known or defined channels,
i.e., the water naturally flowing through, past or under his land, both for his
domestic use and for his cattle, without regard to the effect of such use
upon the! landowners lower down the stream. Further, he has the right to
use the water for any purpose, provided there is no interference with the
rights of other landowners either above or below. He cannot however
lawfully abstract from any stream water for sale or for the supply of the
inhabitants of any neighbouring area... As regards underground water not
flowing in defined channels, every landowner has the exclusive right to all
water obtainable from his land.’

Consequently, local authorities who desire to use surface water as a
source of public supply must in general, with few exceptions, obtain
authority by special Act:of Parliament. Any alteration of the general law
which would simplify the procedure, e.g. by enabling the necessary powers
to be given by Order instead of by Act (as recommended by the Select
Committee in 1910 and proposed in a Bill introduced by the Government
in 1911-12, which, however, did not proceed), would doubtless lead to some
considerable increase in the use of such sources, and the necessity for
gauging streams and the run-off from gathering grounds would become of
the first importance in this connection.

As regards the assessment of compensation water, the Report (d)
mentioned above recommends certain alterations in the present method,
including—

‘ Stream gaugings should be used for the determination of the losses due
to evaporation and absorption.

‘ Stream gaugings should also be used to measure and allow for the
variability of flow.’

The Report (p.'11) mentions only ten different eatchmierit areas for which
continuous stream gaugings were available, and of these four cases were
selected for detail analyses on which the conclusions were based. Ina paper
on this subject read before the British Water-Works Association in 1929,
Mr. Fawcett (then Chief Engineering Inspector, Ministry of Health) pointed
out that ‘ with some exceptions very little reliable data exists of the flow of
rivers as ascertained by actual gaugings, and the Sub-Committee have felt
acutely during their investigations the necessity for more records of river
flows.

Mr. Fawcett continues : ‘ As regards the various purposes for which river
gaugings are desirable, it is only necessary to mention (1) water supply,
(2) industry and power, (3) flooding, etc., (4) dilution, (5) navigation. There
cannot be any doubt but that water supplies take the first place as regards
importance of river gaugings.’

RESERVOIRS (SAFETY PROVISIONS) ACT, 1930.

The passing of this Act, which follows the recommendation ofa Select
Committee as far back as 1865, has brought into prominence the necessity
for reliable and continuous record of the flow from upland gathering grounds,
in order to furnish actual figures of the intensities of floods which require
to be discharged by overflow weirs and channels, in preference to placing
reliance on formulz and estimations based upon rainfall for this purpose.

This subject is now under the consideration of a Committee of the
Institution:of Civil Engineers, whose preliminary report, it is understood,

INLAND WATER SURVEY 395

recommends that suitable recording gauges should be set up for this purpose
on rivers, lakes and reservoirs.

As a consequence of this Act and stimulated by the findings of this
Committee, it may be anticipated that this branch of water engineering will
receive increased attention in the future on those undertakings which possess
large storage reservoirs for upland water.

SouRCES OF SUPPLY.

Referring again to the Local Government Board Memorandum, 1914,
and classifying lakes, ponds, rivers and streams as surface supplies, and wells
and springs as underground supplies, the principal sources at that date
were :—

Lakes:—Thirlmere, Crummock, Hayeswater and Ennerdale.

Rivers and streams.—One hundred and thirty-nine undertakings use these
as sources of supply, some of the most important of which are river Thames
and its tributaries Lee and Kennet; river Severn and tributaries Avon,
Chelt, Wye and Elan ; river Derwent ; river Tees and tributary Balder.

Upland surfaces.—In some cases it is not possible to differentiate between
supplies derived from upland surfaces and from rivers, streams, lakes and
springs, but approximately 167 undertakings depend upon gathering grounds
for the whole or part of their supplies.

Special Acts authorising the abstraction of water from upland surfaces
invariably contain provision for compensation either in money or generally
in compensation water.

Springs —The actual number of springs from which supplies are obtained
is not known, but it appears that springs are among the sources of supply of
520 undertakings.

Underground sources, excluding springs, comprise wells, borings, adits
and headings, etc. These furnish supplies to 495 undertakings.

For some years the supply from underground waters has been increasing,
and the proportion of underground to surface waters used has been con-
stantly growing. At that date the amount of underground water supplied
was put down very roughly as 285 million gallons a day, and particulars are
given showing roughly the amount derived from each geological formation.

In this connection it is pointed out that surface water is generally filtered,
whereas underground water, including that from springs, as a rule is not.

REGIONAL WATER COMMITTEES.

_ In 1928 the Ministry issued a booklet (approved by the Advisory Com-
mittee on Water) recommending the formation of regional water committees
in districts where anumber of undertakers are concerned in the same general
sources of supply, and where a common water policy is much to be desired.

Several such committees have been formed, e.g. the Sherwood Area
Regional Advisory Committee (mentioned in the Ministry of Health Annual

ort, 1931-32), comprising twenty-four local authorities whose supplies are
derived from the Bunter sandstone beds.

In this booklet the Ministry points out, with regard to surface supplies,
for -which in few instances are accurate records available :—

‘It is often necessary to become committed to a source of supply on such
information as is available before accurate records can be obtained, but the
earliest opportunity should be taken to instal proper gauges.

. ‘The collection of reliable data by the Committee will represent a valuable
' part of their work.’

396 REPORTS ON THE STATE OF SCIENCE, ETC.

CONCLUSION.

From the foregoing notes it will be seen that the demand for records of
underground water and river gaugings is general and persistent for purposes
of water supply. The onus of providing these data must in the first place
fall upon the water authorities for whose benefit they are primarily required,
as, for instance, in the matter of compensation water, and whose works
create the liabilities such as have given rise to the Reservoirs (Safety
Provisions) Act. Further, it is on their property that the observations must
be made, and their staff are on the spot to make the records. Water
authorities, however, with few exceptions, have proved slow to realise that
the slight expense involved would be for the advantage of their individual
undertakings, as well as contributing to the wider knowledge essential for
such bodies as regional water committees, and contributing also to the
science of water engineering on which all such undertakings intimately
depend.

It is highly desirable, therefore, that convincing efforts should be made
to enlist the co-operation of the water authorities.

When this is secured, water engineers should have no difficulty in estab-
lishing some appropriate body of experts to give any advice that may be
desired as to the methods of observing and recording, and to compile the
results and draw conclusions of value to all concerned.

APPENDIX D (1) (a).

RECORDS OF WATER SUPPLY AUTHORITIES
(GRAVITATION SUPPLIES).

By C. CLEMESHA SMITH.

It is probable that many of the stream-flow records, etc., kept by water
supply authorities are not in a form which would be serviceable to others
than themselves.

The regulating effects of impounding reservoirs, the existence of catch-
waters, tunnels, and conduits which convey the whole or a portion of the
yield of one catchment area to another, the delivery of compensation water
either intermittently or continuously, the drawing at irregular rates of supply,
all render it necessary that adjustments should be made if the yield of a given
catchment area is to be arrived at.

The records may be used in two distinct ways :—

(a) To show the actual yield of the catchment area in such a form that
it may be compared with the rainfall for stated periods, and, by subtraction,
show the losses by evaporation and absorption.

(6) The quantity which passes down the stream as compensation water
and as unstored flood water.

Water undertakings reasonably organised should generally be able to
furnish the following data in respect of their catchment area :—

Rainfall—The average rainfall over the area for each year, for each
month, and for specific dry or wet periods. (Note.—Automatic recording
gauges are fixed on a few catchment areas. An extension of their use is
desirable.)

INLAND WATER SURVEY 397

Run-off.—
(a) (i) The total run-off from the area.
(ii) The monthly run-off from the area.
(iii) The total run-off for specific dry or wet periods.
(iv) Daily and weekly run-off could be obtained from the records when
necessary.

As regards peak rates of flow, these can in most cases only be ascertained
approximately, few reservoirs having instruments recording the rise and
fall of water level throughout the entire depth.

(6) (i) The annual run-off (overflow water and compensation) passing
into the stream below the lowest reservoir.
(ii) The monthly run-off (overflow water and compensation) passing
into the stream below the lowest reservoir.
(iii) The run-off for specific dry or wet periods.
(iv) Daily and weekly figures of a similar nature could be furnished
when necessary.

Most undertakings reasonably organised aim at statistics in respect of
(a) (i), (ii) and (iii), and could furnish also (8) (i), (ii) and (iii).

It would not serve any immediately useful purpose to work out (a) (iv)
and (8) (iv) for the whole year. In most cases the adjustments are laborious
and would only be undertaken where the results would be valuable.

It is very desirable that peak rates of flow should be ascertained in the
cases of the maximum floods in each year, and undertakings should provide
the necessary recording instruments.

SuB-MEmMoRANDuM D (2).

CATCHMENT BOARDS.
By J. C. A. ROSEVEARE,

The forty-six Catchment Boards set up by the Ministry of Agriculture
and Fisheries, under the Land Drainage Act, 1930, have jurisdiction over
39,000 square miles, which is 67 per cent. of the area of England and Wales.
Many of these statutory areas consist of a number of separate river-basins
amalgamated for convenience in administration.

It is unfortunate for the purpose of water survey that these authorities
do not cover the whole of England and Wales, but the Minister has power
to set up additional Catchment Boards if necessary. The boards are
representative of all the interests in the catchment areas, two-thirds of the
members being nominated by county councils and county borough councils,
and one-third representing lowland areas in the catchment area.

It will be admitted that a catchment basin is the proper unit for water
survey as regards rainfall and river flow, but this is not entirely so when
considering underground water, which may, in special cases, travel from
one catchment basin to another.

In order to design works in the most economical way, Catchment Boards
should know the maximum and minimum flows in their rivers, and should
keep continuous records of the rainfall and the flow resulting therefrom.

It is suggested that these Catchment Boards should undertake the water
survey of their respective areas. From information received from a few
Catchment Boards, it appears that some are already taking steps to this end.

398 REPORTS ON THE STATE OF SCIENCE, ETC.

APPENDIX D (2) (a).
Paper BY J. C. A. ROSEVEARE.

On ‘ LAND DRAINAGE IN ENGLAND AND WALES,’ PRESENTED TO THE
INSTITUTION OF WATER ENGINEERS, AT THEIR WINTER MEETING, ON
DECEMBER 2, 1932.

The paper, and the discussion which followed, appeared in the winter
number of Water and Water Engineering.

The paper describes the formation and constitution of the forty-six
Catchment Boards under the Land Drainage Act of 1930, and gives
information as to the areas, length of ‘ main river,’ rateable value and
other details of the catchment areas.

. The paper and the discussion both indicate the lack of information as to
river flows, the crudeness of the estimates of flood flows, and the need for
accurate gauging.

APPENDIX D (2) (8).

THAMES CONSERVANCY.
(REPLY TO QUESTIONNAIRE.)
By G. J. GRIFFITHS.

(1) The gaugings of the river Thames are made at Teddington Weir,
which is at the seaward end of the Conservators’ jurisdiction. The river
below Teddington Weir is tidal. ‘The measurements are made of the water
passing over gauge crests and weir overfalls and through sluice openings.

The water levels are recorded by continuous clock recorders at points
some little distance upstream and down-stream of the weir.

The formule from which the calculations are made were evolved some
fifty years ago, and though they are not entirely in accordance with modern
formule, they are retained in order that the results may be kept comparative
with those of the past. The estimated flow has been checked from time
to time by current meter observations at various magnitudes of discharge,
and, on the whole, close agreement has been found between the calculated
gaugings and the current meter observations. :

(The formule employed are given in the original statement.)

Current meter observations are taken at times for the purpose of ascertain-
ing the flow at certain other parts of the river or of tributaries, particularly
in periods of drought.

See Appendix F (5).

(2) Part of Teddington Weir is normal to the direction of the stream, and
part is at an angle thereto. sea

The tail-water side being tidal, there is a considerable variation in the
‘fall’ from head to tail at the weir during the day. This differs from
about 3 in. to some ro ft. in periods of low flow, and from about 1 ft. 3 in.
to 2 ft. in times of high flood.

The range of water levels at which flows have been calculated extend
over some 6 ft. or 7 ft. on the headwater side of Teddington Weir, or over
a range of 16:5 ft. on the tail-water side, the flows ranging from 33 cub. ft.
to 37,000 cub. ft. per second.

At some other weirs upstream of Teddington the range is from ro ft. to

INLAND WATER SURVEY 399

14 ft: on the tail-water scale, but none of these represent the full ‘ natural ’
range between minimum and maximum flow, owing to the influence of the
weir next down-stream, in artificially holding up the level in times of low flow.
This feature renders a scale of flows for varying water levels very insensitive
for low readings, but use is made of such station gauges for obtaining
approximate estimates of flow when required. Water is ‘ drawn off’ or
abstracted from the Thames: in very large quantities by the Metropolitan
Water Board and other water companies. The quantities so abstracted
are measured and calculated for each day and are added to the volume
gauged at Teddington, the sum being then described as the ‘ natural flow ’
of the river.

With such numerous and varied methods of abstraction as are employed
it will be obvious that the measurements and calculations of the quantities
are somewhat complicated, and they are made in very considerable detail
to ensure accuracy.

(3) Each lock (there are forty-six lock sites) is provided with a scale gauge
at'the head- and tail-water sides, and ‘these are read and recorded at every
gauge four times in the twenty-four hours. This is in addition to the
automatic recorders at Teddington, and at certain other weirs.

There are at present no station gauges or automatic recorders on any of
the tributaries, but at certain critical times (periods of very low flow)
gaugings have been made of the tributaries.

(4) It may be mentioned that daily records of rainfall are taken at some
seventeen stations distributed over the Thames Valley, and that daily
rainfall averages, together with the records of, natural and gauged flow, are
printed monthly, and are available to the public at a charge of 1s. per
monthly sheet.

Surveys of main tributary streams.are in progress, and information
respecting the rainfall, maximum and minimum flows of these will be
obtained in due course.

It is in view for the future to establish a gauging station on each tributary
from which daily estimates of the flow may be obtained, but for similar
reasons to those mentioned in regard to the main river, there are features
which render this a proceeding of considerable difficulty, and it is doubtful
if the value of the results would at present justify the cost of obtaining them.

APPENDIX D (2) (c).

RIVER TRENT CATCHMENT BOARD.
(REPLY TO QUESTIONNAIRE.)
By W. H. Haltte.

1. Methods of river gauging at principal site or sites—The weirs across
the ‘ main river’ generally are of an antiquated character and are unreliable
for computing river discharges.

The more modern weirs are usually for the purpose of maintaining head-
water for turbines. Part of the river flows over the weir, the remainder
passing through the mill ; thus the weir discharge is not the correct river
discharge.

Up to date it has only been possible to take current meter observations
for special Parliamentary litigation purposes. A start, however, has been
made to take regular current meter readings in the river Trent, at all river
levels, to obtain a rating curve of discharge. The site of the observations

400 REPORTS ON THE STATE OF SCIENCE, ETC,

is just above Beeston Weir, near Nottingham, above which all the main
tributaries join the river.

Head- and tail-water levels of the eight main weirs across the Trent are
taken three times daily by the Trent Navigation Company. The informa-
tion is at our disposal at any time.

2. Method of computing flows.—At the site the Trent is 280 ft. wide.
An accurate cross-section has been taken, subdivided into 20-ft. vertical
strips, fourteen subdivisions in all. At the centre of each subdivision,
velocity readings are taken vertically, approximately at 18-in. intervals.
The mean velocity is computed from the plotted velocity curve for each
subdivision, the total discharge being the sum of (area X mean velocity)
for the fourteen subdivisions.

This series of observations is to be taken at all water levels to obtain a
rating curve to cover all stages from low summer level to flood level.

Knowing the head over the weir crest for each calculated discharge,
constants for the weir discharge can be obtained.

The instrument used is Troughton & Simms’ ‘ Improved Current
Meter.’

3. Keeping of water level records (near gauging site).—It is intended
eventually to establish rating curves for the principal tributaries near their
junctions with the Trent. On computing the rating curves, automatic
recording instruments to give discharge of river at any water level will be
installed at the various gauging sites.

APPENDIX D (2) (d).

GREAT OUSE CATCHMENT BOARD.
(REPLY TO QUESTIONNAIRE.)
By O. Borer.

1. River flow gaugings—I have found no record of past -discharge
observations. The only discharge observations made by me were at
Bottisham Lock, and for the lock gate sluices I used the formula

Q = -62A V2gh (Love’s Hydraulics).
and for the drowned weir—
Q=L [3-1 {@ +h) A) + 6-4ah +2]
(Love’s Hydraulics).

I have not yet taken any river discharge observations, but we shall do so
in the Marsh Cut, where we are having a gauging site arranged.

The site selected has a straight uniform reach of 14 miles in length, and
we are fixing gauges at each end and in the centre. We shall read the
surface slope from the gauges and take direct discharge observations at the
centre by—

(a) Surface floats, using the formula

V=

PN ER where V_ = the mean velocity,
V, = the maximum surface velocity,
and C is Bazin’s coefficient for the H.M.D.

(6) By means of velocity rods, floating vertically in the stream and so
giving the mean velocity in the vertical plane.

INLAND WATER SURVEY 401

From the discharges so observed and the recorded surface slopes the
correct value of N in Kutter’s formula will be ascertained for this particular
reach of river, and subsequent discharges will be calculated from the surface
slopes as observed on these gauges.

The cross-section of the river at the centre gauge (which at this site is
fairly stable) will be periodically checked to correct error due to any change
in this.

2. Current meter measurements by velocity meter are being taken when
observing discharges in rivers and drains.

3. Water level records near flow gauging sites—No record by continuous
recorders, but a record of gauges at important points read daily or twice
daily has been kept for many years.

4. Water level records at other sites.—There are no recording gauges yet
fixed, but eight recording gauges have been prepared and will be fixed
within the next few months,

APPENDIX D (2) (e).

WEST RIDING OF YORKSHIRE RIVERS BOARD.
(REPLY TO QUESTIONNAIRE.)
By J. H. GARNER.

When my Chairman and myself met you in London last November
I think we explained the steps which the West Riding Rivers Board have
so far taken in regard to river flow gauging. You will find some particulars
of our work in the special report on River Don Gauging and in the copies
of the Annual Reports.

Up to the present three Lea Recorders have been fixed as follows:
No. 1, river Don at Hadfields’ Weir, Sheffield (this gauge is now owned
by the Sheffield Corporation and supervised’by the manager of the Sheffield
sewage works); No. 2, river Calder at Kirkthorpe Weir, Wakefield ;
No. 3, river Aire at Beal Weir, near Knottingley. These recorders give a
continuous record of rate of flow and level of water.

Gaugings have also been made on the river Rother at Canklow, and
river Dearne at Hoyle Mill, Barnsley. In these cases the gaugings were
made over a reach of each river by taking the widths and areas of sections
at different water levels and ascertaining velocities by floats.

It will interest you to know that I am in negotiation with the engineer of
the river Ouse (Yorks) Catchment Board with the object of establishing
co-operation in regard to river flow gauging between the Catchment Board
and the Rivers Board.

My Committee has authorised the expenditure of £100 for the purchase
of another Lea Recorder. This will be fixed to work with a suitable weir
on another river in the West Riding where no gaugings have hitherto been
continuously made.

In the West Riding most of the rivers have been industrialised and there
are many weirs, a good many of which the Catchment Board will no doubt
be able to put into satisfactory condition for use with automatic flow
recorders of the Lea type.

So far as the Rivers Board are concerned, the use of suitable weirs would
appear to be the only direction in which gaugings can be made, as the Board
have no staff which could be spared to devote the necessary time to making
gaugings by any other means.

P2

402 REPORTS ON. THE STATE OF SCIENCE, ETC.

AppENDIX D (2) (f).

THE MOTOR BOAT ASSOCIATION
(83, Patt. Matt, Lonpon, S.W. 1).

ABSTRACT FROM A MEMORANDUM ON INLAND WATER SURVEY.

1. INTRODUCTION.

The Motor Boat Association’ appreciates the request of the British
Association Committee to put forward views in connection ‘with «the
organisation of water level survey records on rivers and lakes.

The M.B.A. is representative of owners of motor boats used solely for |
pleasure purposes. Its membership embraces owners in every part of the
British Isles as well as owners on the Continent.

The Association understands that the terms of reference to the Committee
are ‘ To inquire into the position of Inland Water Survey in the British
Isles, and the possible organisation and control of such a survey by central
authority.’

Whilst the Association not unnaturally visualises the benefit of such a
survey from the point of view of navigation of such waterways, it is also not
unaware of the extension of the benefits to such interests as power houses,
fisheries, drainage, etc.

It is aware of the immense bearing which a comprehensive survey and
official and regular collation of results must also have on the important
subjects of industry and research. The latent power inherent in many of
the inland waterways of the country can only be effectively harnessed and
adapted to the best possible service of industry if those responsible for
commercial undertakings can have recourse to some central body from
whom they can secure up-to-date and comprehensive information as to the
potentialities of waterways in areas in which they may be considering
erecting factories, power houses} etc.

On the aspect of research little need be said. Thei importanca, of continued
study into the inland waterways, conducted over a regular and duly notated
period of time, will be apparent. There is opened up, by a comprehensive
survey, a vast field for useful research into the changing conditions and
influences of the inland waterways of the country.

Therefore, in putting forward suggestions as to the organisation for dealing
with such a survey, the Association does so bearing all such interests in mind.

2. NEED FOR COMPREHENSIVE SURVEY

3. WATERWAYS TO BE SURVEYED

4. RECORDING STATIONS (not abstracted).
5. RECORDING INSTRUMENT

6. RECORDING AUTHORITY

7. THE M.B.A. AS THE RECORDING AUTHORITY.

. . . the further point emerges that the Association has at the moment
the nucleus of the organisation required for the regular and systematic
collection and tabulation of water level data. In its service arrangements
it has, at many centres, its own official boatmen and honorary local

representatives.
8. THE STRUCTURE OF THE CENTRAL AUTHORITY (not abstracted).

INLAND WATER SURVEY 403

9. CONDITIONS AS TO APPOINTMENTS.

There are, of course, various other directions from which the data can
be collected, and the machinery in this connection may be summarised as
(i) Officials of catchment boards and waterway authorities.
(ii) M.B.A. and other boatmen.
(iii) Angling clubs.
(iv) Rowing and motor boat clubs.
(v) Specially engaged surveyors.

10. FINANCE (not abstracted).

11. AVAILABILITY OF DATA.

- The Area Superintendents would be expected to have available, and in
their custody, the data from time to time forthcoming as the result of the
surveys, while tabulated information from the whole of the country would
be maintained at and available from the headquarters of the central
authority in London.

12. CONCLUSION.

It is appreciated that the scheme as put forward by the M.B.A. is but
in the nature of skeleton framework upon the broad conception of which
much consideration of detail requires to be given if the proposal so suggested
commends itself as worthy of further exploration.

The Grand Council of the M.B.A. would desire to assure the Committee
of the British Association of its entire sympathy with the objects which its
inquiry is designed to achieve, and in acceding to the request of the British
Association to put forward its views the M.B.A. does so in the earnest desire
to provide a constructive contribution to the question under consideration.

While it feels that it can, if thought fit, readily adapt within its present
constitution the machinery necessary to enable it to undertake the important
functions of a central authority such as is envisaged, it would equally
emphasise the fact that, were it so desired, it would be ready to co-operate
fully in the information and working of a separate central authority, to
afford to such authority every assistance in its power, and to accord to it the
hospitality of its office and organisation, and, in short, to do everything in
its power to collaborate in the important work of inland water survey which
it realises must, sooner or later, be adequately dealt with.

In conclusion, the M.B.A. would again express its appreciation for the
opportunity of expressing its views, accorded to it by the courtesy of the
British Association.

(Signed) C. Horton,
Secretary, Motor Boat Association.

SuB-MEmMorRANDuUM D (3).

WATER RECORDS KEPT BY HYDRO-ELECTRIC
COMPANIES.

By W. T. Hatcrow.

1. In the absence of records of river flow, all large hydro-electric schemes
in Great Britain have been designed on an estimated yield of water from the
catchment areas, based on rainfall records. Many millions of pounds
have been spent on these undertakings, and it would have been of great
assistance. had long-period records of river flow been available for the
engineers. Under present conditions there is an element of uncertainty in de-
termining the economic capacity of such unalterable works as pressure tunnels,

404 REPORTS ON THE STATE OF SCIENCE, ETC.

as experience may show that the yield is either greater or less than has been
anticipated ; if the latter, unnecessary expenditure may have been incurred.

2. The hydro-electric works which have been constructed give an
opportunity of recording the yield from catchment areas, and such informa-
tion is helpful i in dealing with adjacent catchments of similar character.

3. It is customary for the hydro-electric companies to prepare a balance-
sheet of the rainfall and of water utilised and lost. The following informa-
tion is usually recorded :—

(a) Year.

(b) Average rainfall on catchment area in inches.

(c) The level of the water in the main reservoirs on January 1.

(d) The increase or decrease of storage water during the year.

(e) Water lost over the spillway of dams as measured by continuously

recording water level gauge.

(f) Losses from any subsidiary catchments not flowing directly to the

main reservoirs, or water run to waste.

(g) Water utilised for power as measured over weirs or through Venturi

meters.

(h) Total available water.

(2) Total water accounted for.

(j) Loss due to evaporation, absorption, etc., i.e. the difference between

(h) and (2).

By means of these balance-sheets the yield from the catchment area is
obtained, and, by measurement of exceptional increase in the rate of rise of
water in the reservoirs, intensities of inflow owing to flood conditions and
melting snow can be calculated ; should the reservoir be full when such
flood conditions occur the record of the flow over the dam spillway would
also give a measure of the flood conditions.

4. I believe that the hydro-electric companies would be willing to give
information of the yield of catchment areas to a central authority. It is
possible that existing systems of recording data may require modification
to bring them into accord with any recommendations of a central authority.

Sus-MEmoranDvuM D (4).

ELECTRICITY STATIONS.
By Henry Nimmo.

There were 454 stations owned by authorised electricity supply under-
takers in operation at the end of 1932, against 483 in 1931 and 511 in 1930.
With the coming into operation of the grid the decrease will be more rapid
in the next two or three years, until only about 120 selected stations are left
to generate all the electricity required by authorised electricity supply
authorities.

In addition there were, at the end of 1932, 50 (against 55 in the previous
year) stations owned by railway, tramway and certain non-statutory bodies,
and there are still a large number in factories, mines, etc. "The number
of these, however, is expected to decrease rapidly when the full effect of
the grid scheme takes place.

At the end of 1932 there was installed in the stations of authorised under-
takers over 7 million kw. of plant, of which nearly 97 per cent. is steam
driven, the remainder having oil and gas (about 2 per cent.) and over 1 per
cent. water-driven prime movers.

The maximum load on the stations of authorised undertakers was of the
order of 4 million kw., and 12,225 million kilowatt-hours were generated
during the year, the load factor approaching 35 per cent.

INLAND WATER SURVEY 405

In steam-driven stations the water in use in the steam cycle is used over
and over again with an addition of from 2} to 5 per cent. to make up for
leakage and other losses.

The amount of circulating water required varies with the design and
layout of the station. Under existing conditions of load factor, approxi-
mately 60 gallons are required per unit generated, and the total quantity
used by authorised undertakers (including oil- and gas-driven stations,
using about 4:5 gallons per kw. of plant in operation) is equivalent to
something like 300 million gallons (one and one-third million tons) per hour
for 3,060 hours, or a total of over 4,000 million tons in the year. For every
ton of coal consumed in these stations about 500 tons of circulating water
is needed.

In this connection steam-driven generating stations may be classed under
three heads, viz. :—

(1) Those using tidal water, like Battersea and Barking (where 22 million
gallons per hour may ultimately be handled), which are only limited by the
size of the intake tunnels and pumps.

(2). Those using river or canal water ; and

(3) Those with a limited supply from wells or other sources and having
cooling towers so that the circulating water may be used over and over
again. In this case from 3 to 5 per cent. is lost in evaporation.

With a single station ultimately handling up to 22 million gallons per
hour, the provision of an adequate supply of water is of first importance,
and this accounts for the fact that all large new stations are either placed on
a river bank or within reach of tidal water.

In the annual questionnaire sent out by the Electricity Commissioners to
all electricity supply authorities, those with generating stations are requested
to state, under the sub-heading ‘ Condensing Facilities,’ (i) the source of
water supply (stating whether tidal water, non-tidal river, canal, etc.) :—

(a) Minimum dry weather flow in gallons per hour.

(5) Normal usable flow at other times in gallons per hour.

This information, though not complete, is therefore available in respect of a
large number of stations. ‘The flow of many of the rivers has been measured
from time to time, and a list is available giving details of flow in respect of
fifty rivers in England and Wales and the method of gauging at thirty-seven.

Unfortunately, in many cases very rough-and-ready methods have been
employed and some strongly conflicting results obtained. A few have been
measured with some degree of accuracy, but none over any extensive period
of years. While the results on the whole may not be of much value, they
will serve to show what has been done.

One of the most careful and accurate measurements made was on the
Severn at Ironbridge by the West Midlands Joint Electricity Authority,
and details of this survey are given at the end of this memorandum. The
Severn Navigation Board also gauged the Severn at Worcester and could
no doubt supplement the information given here.

Some of the rivers have been gauged at several points—the Irwell, for
example, at five different places—and some others at two or three ; among
the latter the river Aire, which has been gauged at Bradford, Leeds and
Ferrybridge. When the Bradford Corporation Station at Esholt, on the
Aire, was under consideration, the City Electrical Engineer, Mr. Thomas
Roles, had gauging records of the flow taken from 1917 to 1921 (see details
attached). Upstream from the power-station site the river had been
impounded many years ago for supplying water power to a factory, and
the dam wall was adapted by Mr. Roles for the construction of a weir
115 ft. long and 12 in. deep, and a flute chamber some io ft. upstream

406 REPORTS ON THE STATE OF SCIENCE, ETC.

was built in the river bank, into which a seven-day Lea Recorder was
installed to measure the rate of flow. ‘These observations were discontinued
in September 1921, but Mr. Roles thinks this gauging station could be
re-established at a cost of £50 to £100.

In regard to underground water, some information is also available in
respect of wells at various power stations, but no systematic flow measure-
ments appear to have been made.

AppENDIx D (4) (a).

GAUGING OF THE RIVER SEVERN AT IRONBRIDGE
BY THE WEsT MIDLANDS JOINT ELECTRICITY AUTHORITY.
By E. F. HETHERINGTON.

Ironbridge power station has been designed for an ultimate capacity of
200,000 kw., consisting of four 50,000 kw. maximum: continuous-ratéd
machines. When the construction of the station was under consideration
in 1925-26 rough measurements of the river flow were made. In 1927 a
further set of measurements was made, and a third survey was completed
in the summer of 1928 after a long dry spell, when the flow was at its
minimum. The result of these measurements showed that even undér
the extreme conditions prevailing in 1928 there was sufficient water for the
operation of three generating sets at full load, the fourth acting as a standby.

Since that date constant observations have been taken, and a complete
record of the daily river levels from June 1929 to the present day has been
kept and a curve plotted.

The Authority is quite satisfied that during eight or nine months of the
year there is more than sufficient water for the operation of 300,000 or
400,000 kw. of plant, and this being the case they have never troubled
to gauge the river accurately at the higher rates of flow.

The method of gauging adopted was to select a certain stretch of the
river and make an accurate survey of its depth. The particular length
chosen for this purpose had practically the same depth contour throughout,
and this considerably simplified measurements. The floats were designed
and made of a type indicated on a plan which is available, if required.
These floats consist of a kind of boat-shaped raft with a sinker weight, which
could be arranged to hang down into the water at any desired depth, by which
means a more or less mean velocity could be obtained between the surface
of the water and the flow nearest to the river-bed. Levels were very
accurately taken by theodolite, and lines were placed across the stream at
two points, (a) and (b). The floats were timed over the course, and a
velocity table attached indicates the rates of travel down stream. From
time to time intermediate timings were taken, which clearly showed that
the floats traversed the whole length of the course at a constant velocity.
The cross-section of the river (copy available if required) worked’ out at
448 sq. ft., while the mean velocity of flow, as indicated on the table attached,
was found to be 0-849 ft. per second, and taking the number of gallons per
cubic foot as 6°25, the quantity of water was

448 X 0:849 X 6:25 X 3,600 = 8,580,000 gallons per hour.

The Authority has not troubled to take very accurate measurements of
the higher rates of flow, although a number of tests have been made from
time to time, from which it would appear that the normal summer flow of
the river at this point is in the region of 12 million gallons per hour,

(Table of measurements accompanies original statement.)

407

INLAND WATER SURVEY

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408 REPORTS ON THE STATE OF SCIENCE, ETC.

APPENDIX D (4) (c).

TABLE
ACCOMPANYING SuUB-MEMORANDUM D (4).
By H. Nimmo,

The original table gives for each place and authority on fifty rivers :—
(1) Normal summer flow.
(2) Area of gathering ground.
(3) Minimum flow and month of occurrence.
(4) Method of gauging and remarks.

The following abridged table gives the areas and the normal summer
flow and minimum flow in cusecs per thousand acres.

Normal es
P Thousand Minimum
River (and County). Alves! peer ico Method.
ow.
Cusecs | Cusecs
per 1,000 | per 1,000
Acres. Acres.
Aire (Yorks) . ; : — — — Weir
ae Me : 5 , 244 2°9 1°3 Floats
x > f : ; 298 Lg ov! Weir
Avon (Hants) . : : 416 1°5 0°4 Meter
» (Wilts) . ; ; 403 ad 0°2 Weir
Calder (Yorks) ; ; 181 1°8 0°6 Floats
sy : 206 1°4(av.) o0°8 Weir
»> (Lancs) 57 i: 5 o'5 Weir
» (Yorks) ‘ 101 3°8 O°5 Weir
Colne ae - ; 57 1'9 o'7 Weir
Dee (Cheshire) : E 439 2:1 0°6 Weir
Derwent (Derby) . é 270 1°8 0°7 Weir
~ ‘ 300 2°9 I°5 Meter
Don (Yorks) . : ; gI 3°4 1°2 Weir
Eden (Cumbd.) : ; 640 1°3 0'6 —_—
Exe (Devon) . : ; 412 I'l 0°6 Weir
Irwell (Lancs) : ‘ 199 06 o°4 Weir
Nene (Northants) . ci 403 o'5 0°3 Floats
Severn (Worcester) . . | 1,046 o'5 0°3 —
», (Salop) 2 F 704. 0-7 o'5 Floats
Taff (S. Wales) ; : 125 2°2 1°6 Floats
Taf Fechan (Wales) . : 25 2°1 o's —
Tame (Cheshire) . F 22 3°9 2°0 Weir
Thames (Oxford) . : 672 o'8 ovr Floats
Trent (Derby and Staffs) . 704, 1°2 o'2 Weir
Tone (Somerset) . g 83 °'9 o'4 —
Welland (Lincoln) . 5 137 o-2 o'r Floats
Witham s3 - : 38 O°4 o'r Sluice gates

INLAND WATER SURVEY 409

SuB-MEmMorANDUM D (s).

CANALS.
By T. SHrRLEY HAWKINS.

1. Inconsidering what water measurements it may be desirable to take in
the case of canal authorities it would first be as well to set out what different
forms the canals may take, i.e.

(i) The artificially cut canal ;

(ii) the combination of artificially cut canal and the canalised river ;

(iii) the canalised river ;
and with these large differences in type it will be seen that the number
and character of the measurements required would vary for each of the
three types.

2. There are, however, four common purposes for which all three types
of canals require a supply of water, viz. to replace losses caused by :—

(a) Traffic requirements.

(6) Evaporation from the water surface.

(c) Percolation and absorption through the earth banks and waste due

to leakage.

(d) Leakage at the lock gates and sluices and under and around the

locks themselves.

The measurements, so far as (b), (c) and (d) are concerned, have not to
my knowledge ever been accurately measured or gauged. The amount
required for (a) is easily calculated, and the only quantitative knowledge
we have so far as regards (5), (c), and (d) is the amount of feed water that
has to be let down to keep the several reaches filled and to meet the traffic
requirements, so by deducting the known requirements from the total
we can find the necessary amount of water that is required for (0), (c) and
(d), but I know of no means of separating these three into distinct units.

The leakage coming under (d) is often considerable and can be traced
to faulty construction, the state of repair and maintenance, the careless
closing of the gates, and to obstructions that get across the bearings of
the stops, mitres and meeting faces.

3. I next come to the question of supply of water to meet these several
requirements and they differ in all the three cases. Generally, supplies
may be obtained from any of the following sources :

(i) By the rainfall over a catchment area which can be collected and
stored in artificially made reservoirs.

(ii) By the flow directly.into the canal of rivers, streams, etc.

(iii) The storage water obtained under (i) being taken to the canal either
by gravitation or pumping, according to the level of the supply
water in its relation to the canal water level.

(iv) By pumping water from rivers near by the canal, but which are at
a lower level than the canal.

(v) By returning the water ‘ used up’ by traffic to the higher reaches
by means of pumps erected on the lower reach.

4. So far as the ‘ artificially cut canal’ is concerned, its supply may be
derived from all the before-mentioned sources, and a lot of very useful
nN could be obtained by arranging for systematic measurements being

en :—

At the reservoirs to ascertain the rate of fall in the level of the water in

the reservoir due to the feed water supply that is kept on, and also

410 REPORTS ON THE STATE OF SCIENCE, ETC.

to ascertain the rate of rise in the reservoir due to ‘ run-off’ from the
rainfall.

Of the amount of feed water that is ‘ kept on’ to supply the requirements
set out under (a), (0d), (c) and (d).

Of the amount of feed water that is ‘kept on’ at the individual locks
together with recorded levels of the reaches both on up- and down-
stream sides of the lock.

Of the number of lockings that occur daily at each lock.

5. So far as the ‘ combination of artificially cut canal and canalised river ’
is concerned, in this case no doubt fairly extensive weirs will be constructed
on the various reaches for carrying away flood water, so in this type it
would be desirable for records to be kept :—

At each lock of the level of the water in the reaches (up- and down-stream),

Of the amount of feed water that is ‘ kept on.’

Of the daily number of lockings at each lock.

Of the height of the water passing over the several weirs during normal

and flood periods.

6. This introduces another subject which will certainly arise, i.e., what
is the formula to be adopted for the calculation of the amount of water
passing over the weir under various heads, and it is suggested that a very
useful amount of experimental work could be carried out by gauging the
flow in the artificial cuts carrying away the weir water to ascertain how the
coefficient of discharge varies according to the types of weir constructed.

7. So far as the ‘ canalised river ’ is concerned, the measurements required
will be practically similar to those necessary for the immediately preceding
type, except that in all probability the weirs will be longer and larger,
and we may also have the problem of mills being constructed athwart the
river and absorbing a large amount of water, and arrangements for measuring
the amount of water they consume should also be made in addition to the
measurements to meet canal requirements. In many cases millers are
responsible for the river and/or canal water level being kept too high or
run too low in the several reaches both as regards canal working and also
as regards the standing surface water level of the surrounding land.

8.,Of the various sources of supply mentioned in paragraph 3, only
the first has a sufficient and efficient organisation in existence to supply
the necessary data ; the others are only dealt with by canal authorities to the
extent that the efficient working of their canal demands.

9g. No doubt the various canal authorities have a lot of information
available, but whether they would be prepared to consent to this information
being supplied to a co-ordinating body set up for the purpose is one that
would have to be very tactfully ascertained from them, and this would
form a suitable subject for discussion with the main Committee of which
we are a Sub-committee, to ascertain from them how far they consider the
matter should be pursued.

SuB-MeEmoraNnpDuM D (6).

WATER POLLUTION AND RIVER GAUGING.
By A. PARKER.

GENERAL.

Accurate information regarding the flow of rivers and streams, river levels
and underground sources of water is of value not only in connection with

INLAND WATER SURVEY 411

water supplies, land drainage, fisheries, hydro-electric schemes, electricity
supply stations and various manufacturing processes, but also in attempts
to control and prevent water pollution. The extent to which sewage or
other polluting effluent ought to be purified is dependent partly on the
diliition afforded by the river into which the effluent is discharged ; the
greater the dilution the more rapidly the river recovers asa result of self-
purification processes. A knowledge of the flow of the river or stream
concerned is therefore necessary if plant for the treatment of sewage and
industrial effluents i is to be designed and operated on the most economical
lines.

“Attention has been directed on many occasions to the importance of
river flow data in’ relation to water pollution problems. The Royal
Commission on Sewage Disposal, whose comprehensive inquiry during
the period 1898 to 1915 dealt with the methods of treatment and disposal
not only of sewage but also of trade effluents, definitely stated that the
standards to be applied to sewage effluents should be adjusted according
to the character of the streams into which they are to be discharged. ‘The
same principle undoubtedly applies to trade effluents. During the inquiry
a considerable number of rivers and streams of different. types were kept
under observation with a view to tracing the effects of discharging various
séwage liquids of known composition and volume into streams of known
any. volume and velocity; and the scheme of standards which the

oyal Commission finally recommended for sewage liquids was based on
the results of these observations. The value of river flow data in dealing
with problems of pollution has also been stressed in each of the published
annual reports of the Water Pollution Research Board of the Department
of Scientific and Industrial Research since the appointment of the Board
in 1927. In addition, references to this same application of measurements
of river flow have been made in published reports issued by the Ministry
of Health, the Ministry of Agriculture and Fisheries and the West Riding
of Yorkshire Rivers Board, and in other publications.

’ Unfortunately, comparatively little information on the flows of rivers
and streams in this country is available, with the result that in most instances
the effects of discharges of polluting ‘effluents on individual rivers cannot
properly be assessed. As an example of the dearth of information of this
kind, even for important rivers, reference might be made to the river
Tees. Early in 1929, the Water Pollution Research Board began a compre-
hensive scientific survey of this river, with the object of obtaining reliable
data regarding the quantities of polluting effluents of various kinds which
can be allowed to enter a river without unduly retarding the natural processes
of self-purification of the polluted river water. In this instance there
were at the outset no gauging stations on the main river or its tributaries,
and. no reliable records of river flow and levels. The chemical and
biological work of the survey had to be supplemented, therefore, by hydro-
graphical measurements not merely of tidal currents in the estuary, but also
of freshwater flows in the upper river.

In recent years the various authorities, undertakings and individuals
responsible for dealing with pollution problems have undoubtedly begun
to appréciate the importance of river flow data. A few have already made
observations of the flows and levels of the rivers in which they are interested;
and there are definite signs that, with encouragement, many others will be
willing to arrange for river flow ‘and level measurements to be made.

It may be asked whether the labour and expense likely to be involved
in securing data on river flow can be justified in relation to the value of
such data in dealing with pollution problems. In the first place river flow

412 REPORTS ON THE STATE OF SCIENCE, ETC.

data are necessary in deciding whether the discharge of a particular effluent
to any individual stream is likely to cause nuisance or to endanger public
health. Many rivers which are to some extent polluted will, in the future,
have to be utilised after treatment as sources of water supply for both
domestic and industrial purposes. In such cases more accurate information
on the effects on rivers of various discharges and more careful control of
the discharges will be required. Secondly, as already mentioned, data
on the flow of the river concerned are necessary if plant for the treatment
of sewage and industrial effluents is to be designed and operated on the
most economical lines. It is not possible to estimate the expenditure
involved in the satisfactory treatment and disposal of industrial effluents,
but it must be considerable in view of the very large number of industrial
undertakings in this country producing effluents which have to be treated
and discharged into rivers and streams. As regards sewerage and sewage
disposal, loans sanctioned by the Ministry of Health for expenditure on
such works during the three years 1929-30, 1930-31, and 1931-32, amounted
to £5,800,000, £8,900,000, and £7,740,000 respectively.

RIVERS POLLUTION PREVENTION AUTHORITIES.

The principal statutory enactments relating to river pollution are con-
tained in the Rivers Pollution Prevention Acts, 1876 and 1893, which are
directed towards the abatement of pollution in the public interest generally,
and in the Salmon and Freshwater Fisheries Act, 1923, which has in view
the same object in the interests of fisheries.

The duty of enforcing the Rivers Pollution Prevention Acts was originally
entrusted to the sanitary authorities, i.e. town councils and urban and rural
district councils. Under Section 14 of the Local Government Act, 1888,
county councils were given concurrent powers throughout their adminis-
trative counties. ‘The same section also gave power to the Local Govern-
ment Board (now Ministry of Health) to set up, by Provisional Order,
subject to confirmation by Parliament, joint committees or similar bodies
for the purpose of administering the Rivers Pollution Prevention Acts.
Under this section three such bodies have been set up : (1) the Ribble Joint
Committee, (2) the Mersey and Irwell Joint Committee, and (3) the West
Riding of Yorkshire Rivers Board. Fishery Boards also have power,
under Section 55 of the Salmon and Freshwater Fisheries Act, 1923, to
institute proceedings under the Rivers Pollution Prevention Acts.

According to the general law at present, therefore, the power of en-
forcing the Acts of 1876 and 1893 is vested in :

(1) All town councils, and urban and rural district councils.

(2) All county councils.

(3) In respect of the Ribble, the Mersey and Irwell, and the rivers in
the West Riding of Yorkshire, joint committees or rivers boards
set up to deal with those particular rivers.

(4) Fishery boards under Section 55 of the Salmon and Freshwater
Fisheries Act, 1923.

In addition there is a Joint Committee, without statutory powers to
take legal proceedings, set up under Section 57 of the Local Government
oe ee in respect of the upper waters of the Tame (a tributary of the

Trent).

The Upper Thames and the Lee are the subject of special legislation
which has set up Conservancy Boards possessing wide powers of controlling
pollution. Both these rivers supply the Metropolitan Water Board with

INLAND WATER SURVEY 413

water for public supply. The powers granted to the two Conservancy
Boards are greater than are given in the Rivers Pollution Prevention Acts.

Reference should also be made to a clause in the Land Drainage Act,
1930, which provides that a provisional order constituting for a catchment
area or combination of catchment areas a joint committee or other body
having any of the powers of a sanitary authority under the Rivers Pollution
Act, 1876, may be made under Section 14 of the Local Government Act,
1888, by the Minister of Health of his own motion and without any
application by the Council of any of the counties concerned. No joint
committee or similar body has so far been set up under this particular clause.

From the preceding paragraphs, it is clear that the administration of
the Rivers Pollution Prevention Acts is vested in local sanitary authorities,
joint committees, fishery boards and other bodies on which the local
authorities are represented. In dealing with problems of pollution and of
fisheries, these bodies are definitely interested in river flow data, river
levels, compensation water and similar matters. It is suggested that these
bodies should in general be in a position to arrange for systematic measure-
ments of river flow and river level, the results of which might then be sent
to some central office for collection, correlation and, possibly, publication.
Some of the local organisations mentioned are obtaining data on river flow,
but in most instances no systematic observations have yet been made.

Matin MEMORANDUM FE,

UNDERGROUND WATER.
By BERNARD SMITH.

I. SUGGESTIONS AS TO OBSERVATIONS AND MEASUREMENTS NECESSARY.

In any organisation dealing with inland water resources accurate
observations should be taken on the occurrence, amount and quality of the
water stored underground in suitable permeable strata, and upon that
which issues in the form of springs and seepages.

In some districts percolating water is stored in rocks of open porous
texture such as certain sandstones, which form natural reservoirs lying
between, or faulted against, impermeable strata in such a way that a definite
measurable water-table is established ; while in others it is stored mainly
in systems of connected fissures and bedding planes (such as those in
chalk), also with a fairly definite measurable water-table. In other cases,
again, it occurs in more sporadic fashion, either (a) in thin, and at times
discontinuous, permeable strata—as when thin beds of limestone or sand-
stone alternate with shales, or sandy lenticles occur in glacial clays—or
(6) in irregular fissures from which isolated springs may arise, but in which
no definite water-table can be determined—as in slates, granites, etc.

Beneath cover, and down dip, many of these rocks in their subterranean
extension will yield water under artesian head when tapped by bores or wells.

In all cases the thickness, geological character and structures of the
water-bearing rocks require careful study.

Water-tables.—It is essential that any measurable water-tables occurring
in strata that fall within a definite drainage-basin should be studied in
detail, and contours or cross-sections drawn to show their levels at three,
four or more different periods of the year. For this purpose it is desirable
to have standing water levels measured in a carefully selected series of
wells, that tap water in the bed or beds undergoing observation, within as

414 REPORTS ON THE STATE OF SCIENCE, ETC.

small a time limit as possible (say one week or less) for-each chosen period
of the year. _In some wells at which continuous pumping is not going on
the levels might be taken daily or weekly and related to rainfall, percolation
and -evaporation. ‘These would give a more continuous picture of the
fluctuations of the water-table during the year.

Local co-operation would be necessary to gather widespread and consistent
data for drawing contours; but the selection of the wells and the general
supervision might be the task of a hydrogeologist. Some central authority
is needed to encourage a standardised procedure and receive the necessary
data for the construction of a continuous series of contoured maps.

The seasonal fluctuation in the water-tables at or near outcrop would
appear to depend upon :—

(1) Percolation and evaporation ; (2) issue from springs ; (3) pumping.

At trial borings and established pumping stations records are needed of.
(1) the actual amount of water pumped (stating whether working at full
capacity); (2) the maximum fall in water level during pumping; (3) the
rate of lowering of the water level; (4) the rate of recovery after cessation
of pumping; andsoon. Cones of depression in the surface of the water-
table should be mapped out and related to the diameter of the well or
boring, the suction level, capacity of pumps, physical character of the
water-bearing rock and other relevant factors.

Arising out of the plotting of water-table contours, the effects of pumping
on the general, as distinct from strictly local, water-table over a number
of years could be studied, and the results of overpumping—with possible
deterioration of the water both in quantity and quality—properly evaluated.

Amongst associated rocks with different degrees of permeability, perched
water-tables are to be expected.

Isolated wells—In areas where isolated or very widely spread wells
occur it may not be possible to construct either contours or sections of the
water-table (even if present); yet the original geological details, and
subsequent continuous pumping records, will be useful guides to estimating
prospects for future boreholes in the neighbourhood. Their value: will
increase as more and more wells are sunk.

Springs and wet-lines —All springs should be marked down and ganged
consistently. They are the headwaters or subsidiaries of surface streams
fed from underground storage and occur (1) as overflows from permeable
rocks at positions where the water-table cuts the surface of the ground—
as in the Bunter Sandstone area of Sherwood Forest, or in Chalk districts;
where also ‘ bournes’ commence to flow when the water-table rises above
a certain level; (2) as isolated and unrelated issues from irregular. systems
of fissures in less permeable rocks. As a rule springs are much more
regular in yield than the streams they help to feed, and, like rivers issuing
from lakes, far less liable to rapid fluctuations.

It may be:noted that geologists frequently discover previously eens riick
springs, especially alongside, and in the beds of, streams during low-water
periods. ‘They also note and usually map ‘ wet-lines ’ or lines of seepage—
the potential sources of springs—and relate them to the local geology.

Data of this kind are extremely valuable when local water supplies or
impounding schemes are in question, and are especially desirable in
districts—such as those of predominantly shaly, slaty or granitic rocks—
where no water-table, in the ordinary sense, is to be expected.

Quality of water (mineral). —A point that requires research is that of the
potability of water apart from the effects of organic pollution. In certain
cases waters in formation near outcrop, and for a short distance beneath
cover, are potable, but become increasingly hard, saline, and unpotable

INLAND WATER SURVEY © 415

some distance down-dip—yet still well inland, as at Lincoln (Boultham).
In other cases sea-water may gain access to concealed water-bearing rocks
near the coasts or in estuaries—as in parts of Essex, Kent and Sussex.
It is required to discover the approximate line at which the water becomes
unpotable, and the underlying causes of the change. Help from geo-
physicists may be obtained in future, for already it is thought by some to
be possible to detect the change from fresh to saline waters in buried rocks
by means of instruments. Again, changes in the mineral content of water,
where permanent pumping machinery has been in action for many years,
are apt to recur pari passu with lessening yield. Quite apart from changes
that may occur as the distance increases down-dip, or as the overlying
geological cover may alter in character (e.g. in some Chalk areas), research
is needed on the relative qualities of waters derived from definite individual
strata. These ought to be studied much as a palzontologist concentrates
on fossil zones. The form of mineral analyses of waters seems to require
standardisation so that rapid comparisons may be made. It frequently
happens that a bore taps two or three water-bearing horizons, and the
analysis made is that of a mixed water. One of the sources, from a
particular bed, may be known from previous research to be highly saline.
If located and tubed off the quality of the remainder would be improved.

Other problems for study—Amongst other problems to be studied are
(a) the prevention of pollution of underground waters by sewage and
soakaway, (4) the possible repletion of underground reservoirs by means of
dumb-wells, (c) the effects of mining on the distribution of underground
waters.

Conclusion—Records as complete as possible should be secured of all
new wells or borings, and studied from every point of view. Such work
can be undertaken only by persons with special qualifications as hydro-
geologists.

2. OUTLINE OF THE RECORDING AND ASSEMBLY OF DATA.
CoNTINUOUS MEASUREMENTS OF WATER LEVELS.

» Records of water levels during static periods or whilst pumping is in
progress are kept at the larger water undertakings in the country and
occasionally also at private wells (see Appendices (a), (b), (c), (d)), some
covering as much as eighty years; but few of these (apart from those
within the orbit of any economic unit) have been brought into regular and
continuous relationship with others outside, although several undertakings
may draw water from the same geological formation in the same drainage
area. Hence the regular construction of maps or diagrams showing the
(say, monthly) variations in the water-table has been impracticable hitherto.
Useful maps and diagrams and empirical rules as to fluctuations to be
expected have indeed been issued from time to time in printed papers or
water supply memoirs (see Appendices (d) and (e) and Bibliography) ; but
usually the maps refer to only one or perhaps two isolated periods in any
one year, or to a mean annual level alone.

An excellent summary of the kind of observations that might be and
frequently are taken at pumping stations and private wells will be found
in the Report on Stream Flow and Underground Water Records, Section II,
C and E, issued by the Committee of the Institution of Water Engineers
(October 1929), under the chairmanship of Dr. H. Lapworth.

Flow from springs could be measured by weirs. ;
» Collection of general water-supply data.—With regard to the collection
of widespread geological and water-supply data derived from the sinking

416 REPORTS ON THE STATE OF SCIENCE, ETC.

of borings and wells and the study of springs, those of the Geological
Survey are doubtless the most extensive, and may be referred to here as
showing the uses to which such collections may be put. Most of the large
boring and exploration firms and many water engineers and consulting
geologists have considerable, but naturally less extensive, collections of
their own, that have been drawn upon for useful publication from time
to time.

Geological Survey: water supply data—Throughout its existence,
now nearly a century, the Geological Survey has collected records of well-
sections and borings ; but in the early days their use was in the main purely
geological, as an aid to stratigraphy and mapping. Later, when the value
of geological knowledge for underground water-supply became generally
recognised, they were sought for this purpose also.

The information, formerly assembled or published in connection with the
Old Series 1-in. Geological Maps, was next filed under counties, and
the issue of special County Water-Supply Memoirs was begun. This
policy has been continued to the present day and twenty-six memoirs have
been published. ‘There are also chapters on water-supply in many of the
Sheet Memoirs. Data for the early memoirs were gathered from various
sources, but the exact siting of a number of the bores left much to be
desired, and the other information was, in many cases, all too meagre.

At present the collection, filing and siting of records, which already
amount to many thousands, is more consistent, and special studies of areas
of underground water-supply are made from time to time.

Details of wells or bores are entered on section sheets with a special
heading (Geological Survey Memoir form), and comprise as many observa-
tions of a general nature as are likely to be of value—failing continuous
observations of water-levels ; but it must be noted that the information
received is usually incomplete, since the only powers exercised by the
Geological Survey are in respect of borings and shafts over 100 ft. in depth,
sunk in search of minerals.

Present sources of information are from :—

(1) Old Survey Memoirs and other geological publications.

(2) Information obtained on the spot during the 6-in. surveys now
in hand, or from special limited surveys for Water-Supply Memoirs.

(3) Well-sinkers, owners and others who apply for geological advice
on water-supply, or who consult the Survey whilst their work is
in progress.

(4) The books and files of well-known water-boring firms.

(5) The Ministry of Health, who forward copies of the records supplied
to them in cases with which they deal. In important instances
the Survey is asked to give an opinion upon the geological aspects of
the schemes submitted and the prospects for finding the required
amount or quality of water.

With regard to source (3), inquiries about water prospects are now
followed up, after a reasonable interval, if the inquirers do not communicate
further. As a result, the Survey files are becoming increasingly ample,
and a greater number of essential details are secured. In particular, the
accurate location of the well or bore is asked for, and this is plotted on a
I-in. map reserved for the purpose.

Inquiries about water-supply dealt with at headquarters in London,
Edinburgh, Manchester, York and Newcastle, amount to several hundreds
a year.

As a result, the Survey is generally in a position, when inquiries are
made about an area, to give a reasonable or accurate estimate of water

INLAND WATER SURVEY 417

prospects; and this power is increasing with time. Furthermore, the
geologists become specialists on those areas with which they are best
acquainted, from having surveyed and studied either the actual rocks in
question, or their counterparts.

Questions of water-supply apart, it is incumbent upon the Survey, as it
always will be, to collect as many records as possible of strata pierced by
wells, boreholes or shafts, and to secure important rock specimens and
fossils for study.

Although much has been done in the past, and more is contemplated for
the future, it is not claimed that the organisation is as good as it might
be, and this for two main reasons :—

(1) The information has chiefly to be acquired (i) by willing acquiescence
or gratuitous offers on the part of water engineers, well-sinkers, and others
who appreciate the work that is being done; (ii) by personal relationship
between them and Survey officers ; or (iii) by the following up of inquiries.

(2) The work is necessarily limited by the time and energies of the
staff that can be spared from carrying on the general work of the Survey.

EXAMPLES OF CONNECTED RECORDS OF WATER LEVELS, ETC.,
PUBLISHED IN GEOLOGICAL SURVEY MEMOIRS.

Water Supply in Nottinghamshire, 1914.—Contours, at 5-ft. intervals, of
the water-table in a part of the Bunter Pebble Beds, south of Bawtry and
west and south-west of Retford (Fig. 1, p. 7). From one series of
measurements only. The concealed surface of the Pebble Beds is con-
toured (Plate I). ‘This shows the depth with reference to Ordnance Datum
at which artesian Bunter waters can be struck beneath impervious Keuper.

Saffron Walden Memoir, 1932 (Explanation of Sheet 205).—Contours,
at 25-ft. intervals, of the water-table in the Chalk, for February 1928 and
June and October 1929 (Plates IV and V). Plotted from measurements
made by Cambridge geologists under Mr. W. B. R. King, O.B.E., M.A.,
and by officers of the Royal Engineers, under Major R. S. Rait-Kerr, R.E.

Wells and Springs of Sussex, 1928.—Map and diagrams of the summit
of the water-table in the South Downs, near Brighton, by Mr. A. B.
Cathcart, M.Inst.C.E. (Fig. 5); and graphs showing the relationship of
water-level in a well at Broadwater, Worthing, to rainfall from drawings
by Mr. F. Roberts, M.Inst.C.E. (Fig. 6).

Records of London Wells, 1913.—Contours of the underground water
surface at various dates (Fig. 2), and a coloured map of underground
water-levels at 25-ft. intervals (Plate I). Also a diagram showing difference
in amount of bourne-flow water passing Kenley and Purley gauges (Fig. 4),
and a map of the London districts showing contours of the pre-Tertiary
Chalk surface.

APPENDIX E (a).

WATER LEVEL IN THE CHALK AT COMPTON,
W. SUSSEX.
By D. Hatton THomsOoN.
Measured in well at Compton House, Compton. Ground

level, 266 ft. O.D. Depth of well, 180 ft. Recorded water
level varies between 220 and 94 ft.O.D. No pumping.

The saturation level in the chalk emerges at ground level at varying
points lower down the valley up to a distance of 44 miles from Compton,

418 REPORTS ON THE STATE OF SCIENCE, ETC.

according'to rainfall and season. ‘This intermittent stream forms the upper
reaches of the River Ems.

Weekly water levels are available from 1893 to 1930, and the record is
still being maintained (February 1933); there are, however, gaps in the
record prior to 1898. Also, prior to 1903, the measurements were made
at another well in the near vicinity.

Rainfall records at the same site are available for the whole period ; also,
since 1920, a percolation gauge, recording percolation through 3 ft. of chalk,
has been maintained.

An examination of the well-record shows that during dry periods there
is, at any given level, a maximum rate at which that level falls, and that this
maximum rate decreases as the level itself decreases. By piecing together
these maximum rates a ‘ dry weather depletion curve’ can be established >
when the observed rate of depletion is less than that shown by the curve,
or if the level is actually rising, the difference is ascribed to percolation :
The curve, therefore, can be used to analyse the record into two components,
(1) depletion by underflow, and (2) replenishment by percolation. It is:
also found that there is a direct relation between the vertical displacement
of the ground-water level and the effective percolation, by means of which
the fluctuations can be converted into rainfall units.

The water levels are normally lowest in the late autumn, when percolation
is negligible. If the record is divided into periods of nine to fifteen months,
according to the date of recommencement of the annual percolation cycle,
it is found that the percolation figures, as measured by the subsoil gauge
and as calculated from the water levels, are in close agreement. It is also
found that the annual evaporation loss, after excluding the effect of ground-
storage, is nearly constant.

APPENDIX £ (6).

THE SOUTH STAFFORDSHIRE WATERWORKS COMPANY.

DESCRIPTION OF METHODS FOR OBTAINING WATER LEVELS IN
WELLS AND BOREHOLES.

By F. J. Drxon.

In the case of shallow wells the water level is usually obtained by direct
measurement with a wooden float and cord, or if permanant apparatus is
desired then a copper float with a flexible metallic cord working through
either pulleys or geared reducing apparatus indicates the water level.

The actual indication at the surface can be shown on a graduated gauge
board or a dial, but if a permanent record is desired then.a recorder in
which the movement of the chart is synchronised with a clock is the best.
Usually these recorders are made to give a seven-day record, but a shorter
or longer period chart can be used if the recorder gears are arranged to suit.

For deep wells float gears are not so suitable and in boreholes their use
is impracticable. 'The two most suitable methods are the direct measure-
ment method by galvanometer and the pneumatic system reading either on
a gauge or recorder,

The galvanometer consists of a rubber-covered single or double core
cable on a drum fitted with handle for winding up the cable. At the loose
end of the cable is a sinker with brass contact, which is connected to the
cable and covered with a vulcanite sheath, having a hole in the bottom and
a small vent hole at the level of the contact.’ In the case of the double-core

INLAND WATER SURVEY 419

cable, there are two contacts and this sheath prevents the instrument giving
a false reading if water from the strata is falling down the borehole.
Suitably arranged in a box with the cable drum, are a milliameter and a
9-volt dry battery. In the case of the single core cable the circuit is
completed by earthing on to the pump or by a copper bar pushed direct
into the ground. ‘To obtain the water level the cable is lowered until
the pointer of the milliameter is deflected, showing contact has been made
at the water level when the cable is drawn up and the level determined by
measurement.

“The pneumatic system consists of a gauge or recorder, mounted usually
with the pump gauges, together with an air bottle with pressure gauge,
control cocks, foot pump and copper-piping carried down the borehole
below the lowest water level.

The piping (4-in. bore) is clamped to the pump and lowered with it as
erection proceeds. If the size of the borehole will allow, then a bell is
usually placed on the end of the pipe to act as a small air reservoir.

The gauge or recorder is connected direct on to the pipe and a branch on
the pipe connects to the air bottle, which is turn is connected to the foot
pump. A control valve is placed directly under the gauge and also on the
pipe leading from the air bottle. ‘The gauge or recorder is graduated in
feet below floor level, but the dial is reversed as regards marking when
compared with a standard gauge. Assume the gauge or recorder was to
read to a maximum depth of 200 ft. below floor level, then the end of the
pipe or bell must be exactly this distance below the floor. If the water
was down to this level there would be no pressure in the pipe and the
pointer in its zero position would show 200 ft. on the dial or chart. It is
necessary to maintain a pressure in the air bottle higher than pressure due
to variations in water level and a gauge is fitted on the air bottles to enable
the operator to see he is maintaining a suitable pressure with the foot pump.

If we now assume the water level is 100 ft. below floor level and the
pressure in the bottle was go lb., then the air admitted to the gauge pipe
would leak away at the bell or‘pipe end until the pressure just balanced the
head of water in the borehole and the pointer would now show 100 ft. below
floor level on the gauge or recorder. Where there are marked variations in
water level due to alterations in the rate of pumping, or the plant is only
operating a certain number of hours daily, then the best instrument to instal
is the seven-day recorder type, as every alteration is indicated and the actual
time when it occurred, the charts thus obtained giving valuable permanent
records.

- A galvanometer is usually provided at each station to check the pneumatic
depth recorder and also for use in case of a failure on the air-pressure
system.

APPENDIX E (c).
1. PUMPING TESTS AT NEW BORINGS FOR WATER.

*" 2..GAUGING OVER LONG PERIODS FROM WELLS
IN THE CHALK.

By R. C. S. WALTERs.

1. NEw WATERWORKS, ASHBOURNE, DERBYSHIRE, 1930.

tthe water is from Bunter beds lying 223-300 ft. below surface, and
ees Keuper Sandstones and Marls. Borings consisted of a trial bore
and two permanent boreholes.

420 REPORTS ON THE STATE OF SCIENCE, ETC.

In May 1926 the trial hole was tested. This hole was 8 in. in diameter
and 300 ft. deep, and was found to justify the development of the site.

By January 1927 the first of two permanent boreholes, 32 ft. apart, each
23 ins. diameter and 300 ft. deep had been sunk and tested. The second
permanent boring was sunk and tested by the following July. The trial
boring was 5 ft. distant from No. 1 borehole and 31 ft. from No. 2 borehole.

The table below summarises these tests.

The great variation in tests may be traced mainly to the effect of opening
out the strata by several borings and also the result of clearing by extended
pumping. It is obvious that in such strata any conclusions as to the true
yield can only be arrived at after many tests or prolonged pumping.

SuMMaARY OF TESTS ON BOREHOLES.
DuRATION ONE TO FIvE Days.

* Specse
uantity | Rest . yield.
Test. Date. Hole. | Gals. per | Level ion RewOr, Gals. per
hour. Feet. * | hour per
foot.
I May 1926 . | trial 4,840 25 43 I10
3 January 1927 .|No.1 10,500 26 70 150
6 | February 1927 . |No.1]| 10,000 28 44 227
8 | July 1927. . |No.2] 15,500 25 113 138
9 | January 1929 «6. | No.2] 12,500 29 59 212
1o | January 1929 «6. |No.1| 12,500 | 29 44 284

2. A summary of the facts concerning wells in the Chalk which have
been gauged for continuous long periods—varying from a minimum of
three to a maximum of eighty-four years—will be found in Table I of ‘ The
Hydro-Geology of the Chalk of England,’ Trans. Inst. Water Engineers,
vol. xxxiv, 1929.

APPENDIX E (d).
NOTES ON RAINFALL, REST-LEVELS AND PUMPING LEVELS
IN THE CHALK
as deduced from records supplied by
A. E. CoRNEWALL-WALKER.
The East Surrey Water Company.

The records consist of graphs, for 1924 to 1930 (inclusive), at the Purley

Well, of (a) Rest Level ; (6) Pumping Level, and (c) Rainfall.
From a study of the graphs the following points emerge :—

(1) The low degree of porosity is shown by the way in which the rise off
the water level lags some four months behind periods of heavy rainfall.

(2) Irregularities in the rainfall curve tend to become smoothed out in

the rest-level curve ; thus, at one point, two ‘ peaks ’ in the former produce
one in the latter.

(3) After long periods of heavy rainfall the water-level remains high for a

INLAND WATER SURVEY 421

considerable period, the curve being flat-topped ; while after short periods
of heavy rainfall the high water-level soon drops, giving pointed curves.
(4) The average curve of pumping-levels follows closely the curve of
rest-levels. In the present case a composite pumping-level curve is shown,
stronger pumps having been installed in 1926. A measure of water
pumped is shown by the difference in feet between the two water-level
curves ; and the stronger pumps increase this difference without otherwise
affecting the similarity of the two curves. From this illustration it is seen
that in wells where it is not possible to measure rest-levels, except at very
long intervals, some idea of the rest-level may be obtained if records of
pumping-levels are kept, and the difference between pumping and rest-
levels, as determined by occasional measurement, added.
(5) Compare—
(a) ‘ London Wells ’ (Mem. Geol. Surv.), Plate III.
(6) £ Wells and Springs of Sussex ’ (Mem. Geol. Surv.), pp. 19-20.
(c) ‘ Hydrogeological Conditions in the Chalk at Compton, Sussex,’
Inst. Water Engineers, 1921.
(d) British Rainfall, 1919, pp. 257-262, for summary of details, and
bibliography, of records from 1836 onwards, for Chilgrove.

Matin MeEmMoranpumM F.

RIVER GAUGING.
By W. N. McC ean.

1. CHOICE OF SITES.

The sites generally chosen by river authorities for gauging rivers are at
weirs which have been constructed for the purpose of abstracting water or
controlling flow. ‘These sites are chosen because, by installing a recorder
water level gauge in still water above the weir, the flow at any water level
is given by some weir formula. That there is any resemblance to accuracy
during floods seems to be unlikely. For low flow estimates they may be
very convenient.

In practice, the weir itself is not the weir of the laboratory experiment ;
except at low flows, it is partially or wholly submerged and a varying formula
has to be used according to the downstream water levels at some vague
point. The velocity of approach is probably unmeasured. Records of
the water abstracted, which may be the greater part of the low flow, have to
be kept accurately. There are often many complications of sluice control.

Generally speaking, the best site for river gauging, with the current meter,
is a steady-running reach with a steeper water slope down stream, so that
there may be no backing up due to the downstream flood conditions.

These sites are not always obtainable, and often the water-slopes on rising
and falling rivers will have to be very carefully measured during the gaugings
and afterwards for the records.

Sites should be chosen where the river is always within its banks or where
the overflow is never of any considerable amount.

The choice of a site for gauging is not often an easy matter and it may be
necessary to use different sites for floods and low waters. There is much
to be said for the reading of low flows at weirs or in narrow channels and the
big wide reaches are best for floods.

_ The main object of gauging a river should be to obtain continuous records
of water level and of corresponding flow.

422 REPORTS ON THE STATE OF SCIENCE, ETC.

2. SITE SURVEY AND WATER LEVEL GAUGE INSTALLATION..

Assume that a suitable site has been selected.

A careful survey of the river bed and banks should be made above and
below the gauging section. The zero for levels and the zero and direction
of the gauging section should be fixed, for all time, by permanent stations
on the banks which are included in the survey.

The sites of the water level recording points have then to be settled. One
of these will have to be the final station for the continuous records of water
level. Another will have to be on the gauging site in order to give the depths
of water during the gaugings. ‘This will have to be a permanent gauge if
the water slopes are found to differ on the rising and falling river.

The water level apparatus requires special consideration according to
the nature of the site, but automatic recorders and gauge posts are necessary.

When sufficient funds are available there is little difficulty in setting up
permanent stations with float gauges; but in the moreordinary circum-
stances it is best to follow the bank up with short gauge posts: or with a
series of pipe-wells for the use of a hook-gauge. ‘The automatic takes the
form of an air box in the lower well connected by a small diameter pipe to
the clock-driven chart on the bank top.

The site may now be considered as equipped with the necessary water
level apparatus for the flow measurements and for the permanent records.

3- FLow GauGING APPARATUS, ITS SETTING-UP AND USE.

On rivers of any considerable width where floods are to be measured, the
apparatus is the boat or punt or double-punt, with a cross river ropeway ;
the velocities being measured by current meters on wire or rod. The
writer and others have used the bos’n’s chair on a ropeway, and it is not satis-
factory. A portable bridge with trestle piers on the lower part of the bank
may prove best on narrower rivers.

In the writer’s experience, accuracy of current meter observations is
dependent principally on the use of a rod which holds the current meter
steady to the point and depth ; readings then become uniform, even in the
presence of considerable turbulence.

The writer’s apparatus has been developed gradually. It is founded on
a secure ropeway across the river which remains unchanged throughout the
whole period of gauging work. It is easily transported, and is adaptable to
most sites. The head lines of the double-punt are attached to a small
trolley which is made to travel along the ropeway by means of an endless
rope worked from a winch on the bank. The double-punt is steadied and
held in position by another light wire rope across the river. ‘This rope
passes round a drum fixed at the base of the frame which holds the gauging
rod, and the strain on therope is regulated from the bank. An independent
tally line marked at each 5 ft. is permanently stretched across the river
about 2 ft. upstream of the actual gauging section.

The double-punt used by the writer is very completely equipped for
control from a small cabin. The operations are :—

(1) Adjustment up and down stream on the head lines.

(2) Adjustment to the tally line mark by revolving the drum. of the

straining rope.

(3) Adjustment of the current meter dan by raising or lowering the rod.

Each punt is in two parts for ease of transport and launching.

The principal point to emphasise is the use of the streamlined rod, which

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INLAND WATER SURVEY 423

enables steady observations to be made at depths of 17 ft. or over in high
velocities. ‘This rod resembles the struts of an aeroplane in section. It is
also used for soundings. The efficient and safe carrying out of the gauging
is dependent on the care, skill, and accuracy of a surveyor, who is a practical
engineer, a rigger and a boatman.

4. CURRENT METERS,

There are many good types of meters which record, electrically, the
revolutions of the meter.
The essential gauging points are :—

(a) The care of the meters.

(6) The careful work of looking out for weeds, leaves, etc., on the
meter during gauging.

(c) The frequent calibration of the meters at the National Physical
Laboratory and the use of several meters.

5. THE GauGING OPERATIONS AND ACCOMPANYING FIELD Work.

On a 100-ft. to 300-ft. width of river, the velocities are measured on every
gauging at each 10-ft. mark on the tallyline, and often at every intermediate
5 ft. At each of these points, velocities are measured at 6 in., 1 ft., and each
foot to the bottom, and at intermediate 6 in. near the bottom.

The time intervals given by the buzzer are entered on the field sheets,
and also the clock time at the point.

On shore, the assistant keeps the water level records at the two gauges

against the clock time. A hook-gauge in a well is used for these water
levels, and they are plotted for the day. Automatic recorders may be used
in the future.
+ During floods, the water levels vary very considerably during the gauging
day, but the underlying principle of the writer’s method is that each point
on the river has its separate stage-discharge curve, thus eliminating inac-
curacies of computation due to varying water level during the gauging day.
The gauging day thus ends with velocity field sheets and the graphs and
readings of water levels.

6. COMPUTATIONS.

These do not need description in detail, and the whole work centres on

the Stage-Discharge Diagram at each gauging point on the section. A
diagram is attached to this Memorandum, giving, for each water level gauged,
the cusecs passing the point for a 1-ft. width of river and, by intermediate
markings, the cusecs passing at each foot or 6 in. of depth. The water
slope is given against the water-level height of the recorder gauge. To this
diagram is added a diagram of maximum velocities at and near the surface.
This yields a maximum velocity-stage graph, and, by applying different
coefficients to these maximum velocities, the coefficients applicable to each
stage of the river may be judged.
_ These coefficients are used for the final smoothing of the stage-discharge
curve of each point, and, finally, the discharges at each 3 in. of water level
height are transferred to a diagram giving the discharges for the whole river
section at each 3 in. of water level. The results are also tabulated. On
these lines, if there is no overflow, the discharge values may be reasonably
extended to higher floods and approximately to lower low waters.

424 REPORTS ON THE STATE OF SCIENCE, ETC.

47, THE CONTINUOUS RECORD OF WATER LEVELS CONVERTED INTO
FLow REcorDs.

There is, firstly, the table of flow for each } in. or so of water level, which
has resulted from the river gaugings.

From the graph of the water level recorder, the average water level of
each 3 hours is tabulated on the main records table and each 3-hourly
value is converted into flow. ‘The daily average flow is then tabulated.

On special floods, shorter time intervals may be used on a similar table.
Such tables will provide all necessary data for any investigation required.

The essential point to make clear is that the records should be, firstly,
records of water level and the conversion to flow should not be made on
the water level recorder graph. The reasons for this decision are many.
The shortest way of putting the point is that flow measurements are sub-
sidiary to water-level measurements and that the connection between the
two may change (1) by changes in the river, and (2) by improved measure-
ments. But beyond that, water levels are a definite record of storage and
stage throughout the whole river system.

In further reference to river gauging, extracts from Prof. Dixon’s and
Mr. Griffiths’ statements are attached (see Appendices a and b).

APPENDIX F (a).

NOTES ON THE GAUGING OF THE RIVER SEVERN,
AT BEWDLEY.

By S. M. Dixon.

1. The gauging site, half a mile above Bewdley Bridge, is in a section of
the river which is sensibly straight and of reasonably uniform width for a
little over three-quarters of a mile. About a quarter of a mile above the site is
a short section of rapids, which dries partially at extreme low flows. Another
similar shallow section occurs three-quarters of a mile below the gauging site.
The river, near the site, flows between high steep banks, its width varying
from about 140 ft., at minimum flow, to about 180 ft., at which point it over-
flows its banks into level fields on either side. ‘The bottom is of rock, and
the depth at minimum flow varies from 7 ft. in midstream to about 3 ft.
close to the banks.

There is a gauge post at the site, consisting of four cast iron sections,
bolted to steel channels, set in concrete on the bank, each projecting 3 ft.
from the ground, and recording over a total rise of 11 ft. in water level.
Each foot is divided into tenths.

Daily records of the water level are read on a permanent cast iron scale
fixed just below Bewdley Bridge, about half amile down-stream of the gauging
site, and on a sloping concrete scale cut in the Aqueduct carrying the
Birmingham Corporation’s water supply across the river two miles above
the site. An automatic recording gauge is also installed at the latter place
and is attended to weekly by the Corporation Water Department’s walksman,
who lives close by. The sloping concrete scale serves to check the setting
of the automatic recorder.

The zero of the gauge at Bewdley Bridge was chosen to correspond with
the lowest water level which was likely to occur. The zeros of the other
fixed gauges were chosen arbitrarily, the zero of the automatic gauge at the

INLAND WATER SURVEY 425

Aqueduct being the same as that of the fixed gauge beside it. On the
Aqueduct gauge the reading of the lowest water-level recorded is 9°4 ft.,
corresponding to a discharge of 290 cusecs. Other extreme readings are :—

Highest recorded level, 24‘5 ft. corresponding to a discharge of 17,000
cusecs.

Highest summer level, 21:7 ft. corresponding to a discharge of 12,400
cusecs.

Lowest winter level, 10-15 ft. corresponding to a discharge of 710 cusecs.

2. Two meters are used for measuring discharges, an Amsler propeller-
type meter, and the small Price bucket-type meter. In each case, velocities
are measured at intervals of 1 ft. vertically in planes ro ft. apart horizontally.

The Amsler meter is always used on a rod operated from a flat-bottomed
punt. The punt is located and kept stationary by two wire cables, bow and
stern, anchored to the banks, and the rod held over the side.

The Price meter is always used suspended from a cable slung between
two permanent steel standards fixed on either bank. Raising and lowering
and traversing the meter are accomplished by means of two winches, one
on either standard. A full description of this apparatus, and of the method
of using it, will be found in a paper entitled ‘River Gauging’ by M.A. Hogan,
Ph.D., and published by the Department of Scientific and Industrial
Research.

Except close to the banks, and in conditions of extreme low flow, the
velocities of water at the gauging site always exceed about ? ft. per sec.,
and no attempt is made to measure velocities below # ft. per sec.

Occasional measurements of surface velocities are made with wooden
floats 3 in. square and 1 in. thick, their paths being determined by
readings from two theodolites on the tow-path.

The field book contains five columns, Distance (from a fixed point on
bank), Sounding, Depth of Meter, No. of Revolutions (of meter) and Time.
The corresponding velocities are subsequently determined from the meter’s
rating curves—which are checked from time to time in the College Labora-
tory—and the discharges are worked out graphically, by plotting cross
sections of the river and the velocity-depth’ curves at each ro ft. vertical.
Corrections are applied, if necessary, for alteration of the water-level during
gauging, and for down-stream sag of the meter’s suspending cable.

Up to the present, some eighty-five gaugings have been made on about
fifty different occasions during the last eleven years. It is hoped that it
will shortly be possible to compare the results with measurements of the
discharge made at Lincomb Weir, some four miles further down the river.

(Diagrams have been made showing the section of the river at the gauging
site, a typical annual hydrograph, and a drawing from which the results of a
gauging were calculated.)

APPENDIX F (5).
THAMES CONSERVANCY.

NoTEs ON GAUGING.
By G. J. GRIFFITHS.

Current Meter Gauging .—A straight uniform section of the river is selected,
usually 100 ft. in length, and carefully cross-sectioned at both ends and in
the middle. Wires are spanned across the river at each cross-section,
divided into 10 ft. intervals or compartments.

Q

426 REPORTS ON THE STATE OF SCIENCE, ETC.

A current meter (propeller type), with either visible or audible revolution
counter, is then submerged at 6 in. and at other regular depths down to a
point of 6 in. above the river bed, in the centre of each compartment,
readings being taken at each depth. From the plotted velocity curve an
average velocity for the compartment is obtained.

This velocity, in feet per minute, is multiplied by the area of the compart-
ment, and the summation of this process for all the compartments gives
Q for the length of river in question. ;

At times the gradient of the river is also taken and a discharge is calculated
and compared with the current meter observations, with a view to finding
the appropriate coefficients for the section of river under examination. It
may be pointed out, however, that this investigation is by no means easy of
application on the Thames. The river is weired at average intervals of
24 to 3 miles, and it is only when the weirs are fully drawn, or nearly so,
that an approximately natural condition can be obtained.

Also when the river is in full flood the water overflows the banks and
shallow side streams flow over land and meadows which are obstructed by
hedges, fences, buildings, etc. ‘These and many other practical difficulties
have to be provided for, and it is largely a matter of experience as to the best
method to be adopted under the particular conditions of each case.

In certain cases it is found advisable to substitute rod or float readings
for current meter observations.

NOTE.

The Report on Inland Water Survey was adopted at the Leicester
Meeting of the British Association, 1933, by Sections A (Mathematical and
Physical Sciences), E (Geography), and G (Engineering), on whose recom-
mendation the Committee was appointed in 1932. It was felt by these
Sections that Memorandum E and its appendices, dealing with the measure-
ment of underground water, should be regarded as a basis for fuller
treatment of the subject, after consultation with Section C (Geology).

SECTIONAL TRANSACTIONS.

(For reference to the publication elsewhere of communications entered in the
following lists of transactions, see end of volume, preceding index.)

SECTION A.
MATHEMATICAL AND PHYSICAL SCIENCES.

Thursday, September 7.

Prof. L. VecarD.—The auroral spectrum and the upper atmosphere (10.0).

A summary account is given of present knowledge of the auroral spectrum
and its consequences.

Most of the results are based on spectrographic work carried out in
Northern Norway, at Bosekop and Tromsé6 (1912-26), and during the last
three years important results were obtained at the new Auroral Observatory,
Tromsé, in collaboration with Mr. L. Harang and Mr. E. Ténsberg.

In the explored region from 9,000 A.ininfra-red to the limit of atmospheric
transmission in ultra-violet, 85 bands and lines have been detected. Apart
from the strong green line and a couple of red lines, probably due to oxygen,
the auroral spectrum is dominated by nitrogen bands belonging to the negative,
and the first and second positive, groups. The type of nitrogen spectrum
agrees well with the theory of Birkeland, that the luminescence is produced
by electric rays from the sun. The high intensity of the green line is ex-
plained by assuming oxygen atoms excited through collisions of the second
kind with active nitrogen, where a kind of resonance effect takes place.

The auroral spectrum gives no indication of an upper atmospheric layer
dominated by hydrogen and helium.

Typical variations within the auroral spectrum have been detected and
studied. One of these consists of the enhancement of red lines producing
the red colouring of the aurore. A second is an altitude effect detected in
1923, one aspect of which is the enhancement, with increasing altitude, of the
nitrogen bands relative to the green line.

The temperatures of the emitting molecules of the auroral region were
quantitatively measured by means of negative nitrogen bands.

The spectral altitude effect, seen in relation to the height, extension and
luminescence of the auroral streamers and to the low temperature observed,
shows that nitrogen must be carried to high altitudes through the effect of
an electric state set up by the action of a solar radiation of short wave-length.
The resulting state and the distribution of matter, resembling the sun’s
corona, is described and shown to fit in with results of radio-echo work,
and to give a simple explanation of the zodiacal light and the night-sky

luminescence, agreeing well with spectral observations of Rayleigh and
Slipher.

Dr. R. J. VAN pE Graarr.—The electrostatic generation of high voltage
for nuclear research (10.30).

428 SECTIONAL TRANSACTIONS.—A.

Joint Discussion with Section K (Botany) on The X-ray analysis of
fibres (11.0) -—

Mr. W. T. AstBury.—Some recent developments in the X-ray inter-

pretation of the properties of hair, feathers and other protein
structures.

The recognition by X-ray methods of the regular, side-to-side cohesion of
long, chain-like molecules to form crystalline bundles has served to give
form to existing physico-chemical data, and helped us to understand for
the first time many of their most characteristic properties. In particular,
it has been found possible to follow changes under applied stress and
chemical treatment of the configuration of gigantic protein molecules, such
as those of the keratin of hair and feathers, and thereby to study the molecular
mechanism of their long-range elasticity and link it up with that of simpler
molecules. The crystal analysis of the chain-bundles involves at the outset
some generalisation of the usual geometrical treatment, with the result that
we are led to the concept of standard average dimensions of intra-molecular
units, from which can be predicted the probable density of proteins as a
class and the weight per unit area of mono-molecular protein films. Devia-
tions from these standard average dimensions, as in the case of gelatin, may
be used to investigate the linkages which give rise to them and ultimately,
it may be hoped, to derive the precise form of the intra-molecular pattern,
while from a knowledge of the molecular direction associated with each
particular dimension we may follow the course of localised reactions such
as the attack of water on the protein side-chains. The interaction of water
with protein and other chain-bundles offers points of considerable interest,
especially when studied in relation with their elastic properties.

Dr. R. D. Preston.—The structure of the cell wall of Valonia.

While the cells of most species of Valonia are approximately isodiametric
and are not to be considered as fibres in the morphological sense, their walls
are certainly composed of molecular fibres such as are typical of the true
fibres of the plant. Sufficient work has already been carried out to indicate
the importance of investigations on the walls of these large cells in relation
to the organisation of the walls of what may be called the ‘ obvious ” fibres.
The wall of Valonia consists of a kind of molecular basket-work over the
whole surface composed of two sets of cellulose chains, crossing at about
80° to each other, which have been shown to be parallel to the two sets of
striations visible under the microscope. These chains of cellulose exist in
the form of well-defined crystalline aggregates whose orientation is usually
remarkably perfect. As observed by Sponsler, the planes of ‘spacing
6-1 A. tend to lie parallel to the surface of the wall, though there exists an
undoubted dispersion. Variation of the relative amounts of the two sets
of chains from point to point in the wall gives rise to a somewhat misleading
heterogeneous appearance in the polarising microscope.

The structure of the cellulose net of the whole wall is now being mapped
out by a ‘ lines of force method,’ and it seems highly probable that the
crossed chains observed at any point are portions of two spirals.

Dr. J. B. SpEAKMAN.—Fibre chemistry and X-ray analysis.

Wool fibres may be stretched as much as 70 per cent. of their length in
cold water without losing the power of returning to the original length.
If, however, stretched fibres are exposed to the action of steam for, say,
six hours, they assume a ‘ set ’ which is not eliminated even by re-steaming

SECTIONAL TRANSACTIONS.—A. 429

in the absence of tension. The discovery that deaminated fibres are in-
capable of taking a ‘set’ permanent to steam, gives an opportunity of
interpreting the molecular mechanism of the setting process. ‘The problem
is interesting because its solution involves the combined use of chemical
and X-ray methods, and because of the many analogies between the action
of steam on strained fibres and the heat coagulation of egg albumin.

Mr. J. THEwWLIs.—Fibre structure in teeth.

X-ray analysis reveals that tooth enamel, like several other growing
structures (e.g. asbestos, cellulose), consists of fibres. "Tooth enamel con-
sists mainly of calcium, oxygen and phosphorus, with the possible addition
of chlorine or fluorine, and the atoms of these elements are arranged in the
same way as in the mineral apatite. The crystals of apatite, and hence of
enamel, are hexagonal, and the arrangement of the enamel fibres is such that
the hexagonal axes of the individual crystallites all tend to be parallel—
i.e. the hexagonal axis is the fibre-axis.

In human enamel there are two sets of fibres, one with the fibre-axis
inclined at about 20° to the normal to the surface of the tooth, and on the
same side as the tip; the other with the fibre-axis inclined at about 10°
to the normal to the surface, and on the opposite side to the tip. In dog’s
enamel the fibre-axis is at right angles to the surface of the tooth.

Variations in degree of fibreing are found in_ histologically normal
enamel, and three kinds of enamel can be distinguished. In human teeth
it is found that one kind is associated with clinically immune teeth, and the
other two with clinically susceptible teeth.

Mr. Oar BLocu.—Principles and applications of infra-red photography
(12.30).

A photograph of the audience was taken at the beginning of the
demonstration, the hall being illuminated with infra-red light.

The renascence of interest in infra-red photography is due to the syn-
thesis of a new tricarbocyanine dyestuff which renders possible the produc-
tion of emulsions of considerably higher speed to infra-red radiation and
greater cleanliness in processing than existed previously.

Much interest has been created by the long-distance photographs in
which there has been a considerable amount of haze penetration owing to
the lessened scatter of infra-red light by moisture particles constituting
haze or mist. But there are many other applications of the process to the
arts and sciences, and examples of these are shown and discussed. They
include astronomy, medical work, photo-micrography, investigation of
dyed materials, spectroscopy, the detection of obliterated, over-written or
erased writings. Some of these depend upon the power of infra-red
radiation to penetrate beneath the surface of tissues, etc., which are opaque,
or nearly so, to visible radiation. In short, since most photography is record
work depending upon differentiation, wherever differences exist between the
infra-red photograph and the ordinary photograph, the process is one which
may have a useful application.

AFTERNOON.
Excursion to Daventry Broadcasting Station.

430 SECTIONAL TRANSACTIONS .—A.

Friday, September 8.

PRESIDENTIAL ApprEss by Sir G. T. Waker, C.S.I., F.R.S., on Seasonal
weather and its prediction (10.0). (See p. 25.)

Prof. F. Linxe.—The influence of the stratosphere on cyclone formation
(11.0).

The Norwegian polar-front theory stands in contradiction to the opinion
of several German and Austrian meteorologists, in that the formation and
movement of cyclones are produced by inertia or gravitational waves in the
stratosphere.

The wave movements originating on the fronts of the troposphere are
insufficient to explain the energy produced thereby.

The following facts speak for independent stratospherical waves :

(1) On all stratifications with sufficiently great density gradients inertia-
waves can originate, therefore also in the tropopause.

(2) By means of isallobar maps one can study the course of very expansive
wave systems right round the earth, which do not agree with the movements
of the cyclones and even intersect them. ‘These wave systems must have
their origin in the stratosphere. It is observed that fronts which are
becoming stationary again become activised by such waves.

(3) According to the Norwegian view, on the ground, cooling must be
connected with rising air pressure and decrease of cloudiness, warming
with falling air pressure and increase of cloudiness. Frequently, however,
especially in the middle latitudes, a rise of pressure is observed with warm
air invasions, and a fall of pressure with cold air invasions. This can only
be explained by means of the overlying stratospherical waves.

(4) Persistent obviously stratospherical high pressures and low pressures
are sometimes observed. ‘These are circumscribed by short stratospherical
waves, which can invite the building of cyclones.

The stratosphere therefore controls }the tropospherical cyclones.
‘Fronts ’ are stimulated when energy is supplied to them through altera-
tions of the pressure gradient, which are determined in the stratosphere.

On the other hand, however, a reaction of the occurrences in the tropo-
sphere on the stratosphere also takes place. ‘This must be explained on
purely dynamical lines, whereas the action of the stratosphere is purely
statical. "There exists, therefore, a mutual coupling between stratosphere
and troposphere. The Norwegian and German-Austrian cyclone theories
are united in a ‘ theory of the complex cyclone,’ whose further investigation
constitutes the chief problem of synoptical meteorology.

Prof. E. REGENER.—New results in cosmic ray measurements (11.25).

Mr. Wm. Tay tor, O.B.E., and Mr. H. W. Lee.—The development of
photographic lenses at Leicester (11.50).

The problem of the photographic lens is to secure a well-defined image
over a considerable flat field. The solution was not discovered till dense
barium crown and light flint glasses were available to the lens designer,
although the principles applied by Dennis Taylor in the Cooke lens could
have provided a solution with the older glasses. Rudolph (1890), Goerz
(Dec. 1892), and H. Dennis Taylor (Jan. 1893) solved the problem, in
different ways, with the aid of these. The Continental type of lens,

SECTIONAL TRANSACTIONS.—A. 431

comprising many components cemented together, is compared with the
Cooke lens in its various types.

For aerial photography during the war a special type of lens was required,
and the Cooke-Aviar was developed. At this time also the aperture of the
Cooke was increased to F/3. In recent times still larger apertures have
been called for, and the Cooke F/2 and F/2:5 and F/1-5 lenses developed.
Projection lenses for the modern cinema also have had to be of greater
aperture, and this has led to the development of a series of lenses of apertures
F/2 to F/1:5. It is noteworthy that all the modern large-aperture lenses
consist, like the Cooke lens, of separated components, and that the Con-
tinental lens, with many components cemented together, has practically
dropped out in the race.

The anastigmatic Telephoto lens was also first made at Leicester.

The problems of optical design, and the methods used, are reviewed.

The trend of photographic optics is towards the production of lenses of
small focal length and greater speed, largely influenced by the increasing
employment of small cameras, kinematographs, and finer grained emulsions.

Leicester methods of manufacture and testing lenses. Interchangeable
manufacture.

Dr. L. Stmons and Mr. E. H. Smart.—Demonstration of a model to
illustrate the classical motion of a diatomic rotator with two degrees

of freedom (12.40).

AFTERNOON.
Visit to British Thomson-Houston Works, Rugby.

Monday, September 11.
DIscussIONn on Atomic transmutation :—

Rt. Hon. Lorp RuTHERFORD oF Netson, O.M., F.R.S.—A review
of a quarter of a century’s work on atomic transmutation (10.0).

In 1907 a discussion on the constitution of the atom was held before
Section A at the meeting of the British Association at Leicester, in which
the importance of the study of the transformations of radioactive bodies
was indicated, and the difficulty of explaining the part played by positive
electricity was emphasised.

In 1911 clear evidence for the nuclear structure of the atom was put
forward. It soon became evident that outer electrons played no major
part in transmutations, and that in order to institute any permanent atomic
transmutation the structure of the nucleus must be changed. In 1919
decisive experiments were made. When «-particles were fired in nitrogen,
a new type of particle appeared—the proton. Photographic evidence
showed that the capture of an «-particle by the nucleus was accompanied by
the emission of a proton. The nitrogen nucleus, therefore, of mass 14 and
charge 7, assimilates an «-particle of mass 4 and charge 2 and expels
a proton of mass 1 and charge 1. We are therefore left with a nuclear
structure of mass 17 and charge 8, which is an isotope of oxygen. Other
transmutations may be similarly checked, remembering that all such changes
must obey what may be termed general energy conditions.

Beryllium of mass 9 and charge 4, when bombarded, captures an «-particle
of mass 4 and charge 2, giving rise to a nucleus of mass 12 and charge 6,

432 SECTIONAL TRANSACTIONS.—A.

emitting a neutron of mass 1 and charge zero. Future experiments will
show that the neutron is a very powerful weapon of research.

Five years ago it became evident that other types of fast particle must be
used if more information were to be forthcoming, and it was found possible
to obtain from the electric discharge large supplies of particles the speeds of
which might be raised by passage through an electric field. This demand
has resulted in the development of laboratory methods for the production
of high potentials.

Lately, developments of wave mechanics theory have shown that particles
which could not normally surmount a potential barrier might yet get
through if intense streams were employed at relatively low voltages.

Dr. J. D. Cocxcrort and Dr. E. T.S. WaLton.—The transmutation
of elements by high velocity protons (10.30).

The production of types of nuclear transmutation other than the classical
#-particle-proton synthesis by Rutherford and Chadwick was for many
years considered to require ions of several million volts energy for use as
projectiles. This deterrent was removed by the new view of atomic col-
lisions introduced by the wave mechanics, Gamow’s theory of the nucleus
suggesting that protons having energies of a few hundred thousand volts
ought to be able to penetrate the nuclei of the lighter elements.

The apparatus developed by the authors produces protons having
energies up to 700 kilovolts ; with these protons they have been able with
certainty to disintegrate the elements lithium, boron and fluorine, the entry
of the proton leading in all three cases to the ejection of an «-particle.
Lithium splits up into two «-particles, two types of transmutation occurring
in one of which an energy equivalent of 17 million volts is liberated. Boron
appears to split up into three «-particles with a total energy release of about
9 million volts. Wilson chamber photographs of the disintegration pro-
cesses are shown, and the evidence for the conservation of energy and
momentum discussed. 'The relations between the Gamow theory and the
experimental results are considered.

Dr. M. L. OL1pHaNT.—The disintegration of the elements with hydrogen
ions at low bombarding energies (11.0).

Experiments are described in which many of the elements in a very
pure state have been bombarded with protons and with ions of the hydrogen
isotope of mass 2. It is shown that the heavy elements, and in particular
lead and uranium, are not disintegrated appreciably by bombardment at
energies below 220 kilovolts. ‘The extraordinary sensitivity to traces of
boron and lithium are described.

The disintegration of boron by proton bombardment is discussed in
detail, and the results obtained are explained tentatively by a simple theory.

The disintegration of lithium by both protons and ‘ deutons ’ is described,
and the remarkable efficiency of the latter particle as a disintegrating agent
is pointed out.

Mr. P. I. Dee.—A photographic investigation of the transmutation of
the elements (11.30).
The experimental methods used in the investigation of the transmutation

of the light elements, as described by the earlier speakers, have been
extended by the construction of an expansion chamber to work in conjunc-

SECTIONAL TRANSACTIONS.—A. 433

tion with the high voltage apparatus of Cockcroft and Walton. The beam
of high velocity ions was directed upon a thin target of the element under
investigation, contained in an evacuated tube which passed through the
glass roof of the expansion chamber. The walls of this tube where they
surrounded the target were constructed of mica of such thickness that the
disintegration particles passed through them and formed cloud tracks
which ended in the chamber, whilst any protons scattered at the target
were completely absorbed in the mica.

With a target of lithium subjected to proton bombardment under these
conditions photographs were obtained which showed the emission in
opposite directions of pairs of particles, each of range 8:3 cm. ‘This would
correspond to the mode of transmutation given by the equation

Li? + ,H!—> jHet + sHe’.

Photographs showing a similar emission of pairs of oppositely directed
particles were obtained when lithium was bombarded by ions of the heavy
isotope of hydrogen, but in this case each particle had a range of 13°4 cm.
This would correspond with transmutation according to the equation

3Li® + 1H? —— 2He?* + oHe?.

The ranges of the helium atoms obtained by substitution of the exact
atomic masses in these equations are 8-4 cm. and 13:0 cm., agreeing closely
with the observed values.

Photographs of the short range particles produced when lithium and
boron are bombarded by protons have also been obtained, but conclusions
as to the mechanism of disintegration in these cases cannot yet be drawn.
Greater technical difficulties arise in the investigation of such short ranges,
and attempts are being made to develop a more suitable method.

Discusston on The positive electron (Mr. P. M. S. Biacketr and
others) :-—

Mr. P. M.S. BLacketTT (12.0).

Positive electrons are produced in certain types of collision processes.
Their first detection, by Anderson and by Blackett and Occhialini, was due
to the study of cosmic rays by the cloud method. These photographs
showed the presence of positively charged particles with a mass comparable
with that of a negative electron. From the ionisation along their tracks it
can be deduced that the mass and charge of the positive electron do not
differ in magnitude from those of the negative electron by more than
50 per cent. The positive electrons appear to originate in some type of
atomic or nuclear process brought about by the incident cosmic radiation.

Positive electrons have also been found by Chadwick, Blackett and
Occhialini, by Curie and Joliot, and by Meitner and Phillip to be produced
when the radiation from a beryllium target is bombarded by alpha particles.
The measurements of Curie and Joliot suggest that they are produced by
the hard gamma rays emitted by the source rather than by the neutrons.
It has further been shown by Anderson that positive electrons are also
produced when the gamma rays from Thorium C” are absorbed by heavy
élements. It is therefore probable that the production of positive electrons
plays an important part in the anomalous absorption of gamma rays.

Q2

434 SECTIONAL TRANSACTIONS.—A.

Tuesday, September 12,
Discussion on The expanding universe (10.0) :—

Prof. Sir A. S. EppincTon, F.R.S.—The expanding universe.

The observational facts which led to the idea of an ‘ expanding universe ’
are, I think, pretty well known. Outside our own galaxy of stars there are
millions of other galaxies which appear to us as spiral nebule ; and these (so
far as they have been observed) are found to be running away from us.
The greater the distance, the faster they move ; and approximately, at least,
the speed is proportional to the distance. This progression of speed with
distance has been traced up to a distance of 150 million light years, where
the speed amounts to 15,000 miles a second. For the moment we stop
there because observation is becoming too difficult, but no doubt in due
time still more remote nebulz with still higher speeds will be found.

If we plot this distribution of motion it is easy to see that the spiral
nebule are running away from each other just as much as they are running
away from us. It is, therefore, not a case of scattering away from one point,
but a general uniform expansion or dispersal in which all mutual distances
are increasing in the same proportion. We have therefore an expanding
system of galaxies—or, since the system of galaxies is all the universe we
know, an expanding universe. We may therefore say it is a simple, direct
fact of observation that our material universe is expanding. Whether it has
always been expanding and always will expand is another question.

I do not think the speakers who are to follow me will challenge this—
I am judging by what I already know of their views—and it will probably
be accepted as the common basis of discussion. It is therefore, perhaps,
all the more incumbent on me to say that it is not universally accepted as
proved ; there is scepticism in some quarters, and it must not be assumed
that either I or the other speakers regard this scepticism entirely with con-
tempt. We have generalised from data which are not so extensive and not
so accurate as we could wish. It is often pointed out that what we actually
observe is a red shift of the spectrum of the nebulz ; and although a red
shift of the spectrum usually means that the object is running away from us,
it is possible that there might be other causes. We can only reply that if
some other cause is operating in the case of the spiral nebula, it is some
entirely unknown circumstance of which we have as yet no hint, either in
theory or observation. I suppose that entirely unknown circumstances
might upset all our scientific inferences, and there seems no need specially
to introduce this bogy in connection with nebular velocities.

Turning to theory, it is a necessary consequence of the theory of
relativity that there should exist in addition to the ordinary gravitation of
bodies a repulsive force which we call ‘ cosmical repulsion.’ This is too small
to affect small-scale systems such as the solar system, and we can only
expect to detect it in a system on the largest possible scale—if it is detectable
at all. Cosmical repulsion is of such a nature that if it acted on a system
of galaxies at rest it would make it expand uniformly—just the type of
expansion or dispersal that we observe. We must not forget that the
galaxies are attracting one another in the ordinary way, and that this attrac-
tion might, in certain circumstances, hold the dispersing force in check.
However, if the dispersing force once gets the upper hand it will keep it ;
because as it drives the galaxies further apart their mutual attraction will
weaken and offer less opposition to the dispersal. ;

SECTIONAL TRANSACTIONS.—A. | 435

Thus observation tells us that the galaxies form an expanding system;
and theory tells us that there is a force of cosmical repulsion which, if not
counteracted, will produce just such an expansion. So far, so good. But
there is still a doubt whether the theory has anything to do with the observa-
tion, because the relativity theory omits to tell us how large the force of
cosmical repulsion will be. So far as the current theory is concerned, it
might be imperceptible in the system of the galaxies. ‘Therefore, having
no idea of the size of the effect, it is rather a big jump to identify it with the
first thing we come across that looks at all like it. I have tried to contribute
to the settlement of this question by developing relativity theory (with the
aid of wave mechanics) in a way which leads to a direct calculation of the
amount of the cosmical repulsion. I have to begin at the other end of
things and ask you to consider the mass of an electron.

By the mass of the electron we mean the mass in C.G.S. units—i.e. in
terms of the standard kilogram. Accordingly, in any experimental deter-
mination of the mass of an electron, whatever auxiliary apparatus may be
employed, there are two indispensables, viz. an electron and the lump of
metal called the standard kilogram. ‘The experimenter cannot proceed
without a theory: he reads certain deflections, angles, etc.; but he would
not know what to do with these, unless a theorist gave him directions
how to combine them and extract the numerical quantity m out of them.
What is this theory—these equations which connect the behaviour of
the two indispensables, the electron and the kilogram mass? ‘The
experiment will consist of a number of links, and each link will have its
corresponding theory; at the electron end we shall use microscopic, i.e.
quantum theory ; at the kilogram end we shall use macroscopic theory, i.e.
classical mechanics, or, for greater refinement, relativity theory. But there
must be one link which unites a microscopic mass with a macroscopic mass,
included neither in quantum theory nor in relativity theory but with one
‘end in each. It is this link that my investigation supplies. It will be said
that this link is already known; we know how to make the step from
microscopic to macroscopic theory, e.g. as in Bohr’s Correspondence
Principle. Quite so. We know how to do it; it only remains to do it—
to find what formule result in this particular problem. I do not require
any new hypothesis in my investigation: it is the mathematical working
out of principles already accepted. ‘The result is that microscopic and
macroscopic masses are linked through the equation

1om® — 136mm + mo? =
where m is the mass attributed to the single particle and mo is the mass of
the reference frame to which it is implicitly referred.

' In passing it may be mentioned that this equation gives two values of m,
one 1847°6 times the other, which is as nearly as we can tell the ratio of the
‘mass of the proton to that of the electron. But we are more concerned with
Mo, which is connected with cosmical magnitudes. I will try to show, by
‘a short cut, how the mass of the reference frame arises. "The argument will
probably appear fishy—as short cuts generally are. But I have also found
the same result by going the long way round. The short cut depends on
the Uncertainty Principle.

If we have a particle in space of radius of curvature R and know nothing
at all about its location, we may express its uncertainty of position as + R;
‘+ is here an abbreviation for ‘in an unknown direction.’ ‘The particle is
“distant ’ R from the centre of curvature of space in an unknown direction.
By the Uncertainty Principle the corresponding uncertainty of momentum is
+h/2rR ; that is to say, it has a momentum //27R in an unknown direction

436 - SECTIONAL TRANSACTIONS.—A.

arising out of the uncertainty relation. If we take a frame of reference con-
stituted out of the mean of N such particles, the uncertainty of position
of the mean is -- R/1/N according to the usual theory of combination of
vectors in random directions, and the corresponding momentum is
4/Nh/2nR in an unknown direction. The proper mass is obtained by
dividing the momentum by c. Hence the frame has a mass

fives N,
anc R

In quantum theory (which follows the methods of statistical mechanics)
we lay down what is called ‘an a priori probability distribution ’ of the
electron or electrons considered, and this serves as a frame of reference.
This will give an average density and average momentum at all points, and
hence an energy-tensor. By Einstein’s equation the energy-tensor cor-
responds to a curvature of space. This curvature is usually neglected in
quantum mechanics ; but in the linkage between microscopic theory and
macroscopic theory it is clearly of fundamental importance, since macro-
scopic mass corresponds to space-time curvature. Without going into
details, we may conclude that it is necessary to identify the curvature due to
the a priori probability distribution of particles in quantum theory with
the curvature Ag,» which forms the standard with which the curvature
due to macroscopic objects is compared. Each theory uses a standard
distribution in the way that a geodesist uses a geoid ; and to unite micro-
scopic and macroscopic theory we have to adapt them to the same geoid.
The result is that N is the number of particles in the whole universe and R
the ‘de Sitter’ radius of space-time. The two formule above given
determine +/N/R in terms of the mass m of an electron or proton.

Knowing +/N/R, we can find the theoretical value of the limiting speed
of recession of distant objects. It turns out to be 780 km. per sec. per
megaparsec. The observed value (which is subject to considerable uncer-
tainty, and may be a little less than the limiting speed owing to the gravita-
tional attraction of the nebulz on one another) is 550 km. per sec. per
megaparsec.

Prof. E. A. Mixne, M.B.E., F.R.S.

The earliest reference I have found to the expansion of the universe is
Genesis i. 6, when the Authorized Version gives in a marginal note the in-
formation that in Hebrew the word ‘ firmament’ means also ‘ expansion.’
We may conjecture that if allusion could be made to the expansion of the
universe in so primitive a cosmology as that ascribed to Moses, then the
expansion itself must be a very primitive phenomenon. This seems to be
the case.

The observed motions of the extra-galactic nebulz, considered as units,
are utterly different from the Keplerian motions of the planets in the solar
system, from double-star orbits, and from the motion known as star-
streaming and galactic rotation. The extra-galactic nebule are simply
separating from one another. This is a characteristic of any system of
particles in free flight, or endowed with velocities sufficiently large to
escape from the gravitational attraction of the remainder. Such a system,
from the moment at which it is first given (save for negligibly improbable
initial conditions) inevitably expands, and its constituent particles sort
themselves out in velocity, the fastest being the furthest at any given epoch,
followed by the next fastest, and so on. ‘The velocity zones partially over-

SECTIONAL TRANSACTIONS.—A. 437

lap, but the velocity segregation becomes more perfect with increasing time.
Further, the relation between velocity v and distance r, measured from any
particle of the system, is a simple proportionality v~ 1/t, where t is the time
that has elapsed since the system was first given. ‘These characteristics
hold for any system of particles unconfined by any rigid boundary, free to
occupy an indefinitely large volume of space. The epoch at which the
system is first given is the epoch of minimum volume of the system, and
affords a natural time-zero. At this instant (except for negligibly improb-
able distributions) both the system itself and its velocity-reverse necessarily
undergo expansion.

It appears then that the motion of a gravitation-free system of particles,
or of any system with sufficiently large speeds, reproduces the observed
motions of the extra-galactic nebulz in the three characteristics of expansion,
velocity-zoning and a velocity-distance proportionality. The value of t, our
present epoch, reckoned from the epoch of minimum volume, comes out at
about 2 X 10° years; this simply describes the position of the epoch we
happen to be experiencing. On a broad view then it is suggested that the
system of the nebule is that of a system of particles in free flight, subject to
zero or negligible gravitational influences. In any case the expansion is an
inevitable phenomenon, arising kinematically and not in virtue of gravita-
tion; repulsive forces are not required to be invoked to account for it.
It is a primitive phenomenon, as foreshadowed by the author of Genesis.
It is the most natural thing in the world.

The expansion phenomenon itself, however, is only a part of the general
cosmological problem, which is that of the distribution of both matter and
motion in the universe. ‘The usual theory of relativistic cosmology assumes
part of the answer to this problem outright : it assumes that the universe is
homogeneous. For a world devoid of motion the notion of homogeneity
is unambiguous. If the density at any point, to any one observer attached
to a stationary particle of the system, is the same as at any other point, then
the same will be true for any second observer attached to some other par-
ticle of the system. But if to one observer A the universe is homogeneous
but changing in density with the time owing to the motion, then it cannot
appear homogeneous to a second observer B attached to some other particle
in relative motion with respect to A. For by saying that the universe is
homogeneous to A, we mean that at a world-wide instant ¢ for him (i.e. at
instants simultaneous in his reckoning) the density at P equals the density at
Q: e(P,t) = e(O,t). But these will not be in general simultaneous instants
for B; consequently, if the universe is also homogeneous to B, he will
consider A to be measuring the density at different times, when accordingly
the density e(P) is not equal to the density ep(Q). This is a contradiction.
Einstein, in destroying the notion of absolute simultaneity, destroyed also
the notion of absolute homogeneity for asystem whose density is not constant
in time. The usual theory of relativity cosmology evades this difficulty by
constructing a map of the world in which the ‘ surfaces of constant density ’
are labelled ‘ surfaces of constant cosmic time t’; Tt is not the time of
experience, and surfaces ‘@ = constant’ are not ‘spatial’ sections of
experience. The homogeneity of the section ‘~ = constant ’ is a fictitious
homogeneity, obtained by examining each element of the universe at the
stage at which its density, measured locally, takes a given value. No infer-
ence can be made as to the homogeneity or otherwise of an actual spatial
section of experience until cosmic time Z is linked with experienced time f,
as has been done recently by Dr. McCrea and others. The resulting maps
of the world are ‘ expanding maps.’ They are maps of a very particular
kind, since on the general theory of relativity, given the distribution of

438 SECTIONAL TRANSACTIONS.—A.

matter in motion, the curvature of the map to be used is definite. The
geometry of any map is, however, a matter of the arbitrary choice of axioms.
But just as it is legitimate to use curved maps and expanding maps, so, if we
free ourselves from the restrictions in map-drawing imposed by the general
theory of relativity, we can use flat maps and stationary maps. ‘ Space’ in
the abstract is a non-entity, like the aether, and hence to talk of ‘ curved

space’ or ‘ expanding space’ is to label as phenomena of nature what are ©

really attributes of a man-made map. The picture of the expansion
phenomenon obtained by the consideration of a swarm of particles is a case
of the use of an ordinary flat map.

Instead of making any direct assumption as to the homogeneity or other-
wise of the smoothed-out universe, we may return to the kinematic system
previously considered and simply ask what must be its velocity distribution
if it is to possess no preferential velocity-frame—that is, if the velocity dis-
tribution is to be the same from whatever particle the system is viewed. We
must, of course, employ some principle to correlate the observations of
different particle-observers. A sufficient principle is that, for any two
particle-observers in uniform relative motion, each observer is completely
equivalent to the other. When each particle-observer possesses a temporal
experience, it is then possible to infer+ the Lorentz formule of ‘ special ’
relativity, which are thus available for correlating the observers’ descriptions
of events.

It is then readily found that the velocity distribution must be of the form

B du dv dw
ce (1 — Lu?/c?)?
where B is a constant, u, v, w being the components of velocity. It then
follows, by making the substitutions
x ¥y

z
Eb My (8 Fy Wes

t t

that the spatial distribution tends to the asymptotic form

Bt dx dy dz
(2 — Xx?/c?)*
which gives the particle-density. This can now be considered as an ideal
world-model. It represents a hydrodynamical system of flow satisfying the
equation of continuity.

This system has very remarkable properties.. Each particle-observer is
equally the centre of the system. ‘To any such particle-observer, at his
epoch t the system appears to occupy the interior of an expanding sphere of
radius ct, the particles being distributed inside this sphere homogeneously
near the observer but with increasing density towards the boundary. Near
the boundary itself the particles are nearly invisible, owing to recession with
the speed of light. The density tends to infinity at the boundary. This
singularity, at time ¢ in the experience of the central observer, is the counter-
part of the singularity in his past history at t = o, the natural time-zero.
The system includes an infinite number of particles, but the total brightness
is finite. "

The system not only possesses no centre, it possesses no mean velocity.
Thus it defines no absolute frame of rest—every particle-observer may
equally consider himself as at rest relative to the system. Further, it

1 It is even possible to define what is meant by ‘uniform relative motion’ in
terms only of the temporal experiences of the observers.

SECTIONAL TRANSACTIONS.—A. 439

possesses no unique radius or unique age at any given event. If in the
experience of a central observer O, who assigns at a certain epoch of his
experience the radius ct to the system, an event occurs on another particle P,
moving with radial velocity V at the same time tf, then at this event P assigns
to the system the radius ct(1 — V?/c*)?, and ‘ age’ t(1 — V*/c?)#. Thus at
a given event the radius or age of the system depend on the observer observ-
ing this event. Particle-observers close to the boundary (in the experience
of a given observer) are to themselves close to the time-zero. In the experi-
ence of a given observer, the system always (i.e. for any t) contains particles
arbitrarily close, in their own experience, to the singularity called by
Friedmann ‘ creation.’ An observer reckoning himself as central assigns
a greater age to the system than any of the other observers in his world-wide
present, and so reckons himself as the ‘ oldest inhabitant’ of the system.
Every other observer does the same. Each observer has a definite temporal
experience (say, measured by his local density), and in observing other particles
witnesses experiences similar to those of his own past; but he can never
witness experiences similar to those of his own future.

Though each particle-observer experiences an evolutionary history, there
is no meaning to be attached to saying that the system as a whole is evolving ;
it always contains experiences arbitrarily early in time, reckoned from the
time-zero. This is markedly different from the conclusion of de Sitter in
a recent paper (M.N. June 1933) that ‘ the present structure of the universe
is only an episode of a very ephemeral character.’ It appears to me that,
although of course de Sitter is well aware that cosmic time is not the time of
experience, save locally, he has here inadvertently interpreted a section
“z = constant’ as a world-wide section in an observer’s present.

The above properties refer to the world-map made by a given observer,
from his observation of world-pictures. The world-picture he observes at
epoch t is readily specified. If 7, is the distance of a particle or nebula at the
time when it emitted light which arrives at the observer at time ¢ (a given
epoch), then its velocity V is given by

V =7,/(t — r/c)
and the density ‘ distribution ’ in the world-picture at time ¢ is given by

47 B r,2dr;
ec t(t > 27,/c)?

The world-picture necessarily has a radius } ct. The interest of the density-
formula for the world-picture is that it gives a first-order increase of density
with increasing distance. This is a necessary consequence of the expansion,
for in passing from the world-map to the world-picture we must compress
the outer portions proportionally more than the inner, as the outer portions
have expanded more than the inner during the larger time of travel of the
light. ‘This prediction is not peculiar to my model—it holds for any locally
homogeneous world-map in which the motion obeys a velocity-distance
proportionality. Observation of position-distribution of nebule made at
a given instant—i.e. counts of nebulz on photographs—should already disclose
this effect; but the inference of distance from apparent brightness must
also allow for the reduction in luminosity due to the recession of the sources.

Each particle of my ideal model is in uniform motion with respect to any
other. The question arises whether this state of motion will maintain itself
if the particles are supposed to act on one another according to any assigned
law of gravitation compatible with relativity. It can easily be shown that
the resultant gravitational field of this system of particles in motion is zero,

440 SECTIONAL TRANSACTIONS.—A.

whatever the density. For consider a system of frames of reference dis-
tributed according to the above laws, and place a particle in each instanta-
neously at rest in its own frame. The given particle O, being central with
respect to the system, in its own frame, has zero acceleration in its own
frame. Let f be the radial acceleration of a particle P, measured in the
frame of O. Transform to the frame associated with P. Let f’ be the
resulting acceleration of P, in its associated frame. ‘Then in this frame P is
central, and so f’ is zero. Hence, by the Lorentz formule for accelerations,
fis zero. The system is thus self-screened from gravitation. It goes on of
itself. It is a sort of Faraday chamber—it resembles the interior of an
electrostatic conductor. The universe as here pictured realises H. G.
Wells’s dream of a perfect gravitational shield.

This conclusion has been recently criticised by Drs. McCrea and Kermack.
These authors claim that I have left out gravitation. The above proof
seems to me to dispose of their objections. The accelerations they calculate
refer to an expanding-map universe of non-zero density, but they have not
re-mapped their system in the flat space I am using for comparison with my
model. The freedom of the ideal system from gravitation shows that the
actual system will have only a small residual gravitational field, and so
justifies the original comparison with a swarm of particles in free flight.

Much further information may be obtained by a less complete degree of
smoothing out than is implied by the reduction of the world to a hydro-
dynamical system. If we construct a statistical spatio-velocity distribution
in which the members of each pair of particles in uniform motion have
indistinguishable world-views, we find a distribution

u(Z?/X Y) dx dy dz du dv dw
c& Xi Ys

where Xap” yi, Zz Mae 20'23
oe”

and | is undetermined. Imposition of the principle of conservation of
particle-number—the condition that the object counted have a permanent
existence—determines the components of acceleration f, g, h as

payhitlgy Asana EO” 3 nx MO baka
fa-@-m 52 oe!

SGLORT.. Ani Mubbess « coct JPeneeh B= ZX
g=-O- 5 | et See ba snl eee

Y Cc
h=-@-w) 3 [1-e—ore |

Thus the accelerations are definite, apart from an undetermined constant C,
as soon as ¢) is specified, and thus there is a connection between the distribu-
tion of matter and motion and the acceleration. This is what we mean by
a law of gravitation. We notice that the accelerations vanish for the
particles for which u = x/t, v = y/t, w = 2/t. This confirms our earlier
conclusion as to the freedom of such a sub-system of particles from gravita-
tion. The mean particle-density m of this statistical distribution can be
shown to be (as judged by the observer at (0, 0, o) at his epoch 2)

; co 1 0

a ¢ 4 282 = 1 s

a (2 — Dx2/e2)? (s? — x)3 ds [a dn
(I— Sx2/or2) 2 5,

SECTIONAL TRANSACTIONS.—A. 441

which can be reduced to

co
= att ctr
n (te a Dix? /c?)? bir bias aa . G a3 arm! v(1 +)dt

It thus reproduces in broad outline, though not exactly, the hydrodynamical
density-distribution. Again, the mean radial velocity at (x, y, 2) at time ¢,
say Ur, can be shown to be

©o ©o
| a Y(n*)dn
_ Y r 3 (1—?r Jott?) 2 AY

vireg Hi a) Tor) ‘ oo
_28" ~ 1 ds [ b(4?)dn
% 1S

(s? — 1)2

~ (n= #2[c%t2) 2

where r = (x? + y? + 2)2:. The second term is always small, and so the
statistical system reproduces in broad outline the motion of the hydro-
dynamical system. But near r = 0, the second term is dominant to the
first (though itself tending to o as r > 0) and so gives a local ‘ K-effect’
when the cosmical recession is negligible.

We can, however, go much further. We can choose the distribution in
such a way that for a particle of zero velocity near the observer, the radial
acceleration (f,,.) satisfies the condition that

'r
— fro / z | 4nnr*dr
°

has a finite limit as ro. This limit will be described by a Newtonian
observer as Gm, where m is the mass he assigns to a particle of the system
and G is the Newtonian ‘ constant’ of gravitation. It is clear that (&)
must possess a singularity at € = 1, and the above relation determines the
singularity as of the form

VEO) & & (log ‘) (6 ~ 0)

It is then found that 7 possesses a very mild singularity at r ~ 0,
4rA Cr\ +3
MET 5 (Ios aa

so that the number enclosed in a sphere of radius 7 tends to 0 as r> oO.
The singularity is so mild that the mean density inside the sphere of radius
r is practically equal to the density at 7 itself. The singularity is no longer
evident at quite small distances from r = o, and here the mean mass-density
@ comes out to be

3 s} I

Ba 4nG?
This must agree with the central mass-density in the hydrodynamical model,
namely, m,B/c*t®, where m, is the mass of a nebula; whence we find

My
(7 ee a
4nm,G

442 SECTIONAL TRANSACTIONS.—A.

and from this
Gyre 16%? mG

A ee
A physical meaning can be given to these formule. Let the sphere of
radius ct in the hydrodynamical model be filled homogeneously with matter
of density equal to the central density (density near the observer). The
total mass of the ‘ extrapolated homogeneous universe ’ is then

mB et
4n(ct)? mo = 4nm,B = G

Accordingly c®t/G is a world-constant (4mm,B). Its value is about
2°4 X 1055 grams,

the mass assigned by the theory of Lemaitre to his finite universe. This is
the world-constant on which Eddington bases his theory of the proton. It
is the only independent constant occurring in the present theory, and it is
determined from observation. Since B is a constant, we must have G < ¢.
The Newtonian ‘ constant’ of gravitation should be proportional to our
present epoch, measured from the natural zero of time.

The mean density 9 of the smoothed-out universe near the observer, at
our present epoch, should be (4mG?#?)-1. Taking, for t, 2 x 10° years, this
gives p = 10-2” gram cm.—%. If we spread the estimated population of our
galaxy, 10! suns, over a cube of side equal to the distance of the Andromeda
nebula (approximately our nearest galactic neighbour), we obtain just under
0°3 X 10-27 gram cm.—*, The agreement is as good as could be expected.
This formula for the central density is numerically the same as the formula
for the mean density of the homogeneous universes of other theories.

The analysis of the statistical world-system then, when is properly
chosen, yields the remarkable property that the observer sees a mild singu-
larity in density near himself, but nowhere else ; it predicts a local density
roughly equal to that observed, and it suggests that the finite mass of the
universe in the theory of Lemaitre is an extrapolation due to the identifica-
tion of ‘ cosmic time ’ with experienced time. (The two only coincide near
the observer.)2 In that theory, of course, G is treated as a constant.

The cosmological principle employed in the above—the equivalence of
uniformly moving observers in their world-wide experiences—implies the
Lorentz formule of ‘ special ’ relativity and a very general law of gravitation.
One particular distribution, out of the permissible ones, agrees for resting
particles near the observer with Newtonian gravitation; save that now
Gat. The definition of world-systems in the usual relativistic cosmologies
is by means of a ‘ local homogeneity ’ postulate, which then requires to be
supplemented by the use of Einstein’s theory of gravitation. The cosmo-
logical principle I employ is thus very powerful. It has the advantage of
making possible the use of a flat non-expanding map for the description of
the world, and the further advantage of beginning with actual temporal
experience ; the other cosmologies require a translation of their cosmic
time into the time of experience, before yielding descriptions of phenomena
as observed. The general cosmological principle removes the necessity for
attributing any special properties to the phase of world-history we happen
to be witnessing, and it correctly predicts the leading features of this world-
history. Its bearing on world-evolution and its avoidance of any ultimate
‘ heat-death ’ for the universe cannot be treated here. The cosmological

2 As shown by McCrea and Kermack (M.N., June 1933).

SECTIONAL TRANSACTIONS.—A. 443

principle here employed differs from the homogeneity principle of rela-
tivistic cosmology in that it compares the world-wide experiences of observers
with one another, whereas the homogeneity principle compares merely their
local experiences. But the theory here outlined agrees in many quantitative
respects with the general relativity theories. It avoids, however, such
predictions as the possibility of closed light-circuits, or the prediction of the
ultimate dissolution of the universe into causally disconnected systems. All
roads lead to heaven, or, at worst, those which lead elsewhere are paved with
good intentions.

Dr. G. C. McVirr1e.—Condensations of matter in an expanding
universe.

In the expanding universe theory as originally developed by Lemaitre it
was assumed that a fair approximation to the actual universe could be
obtained by treating all the matter in the universe as if it were evenly spread
out in space so as to form a cosmic cloud. Like a gas or fluid, this cosmic
cloud is characterised by possessing a definite density and pressure at each
point. But actually the matter in the universe is not evenly spread out in
space : it occurs in the form of discrete masses, such as the spiral nebulz or
the stars, separated by regions of comparatively empty space. The question
therefore arises : Can the theory of the expanding universe be adjusted so
as to take account of the discontinuous distribution of matter in the universe ?
The answer to this question is found to be closely bound up with a number
of problems left unsolved by the theory of Lemaitre.

We have, then, to substitute for Lemaitre’s cosmic cloud a set of discrete
massive ‘ particles,’ as I shall call them, or condensations of thecosmic cloud.
Put mathematically, we have to find, by solving the equations of general
relativity, the metric of a universe occupied by an arbitrary number of
discrete particles. At the very outset it must be admitted that no one has
yet succeeded in doing this. Even if we assume that there are only two
particles in the universe, the problem proves intractable. So we try to
dodge the difficulty in the following way : we concentrate our attention on
one particle and smooth outall the others so that their material forms a cosmic
cloud of the type imagined by Lemaitre. Thus our solitary particle, instead
of being surrounded by empty space in which other particles occur here and
there, is surrounded by a cosmic cloud which fills practically the whole
universe. It turns out that the equations of general relativity are soluble
for such a case. The solution is not, however, unique: various types of
single particles surrounded by cosmic clouds are possible. One particle,
for instance, is of constant mass ; another grows at the expense of the cosmic
cloud. Moreover, the presence of the particle causes changes in the density,
pressure and state of flow of the cosmic cloud in its immediate neighbour-
hood, Further away, however, these disturbances become quite negligible,
and the universe approximates closely to the completely smoothed-out
universe of Lemaitre’s theory.

Having obtained these solutions, we can now turn to the problems
already mentioned which were left untouched by Lemaitre’s theory. The
chief of these is, perhaps, the question of the disturbance of the equilibrium
of the Einstein universe. It is probable that our own universe started to
expand from a state of equilibrium in which the cosmic cloud had constant
density everywhere and approximately zero pressure. Space was also
spherical and closed. Such a state of affairs had been known long before
Lemaitre’s theory was thought of, under the name of the Einstein universe.

444 SECTIONAL TRANSACTIONS.—A.

Its equilibrium, it is easy to show, is unstable: an appropriate impulse
will set it off either expanding or contracting. Now Lemaitre’s theory
gave no indication as to why it should begin doing the one rather than the
other. It was the inquiry whether the condensation of the cosmic cloud
in the Einstein universe into particles would start it expanding, that first
gave rise to the theory of condensations.

Unfortunately, the effects produced by the formation of particles on the
equilibrium of the Einstein universe turned out to be much more numerous
and complex than appeared at first sight. ‘The reason is that the dis-
turbance of the equilibrium is a second-order effect : to a firstapproximation
the formation of the particles has no effect whatever on the equilibrium.
This so complicates the problem mathematically that no really satisfactory
method of solution has yet been evolved. Instead attempts have been made
to decide on more or less a priori grounds which one of the many perturba-
tions produced by the particle is the predominating one from the point of
view of upsetting the equilibrium. Lemaitre, for example, has tried to show
that the presence of the particle never has any direct effect on the equili-
brium at all, on the ground that the neutral zone surrounding the particle
must always remain in equilibrium. This neutral zone is the region where
the gravitational effect of the particle is balanced by that of the cosmic
cloud. He postulates instead that expansion is due to a diminution in the
pressure of the cosmic cloud at this neutral zone. Unfortunately, it seems
doubtful whether particles do actually possess these neutral zones; and,
moreover, it cannot be proved that there must be a diminution in the pressure
at the neutral zone, supposing the latter to exist.

Another investigator, N. R. Sen, has put forward a theory that expansion
is caused by the very effect Lemaitre disbelieves in, viz. the mere presence of
particles. Sen neglects all possible counterbalancing effects such as
changes in pressure in the cosmic cloud, and shows that, under these circum-
stances, the formation of a particle in the Einstein universe is impossible
unless expansion sets in. His theory certainly seems more convincing than
Lemaitre’s, but in both cases you will see that the attempts to solve this
problem suffer from over-simplification. ‘The most we can say to-day is
that it is probable that the bubble of our universe began to burst the moment
those particles we call spiral nebulz started to condense out of the primeval
cosmic cloud.

I now pass to another question on which the theory of condensations
sheds a more certain light. It is the much-debated one of ‘ cosmic’ time.
The introduction of ‘cosmic’ time into Lemaitre’s universe is directly
attributable to the Einstein assumption which it satisfies: ‘ All points in
the universe are equivalent.’ This means, amongst other things, that all
observers in the universe can differ from one another only in position. It
then becomes possible to define a sort of time common to all of them, which
has been called ‘ cosmic’ time, since it allows of the reintroduction of the
idea of simultaneity of events. Opponents of Lemaitre’s theory of the
expanding universe, notably E. A. Milne, have spoken as if this ‘ cosmic’
time were a consequence, or a necessary ingredient, of the theory. ‘The
truth is that ‘ cosmic ’ time is an a priori simplification introduced into the
theory by investigators anxious to make the mathematics easier! 'The
position becomes clearer if we allow the universe to contain a particle of the
kind I have tried to describe. Consider an observer in the neighbourhood
of this particle. His proximity to it marks him out as different from all
other observers in the universe ; he also has atime peculiar to himself. Now
it is easy to show that Lemaitre’s theory holds for this observer to a high
degree of approximation everywhere except near the particle, with the

SECTIONAL TRANSACTIONS.—A. 445

reservation, however, that it is not ‘cosmic’ time that enters into the
formule, but the peculiar time of this observer. In other words, the so-
called ‘ cosmic ’ time of an event is nothing more than the time an observer
chooses to assign to it. It happens that in Lemaitre’s simplified theory the
observers are all so alike that their ‘ times ’ can be co-ordinated so as to give
the impression of a single ‘ cosmic’ or ‘ absolute ’ time in the universe.

In conclusion, reference should be made to a question which may have
occurred to most of you. If our universe is flying to pieces at the present
astounding rate, how is it that periodic systems in the universe such as our
Sun and his planets seem so excessively stable and permanent? The
answer is supplied by the theory of condensations, which shows that an
observer using the methods of measurements terrestrial astronomers employ,
necessarily concludes that planetary systems are fixed and unchanging in
size, whilst the system of the nebule expands. Conversely, if we imagine
a cosmical being who looked upon the system of the nebule as fixed and
unchanging, this being would see the Sun and his planets shrinking away to
nothing. Indeed, the nature of our minds is such that we instinctively
endow our immediate surroundings with an element of permanency, and
relegate to the distant nebulz the evidences of the instability of the world
in which we live.

Dr. W. H. McCrea.—The relation of Milne’s theory to general
relativity.

I wish to say something about the relation of Prof. Milne’s theory of
world structure to the general relativity theory of the expanding universe.

There is a temptation to start with a moralising homily on the history of
the subject. General relativity, through the work of Prof. de Sitter,
actually predicted the systematic recession of distant nebulez. Data derived
subsequently by Hubble and others gradually accumulated to provide
observational support for this apparent recession. Result: one up for
general relativity! The next development was that Friedmann, Lemaitre
and others investigated non-static universes and arrived at the concept of
the expanding universe—still using general relativity theory. The result
was to make a systematic recession, or at any rate a systematic motion, of
distant nebulze seem inevitable. At the same time an explanation was
given of the particular form of Hubble’s empirical law for the observed
variation of velocity of recession with distance. I should say, however, that
the inevitableness of the phenomenon was apparent only to the initiated.
For it was all very sophisticated and bound up with the difficult ideas of
the curvature of space-time, and the mysterious cosmical constant A.

In passing one might comment on the prevalent fashion of giving \ a name.
Sir Arthur Eddington himself calls it ‘ Gulliver.’ But I fancy he ought to
call it ‘Mrs. Harris.’ For this friend of Sir Arthur’s gets the credit for
marvellous doings—as, in fact, he has just been telling us. Nevertheless,
does she really exist? Einstein and de Sitter have been irreverent enough
to suggest that she might be a zero quantity !

To pursue our history, however, we next come to an unexpected move.
Prof. Milne suggested an explanation of the scattering of the galaxies, which
he has just explained to us, which makes the whole thing seem intuitive in
an absurdly simple way. As Milne himself has remarked, had this explana-
tion occurred to anyone before the advent of general relativity, it would
probably have been immediately hailed as the obvious one. At this point
someone is doubtless heard to murmur: ‘ What a pity Prof. Milne did not
arrive on the scene fifteen years sooner and save us all this trouble of trying

446 SECTIONAL TRANSACTIONS—A.

to fathom the general relativity theory!’ It is, however, my purpose to-day
to show that it is fortunate that things turned out as they did. For I believe
that general relativity provides the best mathematical method for dealing
with Milne’s phenomenon, and I am thankful that he had patience to wait
till this method had been discovered before giving us his own theory, which
otherwise might have been taken to be the last word. In short, general
relativity was all the time studying the simple phenomenon contemplated
by Milne, but somehow never realised the fact! Only general relativity
goes somewhat further, and takes account of the influence of gravitation,
and also of the influence of the cosmical constant—that is, if Mrs. Harris
really does interfere.

The results I am about to summarise were arrived at in collaboration
with Dr. Kermack of Edinburgh.1.We discovered afterwards that
Prof. H. P. Robertson? of Princeton had simultaneously arrived at
identical conclusions.

Milne has stated his postulates. He wants a universe in which every
observer, or every one of a particular class of observers, sees the same
sequence of world-pictures. To fix the ideas we take the simplest solution
of his problem, which is provided by his ‘ hydrodynamic’ solution. This
represents a set of particles all setting out from a single point with uniform
velocities relative to each other. If the velocities are distributed from zero
up to the velocity of light, in the particular manner calculated by Milne, then
each observer will see himself for all time as the centre of the whole bunch.
Any observer at any instant will describe the universe by associating with
each point the velocity and density of particles found by Milne.

Now, in arriving at these results, Milne chooses to map his events in
a four-dimensional Minkowski space. He is quite entitled to do this.
For his space-time is introduced from a different standpoint from space-
time in general relativity. He chooses his space-time first, and then seeks
the law of gravitation for the actual universe which will reproduce the
observed state of affairs. General relativity, on the other hand, puts the
law of gravitation first, and then seeks the form of space-time for the actual
universe, again so that the observed state of affairs is reproduced. ‘These
two distinct methods of approach must always be possible.

Now there is one case in which the space-time of general relativity reduces
to the space of Milne’s map. That is when we neglect the effect of gravity.
In general relativity, however, the result of neglecting gravity is equivalent
to flattening out curved space-time. But the general relativity theory of
the expanding universe admits a whole class of curved spaces. What we
can show then is that, 7f we choose the right one of these expanding universes,
with \ =o, and flatten it out, i.e. neglect the gravitational interaction of the
particles, then we get exactly Milne’s universe described above. We get
identically the same velocity and identically the same density associated with
a given point at a given time. So this particular general relativity solution
enjoys all the virtues of Milne’s solution, in particular its simplicity and its
explanation of why the universe appears to be expanding and not contracting.

This is very important, for, as I have already mentioned, it means that the
mysterious expansion of the universe is nothing more or less than the simple
kinematical scattering of Milne’s theory, allowing, of course, in the general
case for the influence on the scattering of the gravitational interaction of the
particles. General relativity has, so to speak, invented a way of doing sums,
but had to wait for Prof. Milne to come along and tell us what the sums

1 W. O. Kermack and W. H. McCrea, M.N., R.A.S., 98, 519-529 (1933). 7
2 H. P. Robertson, Zeit. fiir A strophysik, 6, in press (1933).

SECTIONAL TRANSACTIONS.—A. 447

were all about. But I think I still prefer the general relativity way of
doing the sums.

Two qualifications must be appended to this result. First, it holds, as
stated, onlyifA =o. If A +0, we get a scattering of galaxies dependent
on the value of \, and if we take the simplest case and neglect the gravita-
tional interaction of the matter, we get de Sitter’s universe. If further we
make A > 0, we find that the velocity of scattering > o also. So this kind
of scattering is physically different from Milne’s.

Second, I suspect Prof. Milne might object to my saying that his calcula-
tion neglects gravitation. For he would contend, if I understand him
aright, that large-scale gravitation is just such as to reproduce this particular
kind of scattering found by him, and no other. I would answer that
I believe it possible to show that his theory certainly does not take account
of the detailed interaction of pairs of particles. As regards the large-scale
effect it is, as a matter of fact, contrary to the strict spirit of general relativity
to’ distinguish kinematical and gravitational effects, for the method of
general relativity is to turn all dynamics into kinematics. Consequently,
his objection would be quite consonant with a proper relativistic outlook.
Nevertheless, I think that the language we have been employing does help
in the physical understanding of the phenomena.

This latter point seems to me largely one of epistemology. The point of
real importance is, what happens to Milne’s theory when the detailed
gravitational interaction of the particles is allowed for. Actually general
relativity provides what is, within its own field of postulates, a complete
solution of the problem which Milne sets out to solve, taking full account of
gravitation. For, in starting with the invariance of the element of interval,
general relativity ensures the constancy of the velocity of light. Thus the
first of Milne’s requirements ts satisfied.

Then, further, the expanding universes of general relativity are based on
the requirements of isotropy and homogeneity. These ensure that an
observer at rest in the spatial co-ordinates sees the world as isotropic, i.e.
as spherically symmetrical about himself, and that all such observers have
the same view of the world at the same cosmic instant.? If, then, these
observers be taken as Milne’s fundamental class, they satisfy precisely the
requirement he makes that each should have exactly the same sequence of world
views. All the general relativity solutions satisfying these requirements are
known.4

It is important to recall, as I was recently reminded by a conversation
with M. l’Abbé Lemaitre and Dr. McVittie, that these solutions are
independent, in the first place, of Einstein’s law of gravitation, and are
derived only from the invariance of the element of interval. The law of
gravitation merely gives the value of the density-momentum tensor asso-
ciated with each solution. A different law of gravitation might lead to
a different value of the tensor associated with any particular universe, but
it could not alter the whole class of universes satisfying the fundamental
requirements.

If, then, Prof. Milne ultimately arrives at conclusions different from
those of general relativity, it must be either by denying the invariance of
the element of interval, or else by something equivalent to using the same

8 Milne in his original paper, Zeit. fiiy A strophysik, 6 (1933), I-99, criticised the
concept of cosmic time, but it is pointed out by Kermack and McCrea, and by
Robertson (/.c.), that cosmic time is implicit in his own theory. There it appears
as the proper time of any one of his fundamental particlessince its passage through
the space-time origin.

4 H. P. Robertson, Proc. Nat. Acad.

448 SECTIONAL TRANSACTIONS.—A.

space-times as general relativity, but with a law of gravitation different from
Einstein’s. Otherwise the two theories will differ onlyinmethod. I believe,
however, that all Prof. Milne’s results so far derived are included amongst
those of general relativity.

M. VAbbé Lemairre——The cosmical significance of the clusters
of nebula.

The theory of the expanding universe seems to indicate that the universe
is not older than a few thousand million years, i.e. not much older than the
earth. On the other hand, the generally accepted theory of evolution of
the stars with transformation of matter into radiation needs a period one
thousand times greater. The conflict between these two theories could be
solved if the mechanics of the expanding universe provided some means of
substituting for the slow evolution of the stars a rapid evolution which would
explain the formation of stars, nebulz and clusters of nebulz in a period of
a few thousand million years.

Progress of the theory of the behaviour of local condensations in the
expanding universe show, at least in the case of spherical symmetry, that
each concentric shell of matter would obey the same law as a universe. But
they need not all follow the law of the same universe. ‘The universe at
large, starting with a very small radius, would expand with a diminishing
velocity, slow down to pass over the equilibrium radius, and then expand
again for ever with an accelerated velocity. On the contrary, interior regions
of a somewhat greater density might fail to attain equilibrium and contract,
collapsing towards their centre, while the universe at large continues to
expand. This is a new typical case of instability, very small differences in
the initial density being followed in the long run by extremely great
modification of the motion.

This property of the universe seems to be able to explain the rapid forma-
tion of nebula. But when we try to follow up this idea in more detail, we
meet a very essential difficulty. For a condensation of a thousand million
suns, as seems required to build up a normal nebula, the equilibrium radius
would be about 80,000 light-years, although the radius of a typical elliptical
nebula is not much greater than one thousand light-years. Now, although
the condensation must first collapse, it will evidently rebound and cannot
adjust itself to a permanent radius of one thousand light-years unless some
vigorous stopping process takes place in the course of the contraction. The
energy which must be taken off is really enormous, and at first sight it seems
difficult to understand what mechanism would account for it. Actual
computation shows that the loss of energy must be equal to the total heat
content of the stars contained in the nebula. This gives the solution of the
puzzle. The stopping process, which prevents the nebule from rebounding
too far, is the formation of the stars. Before the contraction the matter was
formed of gas, dust or meteorites. When the whole mass collapses towards
its centre, powerful encounters take place ; the diffuse matter agglutinates
suddenly into stars and the energy turned into heat by this process explains
together how the new-born stars have the necessary heat to start on the sub-
atomic processes which provide their continuous output of light, and why
the nebulz can adjust themselves to their present radius.

Stars and nebule are born together in an astronomical instant. Sudden
evolution of the universe takes the place of slow evolution of the stars, with
the same net result, even with equipartition of energy among the stars.
The shape of the nebula depends on its initial moment of momentum,
elliptical nebulz or spiral nebulze being born together. Here evolution

SECTIONAL TRANSACTIONS .—A. 449

theory must give way to a statistical theory in order to compute the proba-
bility of the momentum responsible for the rotation of the nebula, and there-
fore of its more or less elongated shape. The total mass of the nebula is also
a matter of chance. Some mass might be more probable, and therefore
more frequent, than another, but nebulze of any mass might exist, and it is
no longer astonishing that we are living in a fairly large nebula.

We have used so far in these considerations the two possible types of
motions which must most probably occur—the ever-expanding type of
motion for the universe at large, the collapsing type for the nebula itself.
Between these two types of motion there is an intermediate type, in which
the motion tends to the equilibrium radius without further contraction or
expansion. Although this event must be comparatively less probable it
must some time occur, and we have to investigate what would happen in
this case. The region under investigation would finally form a part of an
Einstein universe ; it would be in equilibrium, but in unstable equilibrium.
As the time-scale is short and the time of disintegration is rather long, at
least for such a region of large size, we might expect it to survive. We may
hope that the equilibrium would remain in the mean, but not for every small
part of the region, so that local condensations must occur and form ordinary
nebulz by the mechanism we have just described, although the assembly of
these nebulz would neither contract nor expand. The result will be
a cluster of nebulz.

It is possible to test this hypothesis on the origin of the clusters of nebulz.
If it is true, all clusters must have the same density, and this density must be
adjusted to the cosmical constant, as in an Einstein universe. The value of
the theoretical density of a cluster can therefore be computed from Hubble’s
ratio of the distance to the spectroscopic velocity of the nebule. ‘The data
are not yet very numerous, but computation for eight clusters, according to
Hubble’s data, gives concordant results in good agreement with previous
estimates of the mass of a nebula computed from the spectroscopic rotation
or the absolute luminosity. If this hypothesis can be definitely tested it
would practically determine the value of the density of matter in the universe.
The result is really not new; it simply confirms Hubble’s estimates, but
although Hubble’s determination was thought to be subject to an uncer-
tainty of perhaps a factor of one hundred, it would practically turn out to be
exact.

Prof. W. DE Sitrer.—A critical discussion of certain solutions.

450 SECTIONAL TRANSACTIONS.—A.

Mr. C. H. H. FranKLin.—Demonstration of the orbits of a spherically free
pendulum (12.30).

A pendulum which is free to swing over a segment of a sphere has possible
paths which vary from a rotation resembling an engine governor ball to the
swing of a simple pendulum in a plane ; which plane appears to rotate very
slowly, but really indicates the rotation of the earth beneath it (the Foucault
pendulum effect).

The intermediate orbits between the circular and the linear paths are
ellipses, which latter precess at a rate dependent on the maximum and
minimum angles of the pendulum and corresponding ratio of major and
minor elliptical axes. This precession of the ellipse produces a pattern
which corresponds to that produced by two opposed rotations having
a ratio near unity (such as 100: 101, with appropriate amplitude) ; which
may be drawn by harmonograph, etc. Virtually, the pendulum behaves as
if it had two frequencies ; which is in agreement with the facts that the
effective length of a pendulum swinging in a circle is cos « L, where « is the
angle of the swing maintained and L is the length of the pendulum, and in
tracing a single ellipse a maximum and minimum angle and corresponding
minimum and maximum effective length are reached twice.

It will be seen that the greater the angle reached, the greater the variation
of effective length of the pendulum, and it is found that the rate of precession
increases rapidly as the angle increases.

Also, if the ratio of major and minor axes of the ellipse is high (which, in
the limit, becoming ©, means the pendulum swinging in a plane), the rate
of precession is small, in the limiting case becoming o.

And as the ratio of the major and minor axes approaches 1, the rate of
precession becomes a maximum for the angles involved.

When the pendulum is capable of swinging over a hemisphere, and is
oriented to maximum and minimum angles of 180° and 90° (which is a 2: 1
ellipse), the vertical projection of the orbit becomes a 5-loop figure, corre-
sponding to the 3:2 figure with opposed rotations as produced by the
twin-elliptic pendulum, etc., with appropriate amplitudes.

If the pendulum is taken above the equator of its sphere of rotation,
a further reduction in the number of possible loops in the orbit appears to
occur, but this is deceptive, because there is now a loop above and a loop
below the equator, which correspond. Also the figuring can now be
dependent on velocity, the angle of initial swing not necessarily deciding
the pattern, as in small spherical angle orbits.

If the speed of projection of the pendulum is high, the orbit tends to
become a great circle on its sphere, which orbit precesses in the same
direction as would be the case with a gyroscope.

It follows that if the orbit is nearly in the horizontal plane, precession
occurs rapidly for any given mean velocity of pendulum ; and as approach-
ing the vertical plane precession becomes relatively slow, it should, in the
limit, become zero again when the pendulum completely rotates in a vertical
plane.

The rate of precession for any given inclination of great circle orbit now
depends on the velocity of the pendulum bob, in the same way that the rate
of precession of an unbalanced gyroscope at a given slope depends on the
velocity of rotation.

AFTERNOON.
Visit to University College, Nottingham.

SECTIONAL TRANSACTIONS .—A, Af. 451

Wednesday, September 13.
Prof. Dayton C. MILLer.—The ether-drift experiment, and the absolute
motion of the solar system and the orbital'motion of the earth (10.0).

Major A. G. Cuurcu, D.S.O.—Recent developments in television (10.30).
Visit to Messrs. Taylor, Taylor and Hobson’s Optical Works.

PAPERS OF INTEREST TO THOSE ENGAGED IN
TECHNICAL PHYSICS (Af).

Friday, September 8.
Mr. H. Warren.—The talking film in industry (11.0).

Mr. L. J. Davies.—Hot cathode gas discharge tubes (11.40).
A description of various types of industrial hot cathode discharge tubes

such as ‘ Thyratrons,’ gas discharge lamps, etc., with particular reference to
the design of cathodes for various applications.

Mr. J. T. RANDALL.—Spectroscopy in the service of industry (12.20).

Monday, September 11.
Dr. C. H. Spiers.—Some physical problems of leather manufacture (12.0).

Mr. H. Braptey.—(1) A study of water absorption and vapour absorption
by leather and other shoe materials, with a note on the importance of
these processes in shoe manufacture.

Solutions of the diffusion equation with various boundary conditions
and their application to experiments with leathers immersed in water
or exposed to various atmospheric humidities. Absorption isotherms
—absorption hysteresis—air permeability—porosity—the relation of these
properties to the absorption and adsorption processes. Absorbed moisture
and thermal conductivity.

The importance of this work in modern shoe factory development.

(2) The testing of flexible sheet materials by hydrostatic or pneumatic
pressure.

A discussion of the method of test as applied to paper, textile fabrics,
metal foil and sheet, leather, rubber, and a presentation of experimental
results and calculations bearing on the theory of the subject.

Tuesday, September 12.
Discussion on High voltages and high vacua (10.0) :-—

Mr. C. R. BurcH.—On the design and operation of oil condensation
pumps.

The operation of a condensation pump on low vapour pressure organic

fluids, such as vacuum distillates from mineral oils, is influenced by con-

siderations which do not arise when mercury is used as working fluid.

452 SECTIONAL TRANSACTIONS.—At.

The necessity for avoiding ‘ cracking ’ restricts the maximum temperature
and the pressure of the vapour stream, and the fact that the oil wets the
pump surfaces prevents the use of small clearances between cowl and
condensing tube. It is therefore not possible to use such pumps against
a high fore vacuum pressure. Consideration of the properties of a pump
as a vacuum fractionating column shows that the extent to which the final
vacuum is influenced by impurities of small amount (1 in 10°) may depend
markedly on whether the condensing surface is water-cooled or not, even
though a water-cooled trap is placed between the pump and the fine system.
Similar considerations show that it is not advisable to cool the fore vacuum
pipe. It is necessary to constrict the pump mouth above the cowl, to con-
dense the ‘ reverse jet’? due to multiple collisions : this theoretical point
appears to have escaped notice so long as mercury was the only working
fluid used. 5

Contamination of the working fluid by mercury has been found to be an
insidious cause of trouble, so that it is desirable to modify one’s technique of
performing various experiments—e.g. speed measurements—-so as to avoid
the use of mercury. It is in any case undesirable to use McLeod gauges
in oil condensation pump systems, as the readings are no criterion that the
pump is working properly. It is necessary to bake out an ionisation gauge
before an oil condensation pump will produce a really good vacuum in it ;
it is difficult to say how much this is a question of outgassing the gauge,
and how much a question of indirect ‘ conditioning ’ of the pump.

Mr. B. L. Goopier and Mr. A. BEETLESTONE.—The production of
high voltages.

The paper deals with the production of small powers at high voltages for
general laboratory purposes, and particularly for use in connection with
high vacuum equipment.

Such high voltages may be either unidirectional or alternating. Uni-
directional voltages may be continuous pulsating or impulsive ; alternating
voltages may be damped or undamped and of high or low frequency. ‘The
paper outlines the characteristics and methods of producing these various
types of high voltage, and gives details of equipment available.

Dr. T. E. ALLIBonE.—High voltage vacuum tubes.

This paper deals with the construction of vacuum apparatus suitable for
operation at high voltages, such as electron and positive ion discharge tubes,
oscillographs, thermionic rectifiers, three electrode valves, and X-ray tubes.

The apparatus described is primarily intended to be continuously
evacuated, and demountability is one of its special features, so facilitating
experimental work and the replacement of defective parts. Even for high
voltage experiments the oil diffusion pumps are operated without the use
of liquid air traps, thus allowing big pumping speeds to be attained.
Examples of high voltage vacuum tube pumping systems are given.

Dr. J. D. Cockcrort.—A high voltage D.C. generator.

In order to produce high speed atomic particles for work on nuclear
transformations, it has been necessary to develop sources of steady potential
of seven or eight hundred kilovolts, capable of producing currents of several
milliamperes, and to develop vacuum tubes to withstand these potentials.
Transformers capable of providing these potentials are bulky and expensive,
and difficulties arise in applying such transformers directly to a chain: of
rectifiers. A voltage multiplier has therefore been devised which will

SECTIONAL TRANSACTIONS.—At. 453

multiply a transformer potential by a factor whose magnitude depends
simply on the number of condensers and rectifiers employed, the final output
being a potential hav.ng a ripple of only a few per cent. A tower of glass
cylinders evacuated by an oil diffusion pump constitutes the four rectifying
units employed in the 700,000-volt generator at the Cavendish Laboratory.

The general principles underlying the design of vacuum tubes for these
voltages are discussed.

Dr. R. J. vAN DE Graarr.—Engineering possibilities of electrostatics
with vacuum insulation,

An electrostatic force requires merely the presence of electric charges,
whereas an electromagnetic force requires in addition the continuous
motion of the charge. This movement of the large charges necessary for
electromagnetic force inevitably causes certain difficulties, fundamentally
limiting the efficiency, compactness and lightness of electromagnetic
machinery. These difficulties can be eliminated by the use of electro-
static rather than the usual electromagnetic force, provided that a suitable
insulating medium is available for the high voltages and gradients required.

Certain experimental evidence supports the belief that high vacuum has
the desired insulating properties, and that it can be suitably produced for
large electrostatic machinery. Assuming that the above evidence is correct
in showing that vacuum insulation can be made to prevent electrical break-
down, designs for electrostatic generators and motors are given, with cal-
culations showing that they would have a greater power output per unit
of size and weight, with energy losses many times less than present electro-
magnetic machinery.

Prof. W. Cramp.—Axial spin of a magnetic field.

At the end of the year 1831 Faraday carried out a series of experiments
upon the effects of the relative motion of a conductor and a magnetic field.
He concluded that the moving conductor was the seat of the e.m.f., and that
there was ‘a singular independence of the magnetic field and the bar in
which it resides.’ Subsequent writers, however, are at variance as regards
the relationship between a permanent bar magnet and its field, some taking
the view that when such a magnet is given an axial spin its field moves with
it, and others that the field is structureless, and that rest or motion as applied
to it are meaningless.

In an attempt to resolve this problem, the author has carried out a long
series of experiments, not only upon conductors and magnets, but also upon
conductors and solenoids, The results are in some instances unexpected,
but in general lead to the conclusion that a spinning magnet and a spinning
solenoid behave in an exactly similar manner, and that in no circum-
stances can the magnetic field of a cylindrical bar magnet be regarded as
rotating with the bar in an axial spin. Further, it appears to be impossible
to cause a turning moment about the axis of such a magnet by means of
current-carrying conductors lying in its magnetic field. In short, while
the mechanical effects upon conductors carrying currents and lying in a field
leave little doubt as to a connection between the current and the material
of the conductor, there is no evidence of a similar attachment between
a magnet and its field.

AFTERNOON.

Visit to University College, Nottingham. Meeting in Physics Depart-
ment, with papers by members of the department.

454 SECTIONAL TRANSACTIONS.—aAt, A*.

Wednesday, September 13.
Visit to Messrs. Taylor, Taylor and Hobson’s Optical Works, Leicester.

DEPARTMENT OF MATHEMATICS (A*).

Thursday, September 7.

Dr. E. H. Lrnroot.—On the dissection of large numbers (11.0).

Much of the recent work in the theory of numbers has been concerned
with the representation of a positive integer as a sum of integers of specified
type. The Waring and Goldbach problem: are of course the outstanding
examples, but there are several others of a less formidable nature which are
of considerable interest. One of these is the representation of a number
as the sum of kth power-free numbers (numbers not containing any kth
power greater than 1 as a factor) ; this problem yields up its main results
to purely arithmetical arguments, though there are some cases in which
the Winogradoff method, based on the Farey dissection of an interval, is
needed to obtain the sharpest error terms.

The theorems discussed are all of purely arithmetical nature. The
following are two examples. (1) We ask whether every sufficiently large
number can be diss cted into, say, a square and a quadratfrei number.
Estermann showed that it can, and gave an asymptotic formula for the
number of dissections. We then ask whether the dissection can still be
made if the two parts are restricted to be ‘ almost in a given ratio ’—that
is to say, whether for all 7 greater than some number mo the equation

n = m? + q (q = quadratfrei)
always has a solution satisfying
m? = dyn + O(n 8); g =Agn + O(n" 4),
where Aj, A» >O; Ay +A, =1; 0o<B<1. It will be shown that such is
the case provided B <i, and an asymptotic formula for the number of
representations will be given.

(2) A similar theorem holds for dissections into two quadratfrei
numbers almost in a given ratio; in this case the asymptotic formula is
valid and significant for all values of B in the range (0, 1).

Dr. L. S. Bosanquet.—The absolute summability of Fourier series (11.30).

A series Lay is said to be absolutely summable (A) if Lanx” converges to
f(x) for o<x<1 and f(x*) is of bounded variation in (o, 1). The sum is

then _ lim of (*)-

i=
The Pasties series of an even function 9(¢), integrable L, is absolutely
summable (A) to zero at the point t = 0 if, for example,

(1) @a(t)/t is integrable L in (0, yn) for some « > 0, or
(2) 9.(t) is of bounded variation in (0, 1) ie some « >0, and 9,(t) > 0
as t-> o, where

t

Qa(t) = “| (t — u)*-1 o(u)du, «>0,
°

Pa(t) = et).

The second condition includes the first. Special cases were given” by
J. M. Whittaker and B. N. Prasad. j

SECTIONAL TRANSACTIONS.—A*. 455

Lan is said to be absolutely summable (C,«) if &| S% —S%_, | is con-
vergent, where S% is the «-th Cesaro mean of Sx =ad.+ ...+4n,

The sum is then = S%, and the series is also absolutely summable (A).

By employing absolute summability (C) more precise results may be
obtained for Fourier series. In particular, (2) is necessary and sufficient
for absolute summability (C) of an unspecified order.

Dr. A. C. OrrorD.—Fourier and Hankel transforms (12.0).

Two functions f(x) and F(x) are said to be Fourier cosine transforms of
one another when they are connected by the formule

(x) F(x) = (2) "cos xuf(u) du,
°
-00

(2) f(x) = (2) ‘| cos xuF(u) du,
°

where the integrals may be either integrals of the classical kind or integrals
in some generalised sense.

More generally f(x) and F(x) are Hankel transforms of one another when
they are connected by the relations

F(x) = [vou Pema
fe}

ie | vowl (ou) F(u) du,
(eo)

where Jy(z) is Bessel’s function and R(v) > —}4. Whenv = — i, } these
reduce to the cosine and sine transforms respectively.

For simplicity we will first state the results for the special case of the cosine
transform. We say that f(x) belongs to the class H if

W
(H) - \| (: — 4) cos xu f(u) du| < M,
a w
for all w and x, M being an absolute constant. This condition will obviously
be satisfied when / (x) is absolutely integrable in (0, cc). We show that every
function of H has a cosine transform which is bounded. More precisely
we prove that, when f(x) belongs to H, the integral (1) is summable
(C, 1) almost everywhere to F(x) and (2) is summable (C, 2) almost
everywhere to f(x).

Now consider the converse problem, Let F(x) be a bounded function
and let it be such that the integral

(2) (Pse ra,
°

TT

which is known to exist in the (C, 1) sense, is uniformly summable (C, 1)
to an indefinite integral. So that we can almost always write

: co.
(x) = (2)8 f \, sin (u) du.

456 SECTIONAL TRANSACTIONS.—A*.

When this is the case we say that F(x) belongs to the class B* and we take
4(x) to be its cosine transform.

We can now state our results as follows :

(i) A function of H has a cosine transform in ‘De.

(ii), A function of B* has a cosine transform in H.

Suppose now that f(x) belongs to’ H and is bounded. Then we show that
its transform F(x) belongs to H. Hence there is a class HB, consisting of
all the bounded functions which belong to H, which is such that the cosine
transform of a function of HB belongs also to HB.

These results hold also for Hankel transforms. We say that f(x) belongs
to Hy if

Ww
[f(s =) won syle) fd de | <M
° wW

for allx and w. There is a corresponding definition of the class By*, and
there is a symmetrical class HyB as in the case of the cosine transform.

We can now apply the analysis of Hardy and Titchmarsh (Quart. Fournal,
Ox. Series, i, pp. 196-231) to find the class of all the functions of HyB

which are their own Hankel transforms. We obtain, in fact, the following
result.
A necessary and sufficient condition that a function f(x) of HyB should be

its own Hankel transform is that it should be of the form
co
I ’
f(s) = = x(t) 2 -4-i di,
—co

where the integral is summable (C, 1) almost everywhere, and x(2) is such
that

io
la m8
| [6 laa) x(t) x dt| < M,

x(t) ti finctl

: = tion of t.

st FRG eg ea a) even function o

Putting v = — 4, we get the necessary and sufficient condition for a

function to be its own cosine transform.
It is possible to extend the theory for cosine transforms to functions of
several variables.

Friday, September 8.

Mr. W. V. D. Hopce.— Abelian integrals attached to algebraic varieties (11.0).

G. Mannoury has shown how a complex projective plane can be repre-
sented as a closed four-dimensional locus in Euclidean space in such a way
that many projective properties of the plane can be represented as metrical
properties of the locus. His method can be extended to algebraic varieties
of any number of dimensions, and in this way we can obtain a representation

of the Riemannian manifold of an algebraic variety of m dimensions as a
locus of 2m dimensions in a Euclidean space. The differential form

which gives the element of length on this locus has many interesting pro-

SECTIONAL TRANSACTIONS.—A*. 457

perties, when considered according to the general theory of quadratic
differential forms.

It can be shown that the anti-symmetric tensors B(i, . . . ip) which satisfy
the equations

prt . . . . .
D> ( = 1)r-t Bay, + + 6 lp-rly+1 . .. ptr, Zr) =o
r7=1

PIBGNs 24. By 1% 5) S10

and which are finite everywhere on the manifold are all linear combinations
with constant coefficients of Rp independent tensors, where Ry» is the p-th
Betti number of the manifold, and that the integrals formed from these

| Be, es tp) dx... dx'e,

which are called harmonic integrals, cannot be without periods. It is usual

to take 21, . . . , 2” as the complex parameters on the variety, and writing
at = or inet,
we take x1, ..., x?” as the real parameters on the manifold. Then

among the harmonic integrals are included the real and imaginary parts of
the Abelian integrals (of the first kind)

| PG 2. tp) dz... dz'p

attached to the variety. A study of the harmonic integrals leads to many
new and interesting properties of the Abelian integrals, some of which are
described.

Dr. D. W. Bassace.—Cremona transformations (11.30).

If V; is a rational k-dimensional locus in space S,, of m dimensions,
which can be birationally projected from each of two [n — k — 1]’s, Il, and
II,, then we can use V;, to set up a Cremona (1, 1) correspondence between
two [R]’s, S,% and S,, taken in general position in S,, two points,
P,, Ps, of these spaces corresponding when the [7 — k]’s, which join II, to
P, and Il, to P, respectively, meet V, in the same point P. Segre has
obtained Cremona transformations of ordinary space arising by two pro-
jections in this way from rational scrolls of planes, and Marletta has given
a simple method by which any Cremona transformation T can be inter-
preted in terms of two projections of a locus of higher space; but apart
from the work of these, little has been done by hyperspatial methods.

In the present paper these methods are used to give a simple interpretation
and classification of the so-called rational and elliptic Cremona trans-
formations of ordinary space S3, the genus of a Cremona transformation
of S; being defined with Loria as the genus of the general plane section
of a general member of one of the two homaloidal systems of the trans-
formation, a number which is an invariant of the transformation. The
question of resolving a Cremona transformation T into the product of several
simpler transformations is often simplified when T is given a hyperspatial
interpretation ; for example, the known fact that all the rational Cremona
transformations of 3 can be built up from quadro-quadric Cremona trans-
formations is rendered practically self-evident.

Dr. P. Du Vat.— Multiple planes (11.50).

A multiple plane of n sheets may be defined as the projective image of
a rational involution of sets of m points on an algebraic surface. It has a
R

458 SECTIONAL TRANSACTIONS.—A*.

branch curve, locus of images of sets in which two points coincide, which
has a cusp for each set in which three points coincide, and a node for each
set in which four points coincide by pairs. The arithmetic genus of a
multiple plane is given by

Dart es (8. 1) (Remi2): the ex — 8

where 7 is the number of sheets, 28 the order of the branch curve, 3x the
number of its cusps, and 48 that of its nodes.

Double planes form a class of surfaces somewhat analogous to hyper-
elliptic curves, in having a rational involution of pairs of points; the
analogous property holds, that the canonical system belongs to the
involution.

A double plane can have as branch curve any curve of even order, but for
n > 2 the branch curve must have some cusps and (for m > 3) nodes in order
that the surface may exist at all.

A topological condition (of presence and arrangement of cusps and
nodes) on the branch curve for the existence of a multiple plane exists but
is not easy to apply.

By comparatively simple algebraic methods, however, it is possible to
enumerate all the cases that can arise with branch curves of reasonably
low order.

Mr. J. H. C. WuITEHEAD.—On the calculus of variations in the large: loct
of conjugate points (12.10).
Let Vn be an analytic manifold with a positive Finsler metric
ds? = gij (x, dx) dx' dx,

the g’s being homogeneous of degree zero. By minimising the integral
fds we obtain a family of extremals. Each extremal through a given
point O may be regarded as the image, possibly the singular image, of a
straight line through a point (0) in a Euclidean space, En. As when
setting up a normal co-ordinate system one can vary the straight line through
(0) and so represent V» as the image of Ey in a single-valued analytic
transformation E, > Vn. The points in Ey, at which this transformation
fails to be locally (1-1) correspond to the points in Vn, which are conjugate
to O. They constitute an analytic complex Ky... The object of this
paper is to study the complex Ky, and the nature of the transformation
En — Vn near points on Ky.

Mr. H. G. Green.—Pascal’s Theorem in n dimensions (12.30).

The paper describes the work of the author and a colleague on an appli-
cation, which is still in progress, of the theory of involutions of restriction
1 to a generalised Pascal figure. The methods used are a development
from those of Pomey, which give opportunity for a closer discussion of
special cases. The methods of the extension are illustrated by details of
the figure in three dimensions, in which the place of the two dimensional
Pascal line is taken by a series of closed networks of lines and the pro-
jective connection with the plane figure is established. In the general
n dimensional case it is shown that it is only for special forms of m that
a symmetric figure can be constructed, and that the networks-are then of
two types, open and closed.

SECTIONAL TRANSACTIONS.—A*, At. 459

Tuesday, September 12.

Joint Discussion with Section J (Psychology, g.v.) on The validity and
value of methods of correlation (10.0).

DEPARTMENT OF COSMICAL PHYSICS (At).

Thursday, September 7.

Dr. W. H. McCrea.—Problems of the solar chromosphere and corona (11.0).

Survey of recent work, particularly Rosseland’s theory depending on the
ejection of fast electrons by the sun. The possibility of such ejection.

Mr. W. M. H. Greaves.—The observation of stellar colour temperatures
(11.25).

Dr. G. C. McVitt1r.—Non-static solutions, with singularities, of Einstein’s
gravitational equations (11.50).

Generalisation of Schwarzschild’s solution for a mass-particle, in the ex-
panding universe theory. The choice of co-ordinate systems. The dis-
tribution of matter outside the mass-particle. The cosmical constant.

Dr. W. J. S. Lockyer.—Periodic changes in two Be-type spectra (12.15).

One of the researches which is being carried out at the Norman Lockyer
Observatory at Sidmouth is the spectroscopic study of some of the brighter
stars of the Be type—i.e. those stars which exhibit bright hydrogen lines in
their spectra. This work was commenced in the year 1923, and has been
continually pursued since then.

The Sidmouth research has been chiefly confined to the determination
of the changes in the relative intensities of the bright components of each
of the hydrogen lines, for each hydrogen line consists of a broad absorption
band on which are superimposed two bright lines, separated by a strong sharp
absorption line. These intensity differences are determined by two methods
—one by eye-estimates under a small magnifying power ( x 2), and the other
by a wedge-micrometer. The results are here given for two stars only, to
illustrate the methods. The first deals with the star 7 Persei, of magnitude
4°19, for which a period of change of 126°8 days is deduced. The character
and intensities of several absorption lines in the spectrum are also discussed.
The second star, y Cassiopeiz (mag. 2:o1), is a star the spectrum of which
has never before been detected to exhibit any change. Distinct variations
are here indicated, and a probable variation of about four years in length
is clearly indicated.

Mr. A. D. Tuackeray.—The measurement of line intensities in stellar
spectra (12.40).

Stellar spectra for the measurement of line intensities have to be
standardised photometrically in order to relate the photographic density to
the intensity of the original incident light. Many photographic errors may
arise due to differences in stellar and standard exposures, and especially to

460 SECTIONAL TRANSACTIONS.—Af.

Eberhard effect. The microphotometer will introduce further errors, but
the largest errors of all probably arise in the final process of reducing the
microphotometer tracings, the difficulties of drawing in the continuous
background and eliminating blends being often insuperable. With spectro-
graphs of ordinary dispersion, an error of 20 per cent. is to be expected in
many cases. This seriously limits the usefulness of such observations in
deriving values of atmospheric pressures, compositions and opacities, and
of stellar rotations.
EVENING.

Prof. F. Linxe.—Cloud evolution (with cinematograph demonstration,
8.30).

Tuesday, September 12.

Mr. A. GraHAM.—The instability of air layers (10.0).

Walker and Phillips have shown that the vortex patterns produced, when
a thermally unstable layer of air is subjected to a double shear, show close
similarity to certain cloud formations in the sky ; in the sky, however, there
is ordinarily a single shear. ‘The paper describes some experiments with
an unstable layer subjected to single shear.

The upper surface of the experimental channel was a long strip of plate
glass ; it was drawn steadily over a short, hot iron plate, thus producing
a single shear in the air layer between them. As in the double shear experi-
ments straight vortices could be formed, aligned either transversely to or
along the shear; in addition, there were formed a square pattern having one
set of diagonals along the shear, and some transitional patterns ; hexagons
were obtained without shear and also with a certain value of the shear.
There is a steady change from hexagons into longitudinal rolls through the
other patterns. All these patterns have their counterpart in the sky.

An investigation was made into the patterns formed in the absence of shear.
If the lower surface of an air layer is rapidly warmed, cells having ascending
air at the centres are produced ; if the upper surface is rapidly cooled, the
cells have descent in the centres. In the sky cells are formed having ascent
in the centres and also cells with descent, thus it appears that they should
be formed under the above conditions. If in the laboratory the temperature
difference between the top and bottom surfaces of an air layer is large the
cells have descent in the centres, whereas with a liquid layer the cells have
ascent ; this phenomenon is apparently due to the fact that the cool upper
surface of an air layer has a lesser viscosity than the warm lower surface
and is therefore less stable, while for a liquid it is the reverse.

The experiments considerably strengthen the theory that many cloud
patterns are due to thermal instability and not to Helmholtz waves.

Mr. E. Tititotson.—High focus earthquakes in the International
Seismological Summary (10.20).

From June 1914 to March 1928 there were twenty-four so-called shallow
focus earthquakes, whilst there were about three times as many deep focus
earthquakes and approximately 11,000 normal tremors published in the
International Seismological Summary. One of the ‘ shallow ’ focus earth-
quakes had a focus 0°04 of the earth’s radius above normal, and so it has
been suggested for this and other reasons that the normal depth of -an
earthquake is about 160 miles below the surface. More recently, however,

SECTIONAL TRANSACTIONS.—Af. 461

Dr. Harold Jeffreys and others have shown that the normal depth of an
earthquake is at the base of the granitic layer, or about 11 miles deep.

There is no peculiarity in the periodicity of these ‘ shallow ’ focus earth-
quakes, nor is there any system about the position of their epicentres in the
earth’s surface. Also when the seismograms for such tremors are examined
they appear to be perfectly normal, and the L phase is not unduly large.

At Oxford the epicentres of all earthquakes are determined from the
S-P differences, using Zéppritz-Turner tables, and a shallow focus earthquake
is one which calls for a removal of the epicentre so determined away from
all observing stations, no matter what their azimuth. In other words, if
the P phase arrives at its correct time, then S appears to arrive late.

Travel-time graphs have been drawn and calculations made for all the
readings for all the ‘ shallow ’ focus earthquakes separately, and from these
it appears that the P wave is quite normal and always well observed, whilst
the true S by Jeffreys’s tables is practically absent, and the readings usually
given for S approach more nearly to the Gutenberg PS curve. Several
seismograms have been examined, and in all these P, PP, PPP,and PS waves
are discernible, but S and SS are either extremely doubtful or absent
altogether.

Conclusions.

1. The peculiarity of the so-called ‘ shallow ’ focus earthquakes appears
to be due to the absence or doubtful presence of the true S pulse on all the
seismograms, though the PS pulse is present and has been usually identified
as S

2. Too great praise cannot be bestowed on the work of the International
Seismological Summary at Oxford, and it seems advisable to continue to
print all the readings sent by observing stations.

3. More reliance may be placed on the general identification of the P than
the S pulse, though it is important to have good tables for P and S separately.
These are confidently expected when Dr. Jeffreys has completed his present
work on his new tables.

4. The fine adjustment of epicentres might with advantage be carried
out with P readings alone.

5. Itis advisable to have field evidence with regard to an epicentre wherever
possible in addition to the evidence of seismograms.

Rey. J. P. RowLanp, S.J.— The Wensleydale earthquake of 1933, January 14
(x0.40).

On January 14, 1933, at about 8.30 a.m. G.M.T., an earthquake shock
was felt over a large area in the north of England, and was recorded at all
the British seismological stations, and at a few on the Continent.

By collation of all the newspaper reports and a few private advices—
about a hundred reports in all—a seismic map was drawn, which gave
a series of isoseismals ranging from 7 to 2 on the Rossi-Forel scale, the
highest enclosing a small area round Upper Wensleydale, and the lowest an
area of about 25,000 square miles, extending from near Berwick-on-T weed
to Anglesea, and from the Isle of Man to some distance in the North Sea off
the Yorkshire coast. The disturbed area is about the average given by
C. Davison for British earthquakes of central intensity 7.

Measurement of the P* and S* phases on the seismograms of the three
nearest observatories, Stonyhurst, Durham, and Bidston, gave the position
of the epicentre as 54° 20’ N., 2° 18’ W., which is at the head of Wensleydale,
about one mile to the N.E. of Hawes Junction railway station. Reference

462 SECTIONAL TRANSACTIONS .—Af.

to the Ordnance Survey geological map of the area shows that this position
lies on a fault which runs for about two miles in a north-easterly direction
from the head of the Dale.

From this epicentre distances were calculated to all the observatories—11
in number—from which records were available, and a time-distance diagram
was plotted for all the points measured on the seismograms. From this the
travel-times, velocities and apparent delays in starting of the six phases
exhibited in the following table were deduced. 'The values obtained by
Dr. Harold Jeffreys for two previous British earthquakes are given for
comparison.

WENSLEYDALE. JEFFREYS.
Vel. Delay. Vel. Delay.
Phase. km./sec. sec. km./sec. sec.
P 8°55 II 7°8 9
Pp* 6°21 2 6°3 5
Pg 5°23 6 574 3
S 4°29 10 4°35 8
S* 3°54 ° Shh 4
Sg 3°30 4 3°3 °

It will be noted that whilst the velocity of the Sg wave is identical with
that previously found, that of the P wave is appreciably higher, and all the
rest are slightly lower than the normal. The apparent times of starting also
follow a different order. ‘These anomalies may be related to depth of focus,
which appears to have been somewhat greater than normal. In determining
the epicentre from the three nearest stations, it was found impossible to
obtain intersecting circles by adopting the velocities appropriate to Pg and
Sg, but good concordance was obtained by taking those of P* and S*.

It should be stated that at all the stations except Stonyhurst and Durham
the movements recorded were extremely small, rendering measurement and
identification of phase difficult, so that any conclusions arrived at can only
be taken with some reserve. ‘The points measured, however, lie very well
on the straight lines corresponding to the values in the above table, which
accordingly seems to be fairly well established.

Mr. A. C. Best.—Temperature gradients near the ground (11.0).

A paper was read at the British Association Meeting in 1925 by N. K.
Johnson, describing the results obtained from a study of the vertical gradient
of temperature in the atmosphere over the height interval 1-2 m. to 17°1 m.
These results were subsequently amplified and published as a Geophysical
Memoir by the Meteorological Office.

The apparatus used by Johnson has remained in use since that date, and
in 1931 additional apparatus was erected by the author with a view to
examining the temperature gradient below 1-2 m.

Records of the temperature differences over the height intervals 2-5 cm.
to 30 cm. and 30 cm. to 120 cm. over close cropped grass have been
obtained for approximately two years by means of thermocouples. 'The
results have been analysed to give mean values corresponding to clear and
overcast skies. The greatest values of the temperature differences for each
month are also given, the maximum values of the lapses found for the lowest
interval being of the order of one thousand times the dry adiabatic lapse rate.

Some temperature-height curves for the height interval 2-5 cm. to
17*1I m. are given, and the time of maximum temperature at various heights
is discussed.

SECTIONAL TRANSACTIONS .—Af. 463

Discuss1on on Condensation of water in the atmosphere :—

Dr. G. C. Stvpson, C.B., F.R.S.—Problems of the condensation of
water in the atmosphere (11.20).

A simple straightforward description of the physical processes involved
in the condensation of water in the atmosphere leading up to precipitation
would appear to be as follows :

The nuclei of condensation are hygroscopic particles, mainly sea salt.
These collect water and grow in size with increase of relative humidity,
but remain invisible even in saturated air except as a haze. When air is
cooled below the dewpoint, water is deposited on the nuclei, and a mist,
fog, or cloud is produced. Continued cooling (within ascending air currents)
causes growth of cloud particles, until their increased size, augmented by
collisions, results in rain.

This simple statement will be considered in the light of the Pole wine
difficulties or problems :

(a) Kohler’s statement that if p is the concentration of salt in water
derived from clouds (grams per litre), then p = p. 2” in which pois aconstant
and 7 is an integer.

(6) Kéhler’s similar but quite unrelated statement, that if v is the volume
of a cloud particle, then v = vo2” in which ¥o is a constant and n is an integer.

(c) Why do some clouds rain and others not ?

(d) Is coagulation caused by (1) the relative motion of drops of different
size, (2) the turbulent motion of the atmospheres, (3) electrical charges ?

(e) Bergeron’s statement that no rain (other than fine drizzle) occurs
without the presence of snow in the upper part of the cloud—the melting
snow-flakes being the origin of the raindrops.

(f) Do certain sizes of raindrops occur more frequently than others, as
first suggested by Defant, and later by K6hler and Niederdorfer ?

(g) The part played by radiation in fog.

(h) The diurnal variation of fog. Is Entwistle’s explanation of the high
frequency of fog just after sunrise satisfactory? (Jour. Roy. Aeronautical
Soc., 1928).

(t) Optical phenomena show that spherical cloud particles occur at very
low temperature—e.g. cirro-cumulus clouds, fogs in polar regions, etc.
What is the physical state of these particles ? They cannot be supercooled
water because they appear in air masses, the temperature of which is always
far below the freezing-point, and it is difficult to see why sublimation should
not build up crystals at such low temperatures.

Mr. H. L. Green.—A critical study of direct methods for determining
the number and size-frequency of particles in aerosols (11.40).

The ranges of sizes of particles found amongst atmospheric nuclei, dusts,
fogs, clouds and other aerial disperse systems are considered, and direct
methods for determining the number and size-frequency of such particles
are critically examined. The study is confined mainly to condensation
(Aitken), photographic, microscopic, ultramicroscopic and other optical
methods, particular attention being paid to the accuracy and limitations of
each method.

Prof. J. J. Notan and Mr. J. P. Ryan.—Discharge from a raindrop
in an intense electric field (12.0).

When a drop is exposed to an intense electric field, it becomes pulled
out and begins to discharge. Negative discharge is greater than positive

464 SECTIONAL TRANSACTIONS.—Af, B

and occurs at lower field values. The onset of discharge is determined
by the approximate relation F1/r = 3,600, where F is the uniform field in
volts /cm. and ¢ the radius of the drop.

In ordinary atmospheric air the ions discharging from the drop attach
themselves to condensation nuclei and form large ions. But in pure air,
ordinary small ions only are found. No production of large ions or nuclei
can be detected even when a drop is discharging up to 55 micro-ampéres
and is being visibly broken up by the discharge.

It would appear, therefore, that the low mobility ions required by C. T.R.
Wilson’s theory of thunderstorm electrification are not rs produced
by discharge from raindrops.

Mr. L. H. G. Drnes.—Observations of supersaturation of water in the
free atmosphere, and an example of a cumulus cloud composed of
supercooled water drops (12.20).

A number of observations of relative humidity in the upper air over
England are summarised, made with sounding balloons carrying recording
meteorographs. The conclusion is reached that on many occasions, in
clouds, a state of supersaturation of water vapour exists. It is suggested
that the degree of this supersaturation may often exceed a relative humidity
of 120 per cent.

SECTION B.—CHEMISTRY.

Thursday, September 7.

PRESIDENTIAL ADDRESS by Prof. R. Rosinson, F.R.S., on Natural
colouring matters and their analogues (10.0). (See p. 45 .)

Discussion on Natural colouring matters (11.0) :—

Prof. Dr. R. Kunn.—Carotenoids and flavines.

In recent years many new natural colouring matters of the carotene-group
have been discovered, and a general view is given of their genetical relation-
ships. The first products of synthesis in plants are the dyestuffs with
40 carbon-atoms, from which carotenoids, containing fewer carbon-atoms,
are produced by oxidative disintegration. The splitting of the carbon-
chains may occur in different ways :—

(1) Cyg —+> Cop + Cao, B-carotene —— 2 vitamin A.

(2) Cy —~C,g + Cy, + Cg, lycopene —— bixin + 2 methylheptenone.
(3) Cao —~> Cyp + Cop + Cy, proto-crocin —-—>crocin + 2 picro-crocin.
(4) Cy —~>Cy3 + Cy,, proto-azafrin ——(ionone) + azafrin.

a-, B- and y-carotene are provitamins A. The constitution of «- and
Y-carotene isasymmetric; they supply only 1 mol. of vitamin A, and therefore
their physiological activity is only half that of the symmetrical B-carotene.

Widely distributed in nature are certain water-soluble dyestuffs, coloured
yellow and fluorescing intense green. They have been called flavines.
Ovoflavine from egg-albumin and lactoflavine from milk have been prepared

SECTIONAL TRANSACTIONS.—B. 465

by Th. Wagner-Jauregg in crystalline condition. ‘The elementary analysis
suggests the formula C,,;HN,O,. According to the experiments of
P. Gyérgy, lactoflavine, three times recrystallised (m.p. 267°), promotes
normal growth, when administered in doses of 5 y daily to rats deprived of
vitamin Bg.

The properties of flavines (lyochromes) and of carotenes (lipochromes) are
in many respects complementary.

Lyochromes. Lipochromes.
Solubility Soluble in water Insoluble in water
Colour Yellow, orange Yellow, orange, red
Fluorescence Green (very strong) Yellow-green (weak)
Combined with Proteins, polysaccharides —
Composition Containing nitrogen Nitrogen-free
Acids Resistant Labile
Alkalies Labile Resistant
Oxidation Resistant Labile

Biologically related to Vitamin B, and enzymes Vitamin A
5 Y & or yY-carotene

Effective daily dose 5 y lactoflavine 2°5 7 B-carotene

The flavines can be reversibly reduced (flavine + 2H= leuco-flavine), and
therefore they act in the cell as transporters of oxygen. When combined
with carriers of high molecular weight, they appear to act more strongly
as enzymes (O. Warburg). Apparently the flavines are exogenous precursors
of such oxidation-enzymes (pro-enzymes). The undialysable enzyme-
preparations act also as vitamin B,; the dialysable flavines have no more
enzymatic activity; the irradiated flavines, soluble in chloroform, have
neither the properties of enzymes nor those of the vitamin.

Flavines. Activity as
Vitamin Bg. Enzyme.
(1) Combined with carriers of high
molecular weight (undialysable) + a
(2) Crystallised dyestuffs (dialysable,
insoluble in chloroform) . + =

(3) Crystallised irradiated flavine
(soluble in chloroform) . : - -

Dr. R. P. Linsteap.—The phthalocyanines : a new class of synthetic
colours.

When phthalimide is heated wth certain metals, notably iron and
magnesium, in a current of ammonia, a complex reaction occurs with the
formation of highly coloured substances of a novel type. These have been
named phthalocyanines from their origin and deep-blue colour.

Identical compounds may be made from o-cyanobenzamide C,H,4(CN)
CONH, by the action of metals and metallic derivatives, such as oxides,
at temperatures of about 250° C. The metal may be eliminated from the
magnesium compound by the action of concentrated sulphuric acid to yield
phthalocyanine, the parent substance of the group.

Like indigo and indanthrone, these substances may be purified by crystal-
lisation from boiling quinoline and by sublimation in a vacuum, and may
Beer snes as homogeneous macrocrystalline blue solids with a fine purple
reflex

Analysis shows them to contain the unit (CsH,N,) combined in their

R2

466 SECTIONAL TRANSACTIONS.—B.

simplest form with a divalent metal or with hydrogen in the manner :
(C,H,N,),H2 or (CsH,N2),.metal. The mode of synthesis and the re-
actions of these compounds indicate that they contain a system of iso-indole
rings linked by nitrogen atoms and forming a large ring with the metal held
in the centre by primary and secondary valencies.

The phthalocyanines exhibit two features of special interest. First, their
fundamental unit resembles that of porphin, which is the basis of the
naturally occurring pigments of the chlorophyll and hemin group. The
structural unit of the natural pigments differs in containing no benzene
ring and in having methine (— CH =) links in place of nitrogen.

C—N= CGH
; 4\/\ CH/\
Phthalocyanine Pwd IN Porphin Unit | oN
Unit \ fo P CEN in

| |

Secondly, the phthalocyanines are among the most stable of complex
organic compounds. For example, the copper compound sublimes un-
changed at 600°; dissolves in strong sulphuric acid without decomposition
or loss of metal ; and resists the action of molten caustic potash. Other
compounds of the group show a similar stability.

Dr. N. V. Srpewick, F.R.S.

The plane arrangement which these formule require us to ascribe to
the covalencies of the metals they contain is of great interest. According
to the theory, a plane distribution of four covalencies of an atom is possible
(1) for four of the six covalencies of a 6-covalent atom, (2) for a 4-covalent
atom of one of the later transitional elements, such as nickel and perhaps iron.
The iron compounds described would then come under (2), and the
magnesium complexes could only exist under (1) if the atom was 6-covalent,
which would explain why these compounds have two molecules of water.

An interesting test would be to examine the beryllium complexes of these
substances. On the theory, beryllium cannot form more than four covalen-
cies, and these cannot lie in a plane, but must be tetrahedral. It should,
therefore, be incapable of forming links with four nitrogen atoms in a plane.
On the other hand, beryllium co-ordinates with such energy that it will form
the complexes if it can; and we could thus discover whether the steric
conditions permit of their formation.

Friday, September 8.

Discuss1on on Hormones (10.0) :-—

Prof. Dr. F. KocL.—Plant growth hormones (Auxin a and Auxin b).
(Ordered by the General Committee to be printed im extenso. See p. 600.)

Mr. G. A. D. HasLewoop.—Earlier chemical work on estrin.

From 1903 onwards, many extracts of ovarian tissue were prepared which
could produce cestrus in normal and ovariectomised animals. In 1923,
vaginal cornification was adopted by Allen’and Doisy as a method of assay.

SECTIONAL TRANSACTIONS.—B, 467

Ascheim and Zondek in 1927 discovered the hormone in pregnancy urine.
The chemical nature of the active substance was partially disclosed by
methods of obtaining potent extracts. Its phenolic nature was recognised
by Funk and by Marrian in 1929.

Doisy, Veler and Thayer, in 1929, and shortly afterwards Butenandt, and
also Dingemanse, isolated crystalline ketohydroxycestrin, C,H», (CO)(OH).
Marrian obtained trihydroxyestrin, C}sH2;(OH)s, in 1930.

Butenandt, having found both compounds in pregnancy urine, de-
monstrated that ketohydroxyeestrin was formed by potassium bisulphate
dehydration of trihydroxyeestrin, a reaction which Marrian and Haslewood
later showed to occur through elimination of the elements of water between
the two alcoholic hydroxyl groups of trihydroxyeestrin.

Examination of surface films of cestrin derivatives by Adam and Danielli
and a crystallographic investigation by Bernal showed the estrin molecule to
possess a rigid fused-ring structure of the phenanthrene or anthracene type,
with the phenolic group remote from the other oxygen-containing groups.

The absence of ethylenic double bonds was shown by the preparation of
substituted mono-bromo-derivatives.

Dr. A. BUTENANDT.—The relation of the sex hormones to the sterols
and bile acids,

The following constitutional formule have been proposed for the follicular
hormone, C,,;H 2302) and its hydrate, Ci3H.,0; :

O OH
CH; | CH; |

(SP i nS

iparifions ¢
HO\V/\Y (D HOVY/\/ (ID

These formulz are based on the following observations :

(x) The follicular hormone is a hydroxyketone, the hydrate a trihydroxy-

compound ; both contain one acidic hydroxyl group, similarly linked in each
case, whilst in the hydrate two adjacent secondary alcoholic groups replace
the keto-group.
_ (2) The results of catalytic hydrogenation conjoined with those of the
measurement of molecular refraction show decisively the presence in the
molecule of only three double bonds. This being established, the hydrogen
content as determined by analysis demands a four-ring system.

(3) The three double-bonds confer aromatic character, as shown by their
chemical behaviour and in view of the results of measurements of molecular
refraction and ultraviolet absorption. The acidity of the phenolic group
is to be explained by its phenolic character.

(4) The keto-group or the two hydroxyl groups are in a terminal five-
membered ring, which is opened by the alkali-fusion of the hydrate, a
dicarboxylic acid C,;H.,O; being formed.

(5) The points of union of this ring are shown by the degradation of
the acid C,,H,,O; to 1 : 2-dimethyl-7-hydroxyphenanthrene and 1 : 2-di-
methylphenanthrene.

The formule I and II demonstrate a clear connection between the folli-
cular hormone and the sterols, bile-acids, and pregnandiol. This relation-
ship is substantiated by the preparation of degradation products common

468 SECTIONAL TRANSACTIONS.—B.

to both classes of compounds (e.g. 1 : 2-dimethylphenanthrene from ztio-
bilianic acid). :

The testicular hormone (male sex-hormone), the action of which is
demonstrated by the growth of the cock’s comb, is a hydroxyketone,
CigH 3902, which contains a saturated four-ring system. Its relationship to
the follicular hormone and to the sterols has not yet beenshown with certainty.

Prof. E. C. Dopps.—The significance of synthetic estrogenic com-
pounds.

Hitherto the cestrus reaction has been regarded as a specific response to
cestrin and its derivatives, none of which have as yet been prepared syntheti-
cally. In collaboration with Cook it has been shown that compounds of
widely differing chemical structure may be synthesised, capable of causing
a full ceestrus reaction quite indistinguishable from the natural phenomenon.
Thus, 1-keto-1 : 2 : 3 : 4-tetrahydrophenanthrene falls into this category,
and also 9g: 10-dihydroxy-g : 10-di-n-butyl-9 : ro-dihydro-1 : 2:5 : 6-di-
benzanthracene. In addition, it has been shown that calciferol will
produce cestrus when injected in large quantities, as also the two carcinogenic
hydrocarbons 1 : 2-benzpyrene and 5 : 6-cyclopenteno-1 : 2-benzanthracene.
It would appear, therefore, that it is possible to have one molecule possessing
pharmacological activity of two entirely different varieties. The theoretical
importance of these observations is obviously great, since it may mean
that the processes of cestrus-production, cancer production and vitamin-D
activity are related in some unsuspected manner.

AFTERNOON.
Visit to Messrs. Boots, Nottingham.

EVENING.
Sectional dinner.

Saturday, September 9.
AFTERNOON.
Visit to Ketton Cement Works.

Monday, September 11.
Discussion on The interatomic distances and forces in molecules (10.0) :—

Dr. .N. V. Sipewick, F.R.S.
Prof, J. E. LENNARD-JONES.

Dr. J. M. Rospertson.—Interatomic distances in some aromatic hydro-
carbons from a Fourier analysis of the X-ray crystal data.

If X-ray crystal analysis can be carried far enough it yields the most
accurate and complete information regarding interatomic distances, and has
the great advantage of being applicable to very complicated structures with
the same precision as to simple atomic arrangements. Owing to the
essentially periodic structure of a crystal, we may represent the electron
density by means of a Fourier series

+co +00 +co
e(x,y,2)= 2 LY XZ Apg cos 2x (px/a + gy/b + r2/c),
—coo co

—co —

SECTIONAL TRANSACTIONS .—B. 469

assuming a centre of symmetry in the structure. It can then be shown
that the coefficients Ag, are proportional to the structure factors of the
crystal, which can be determined from experimental measurements of
intensity. ‘These measurements, however, do not tell us the phase constant,
or sign, which must be attached to each term. These must at present be
found by trial and error. In practice a double Fourier series is the most
convenient to apply, representing a projection of the structure on a given
plane.

Examples of such projections from anthracene, naphthalene and durene
were shown. ‘The benzene ring in all these compounds consists of a regular
plane hexagon of carbon atoms, the distance between the centres being
1°41 A. In durene the methyl groups are reasonably spherical, and are
situated at 1°47 A. from the adjacent aromatic centres. These methyl
groups are also displaced slightly away from each other, towards the unsub-
stituted positions of the benzene ring, the displacement being about 3° from
the symmetrical or unstrained position.

Dr. J. D. BERNAL.

Mr. E. J. BoweEn.—Forces between atoms in molecules.

The characteristic vibration frequencies of simple molecules can be
found from Raman spectra, near infra-red absorption spectra, and from
electronic absorption spectra in the visible and ultra-violet region.
A diatomic molecule has one characteristic frequency, from which the force
constant of vibration can be calculated. More complex molecules have
a number of characteristic frequencies which must be assigned to specific
modes of vibration. For this purpose use is made of selection rules due to
Placzek and to Dennison. In the case of certain simple types of organic
molecules (e.g. the cyanogen halides) it is possible to assign frequencies
with some degree of reliability by intercomparison of the observed fre-
quencies with those of other molecules, but in general it is necessary to
examine the infra-red absorption bands at high dispersion in order to apply
Dennison’s assignment rules. Such infra-red work at high dispersion has
been carried out in few cases at present. When the observed frequencies
of a simple molecule such as SO, have been correctly assigned to specific
modes of vibration, approximate values for the force constants of the links
and the apex angle of the molecule can be obtained by treating the molecule
as an assemblage of masses and springs. A more refined treatment must
take into consideration ‘resonance degeneracy’ and the anharmonic
character of the vibrations. This necessarily means the introduction of
many new constants into the problem. A very complete treatment of the
vibrations of the CO, molecule, allowing for these factors, has recently been
given by Adel and Dennison. From the experimental values of the funda-
mental frequencies (allowing for resonance interaction), of the overtones
(which are not the sum of integral multiples of the fundamentals), and of
the rotational structure of the vibration bands (which is modified by the
vibration), they build up an equation of twelve constants which completely
expresses the experimental results. The next development lies in the
elimination of many of these constants by the discovery of a suitable potential
energy function which will also reproduce the results. Adel and Dennison
apply a Morse potential energy function to each of the C=O links in the
molecule, and an empirical exponential function to allow for the repulsion
of the oxygen atoms for each other. The resulting equation containing four
constants is capable in a semi-quantitative way of reproducing the features

470 SECTIONAL TRANSACTIONS.—B.

of the original twelve constant equation. Further work on these lines is
likely in the near future to provide a clearer picture of the interaction within
a molecule of atoms which are linked together and of atoms which are not
linked in the chemical sense.

Mr. C. N. HINsHELWoop, F.R.S.

The curves showing the rate of reaction of certain gaseous substances as
a function of pressure have proved to be composite in nature, although only
one set of reaction products is formed. ‘Thus it must be concluded that
a given molecule can be activated in more than one way for the same
chemical transformation. This phenomenon presumably depends upon
the localisation of the energy of activation in different modes of vibration,
and should be correlatable with the information about the internal structure
and vibrations of the molecules, as obtained from other methods of
investigation.

AFTERNOON.

Visit to Messrs. Briggs’ Tannery, Leicester.

Tuesday, September 12.

Discussion on The chemistry of the tanning process (10.0) :—

Dr. D. Jorpan Lioyp.—The chemistry of skin, and the problem
confronting the tanner.

Animal skin consists of a tissue of fibres which are the biological units.
Each fibre has crystalline properties and is formed of packets of elongated
molecules between which are planes of weakness. ‘The fibre can be split
up at these planes into fibrils. This is an essential pre-tanning process since
it increases the capillary space through which the colloidal tannins can diffuse
and makes the polar groups of the protein accessible to the tan. Collagen
carries postively and negatively charged polar groups, and collagen fibres
contain both bound and free water. ‘Tanning consists in conferring chemical
and physical stability on the collagen fibre by the suppression of the active
groups and the elimination of water.

Prof. Dr. K. FREUDENBERG.—TZannins and their behaviour towards
proteins.

It is known that phenols form molecular compounds with amines and
amides (e.g. phenol itself with aniline or urea). ‘The amines and amides
can be simple or complex, like proteins ; the phenols also can be simple or
complex, as for example the tannins of the gallotannin or catechin groups
(whose constitutions are discussed). It is therefore affirmed that, when a
tannin and a protein particle come together, a molecular compound is
formed first. In a single tannin particle there are available many phenolic
groups capable of combining with the active groups of a protein particle.
After the first contact the two particles combine in such a way that the
greatest possible number of the phenolic and peptide groups are near one
another.

The first process is a contact at single points, the second is the mutual
permeation of the parts. Until then the process is mainly reversible.
The third process is the condensation of the neighbouring tannin particles
te insoluble high molecular compounds. The two first steps may be

Pn

SECTIONAL TRANSACTIONS.—B. 471

compared with the adsorption of indigo-white on the fibre; the third
resembles in some way the production of the insoluble indigo itself on the
fibre, and this process is irreversible. The third step, that is the self-
condensation of the tannin, is portrayed in this connection,

Dr. P. MairLanp.—The chemistry of Quebracho tannin.

The hypothetical stem substance of Quebracho tannin, the so-called
Quebracho-catechin, whose formula was suggested by Freudenberg in 1925,
has now been prepared synthetically from the corresponding pyrylium salt.
This new catechin is very similar to ordinary catechin itself, and has been
condensed to a product which shows many similarities to the purified
Quebracho tannin of natural origin.

The ‘ phlobaphene ’ reaction of the catechins has also been studied, and
some light thrown on its probable mechanism.

Prof. Dr. M. BERcMANN.—The chemistry of skin, and the catechol
tannins.

Skin is altered by tanning in such a way that it becomes more resistant
to putrefaction. ‘The chemical groups of the skin are also so altered by
tanning that they can better resist the chemical attack of the proteolytic
enzymes of the organisms of putrefaction. 'This resistance to enzymes is,
however, only limited in vegetable-tanned leather. According to the
tanning material used, the pre-tanning treatment of the skin and the manner
of tanning, the leather can be digested by the proteolytic enzymes to a
greater or less extent. The measure of this digestion is a measure of the
quality of the tanning. There appears to have been found here a new
analytical means for the investigation of leather since progress of tanning
can be measured by a falling away of a particular chemical characteristic.
By simple experiment it can be shown that liming and bating with enzymes
have a quite recognisable influence on the colloidal condition of the skin
which must make itself felt during the course of tanning.

The behaviour of a tannin during the tanning process depends directly
on its general chemical character. By sulphiting, the chemical nature is
altered and it then produces leather of different properties from non-sulphited
tans. Even the molecular size of the tannin is of fundamental importance
in the tanning process.

These particular lines of thought and experimental methods show the
way to a rational method of leather manufacture. The properties of the
leather can be altered at will by selected variations of the methods of tanning.

Dr. H. Puitiies.—The nature of the vegetable tanning process.

Gelatin in solution combines instantaneously with tannins, hide powder
less rapidly, whilst the structurally intact hide tans slowly. The speed of
tannage is thus governed by the rate of diffusion of the tannins into the hide.
This rate of diffusion is dependent on the following inter-related factors :
(a) the size of the intermolecular spaces in the hide ; (b) the intensity of the
electrical charge on the protein molecules ; (c) the size of the tannin mole-
cules ; (d) the charge on the tannin molecules ; (e) the degree to which the
tannin molecules are hydrated. The non-tannins in vegetable tanning

“materials play an important part in the process since they influence the size
of the intermolecular spaces in the hide and also modify the properties of
the tannins. Vegetable tanning materials vary in character, and the tanner
blends and manipulates the tan liquors so that penetration of the hide by

472 SECTIONAL TRANSACTIONS.—B, C.

small non-tan molecules is followed by the absorption of tannins possessing
large molecules. Reasons are given for upholding the view that the com-
bination of collagen with tannins is mainly electrostatic in character, being
partly salt formation between tannin and protein and partly association
arising from the polar character of the molecules.

Mr. F. C. THompson.—The gelatin-tannin reaction.

This interesting reaction has a long history beginning with Seguin and
Humphrey Davy, but has not yet been completely elucidated in spite of
the efforts of many workers. The variability in the composition of the
precipitate under differing experimental conditions attracted the attention
of the earliest investigators and led ultimately to the somewhat vague
characterisation of the reaction as a ‘ colloidal’ or ‘ adsorption’ reaction.
Attempts to gain a closer insight into the mechanism have been made in
several quarters. J.T. Wood showed that the reaction had little in common
with what is usually considered to be adsorption. Stiasny has emphasised
the importance of the degree of dispersion of the reactants, whilst Kruyt
has considered the reaction as an electrical discharge followed by dehydration.
A simple chemical theory assuming the formation of an insoluble salt from
the tannin as acid and the gelatin as base (a salt which largely resists
hydrolysis by reason of its high degree of insolubility) is fairly satisfactory
up to a point but does not cover all the facts of the case. An adequate
chemical theory will probably have to take account, following Freudenberg,
of the molecular compounds formed by phenols and organic bases.

Dr. F. E. Humpureys.—Factors influencing the tanning properties

of tan liquors and extracts.
The average molecular weight and degree of hydration of the constituents
of the more common vegetable tanning materials and extracts have been

determined. ‘The influence of these factors on the tanning properties of
the materials examined is discussed.

AFTERNOON.
Excursion to Fort Dunlop.

SECTION C.—GEOLOGY.

Friday, September 1—Wednesday, September 6.

GEOLOGICAL ExcuRSION TO SHROPSHIRE AND THE WELSH
BORDERLAND.

This excursion, carried out under the general direction of Prof. W. W.
Watts, F.R.S., occupied the time from September 1 till the opening of
the meeting. The headquarters were at Much Wenlock, and the districts
visited included the following : the Wrekin, Charlton, and Overley areas
under the guidance of Dr. R. W. Pocock ; the Cambrian and Longmyn-
dian Rocks of Caer Caradoc and Church Stretton under the guidance of

SECTIONAL TRANSACTIONS.—C. 473

Dr. E.S. Cobbold ; the Tremadoc Rocks of Shineton and the Ordovician
Rocks of Evenwood with Dr. C. J. Stubblefield ; the Silurian Rocks of
Wenlock, Ludlow, Leintwardine, and Onibury with Mr. Shirley and
Dr. Whittard ; and the Ordovician and Valentian Rocks of the Onny
and the northern Shelve country under the guidance of Dr. W. F.
Whittard. ‘The excellent weather allowed of the carrying out of a very
full programme, and satisfactory collections of rocks and fossils were
made.

Dr. E. 5. Coppo_p.—Notes on Comley Quarry, near Church Stretton,
Shropshire.

The geological history of this quarry may be sketched as follows :

In 1878 Dr. Charles Callaway claimed the discovery of Cambrian
(‘ Ffestiniog Beds ’) here, on the evidence of brachiopods.

In 1888 Prof. Charles Lapworth announced that he had collected frag-
ments of Olenellus, now relegated to the genus Callavia, and that the rocks
were of Lower Cambrian age.

In 1891 the same author described and figured a number of fragments of
Olenellus (Holmia) callavei, as he named the species, together with a restora-
tion of the trilobite so far as was then possible. At the same time he gave
a preliminary description of a Paradoxides found by T. T. Groom (P. groomi
Lapw.), which showed that the Middle and Lower Cambrian were in
juxtaposition at this spot.

In 1892 Mr. John Rhodes (senior) made a considerable collection for
H.M. Geological Survey, under Prof. Lapworth’s direction.

Since that time many geologists have visited the area and numerous
fragments have been collected.

In 1907, with the advice and help of Prof. Lapworth, and with grants
made to me by the Committee of the Association for the excavation of
critical sections among the Paleozoic rocks, I commenced a series of
excavations in the area, the principal results of which have appeared in the
Annual Reports of the Association and in the Quarterly Yournal of the
Geological Society.

Quarrying has now been abandoned, and much of the detail is lost under
débris and vegetation. I have, therefore, sketched a section of what was to
be seen some twenty-five to thirty years ago, in order to supply the present
deficiency.

The two divisions, Middle and Lower Cambrian, meet at the darkly
shaded line on the section representing the impersistent Lapworthella Lime-
stone, which by its fauna is relegated to the Lower Cambrian. To the east
of this we have the coarse grits of the Middle Cambrian, seen in the remains
of the quarry face in the south corner and in a depression in the floor, at the
eastern end of which they graduate by interpolation into fine shale, all
dipping about 70° to the east. An initial deposit, varying greatly from
place to place, occurs at the base.

In the trench seen to-day this deposit takes the form of a very dark,
gritty breccia ; two or three yards farther on it appeared as a black phos-
phatic skin adhering to the top of the Lapworthella Limestone, and contained
Dorypyge laket Cobbold, Paradoxides fragments, now referred to P.
elandicus Sjégren, and other fossils.

To the west of the dividing limestone the Lower Cambrian is seen
apparently in close conformity with the grits and shales above mentioned.
The beds consist of (i) three grey limestones—in descending order the

SECTIONAL TRANSACTIONS.—C.

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SECTIONAL TRANSACTIONS.—C. 475

Protolenus-, Strenuella-, and Eodiscus bellimarginatus-Limestones. Un-
fortunately, they are much disturbed by strike faults or differential sliding,
but are well seen in an excavation 200 yards to the south. Below these
come (ii) the Callavia Beds, as we now call the Olenellus Limestone of
Lapworth, which graduate downward into the Lower Comley Sandstone.

The five calcareous beds carry very distinct faunas and are regarded as
representing five separate faunal horizons.

The Lower Comley Sandstone is seen on the west. It is a green, fels-
pathic and micaceous rock estimated at 450 feet and includes some bands of
shale. It is not, as previously supposed, unfossiliferous. ‘The base of this
sandstone formation merges, by interpolation, into the Wrekin Quartzite.

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The evidence for the inter-Cambrian unconformity is indicated in this
quarry, (1) by the abrupt change in the lithology from fine-grained felspathic
sandstones to coarse quartzose grits, (2) by the complete change in the faunas,
(3) by the finding of fossiliferous fragments of the pre-existing Lower
Cambrian rocks in the conglomerate at the base of the coarse grits.

Further afield in Robin’s Tump these same grits are seen to rest with
discordant strike and dip upon sandstone beds that are estimated to be
100 feet below the Lapworthella Limestone.

A more striking exhibition of the unconformity is seen within 200 yards
of this quarry in the ‘Comley Breccia Bed,’ where the matrix carries
a younger Middle Cambrian fauna (the P. tessini fauna of Scandinavia),
while the included blocks consist almost entirely of Lower Cambrian
Limestones and Sandstones.

The characteristic Lapworthella nigra of the Lapworthella Limestone was

476 SECTIONAL TRANSACTIONS.—C.

so named because it marks the dividing line between the Middle and
Lower Cambrian in which Prof. Lapworth was greatly interested. The
deposit is black, phosphatic, and calcareous, about 3 inches thick at its best,
and crowded with brachiopods (Acrothyra) and Hyolithellus micans.. The
little Lapworthella shells are abundant. There are also three or more other
organisms and some nodular bodies, probably algal in origin.

This limestone occurs in the same stratigraphical position at Rushton.

‘TRANSACTIONS AT THE LEICESTER MEETING.

Thursday, September 7.

PRESIDENTIAL ADDRESS by Prof. W. G. FEaRNsIDzES, F.R.S., on A correlation
of structures in the Coalfields of the Midland Province (10.0). (See

P- 57:)
Mr. H. H. Grecory.—The geology of the Leicester district (11.0).

Mr. Francis Jones.—Further notes on the petrology of the igneous rocks
of Leicestershire (12.30).

The intrusive rocks of the Leicestershire-Warwickshire area group into
five divisions, viz. (1) Diorite-Granophyres of Charnwood, (2) Micro-
diorites of South-West Leicestershire, (3) Mountsorrel Granite complex,
(4) Camptonite-Diorites of Nuneaton, (5) Intrusions into Caldecote series.
Chronological or genetic correlation is difficult. The age of the last two
groups is known within limits : that of the granophyres is established with
the fifth group. The ‘ camptonites’ contrast with all the others not only
as regards basicity, but in being concordant intrusions of ‘ wet ’ magma.
~ Structural study of the Mountsorrel complex confirms the evidence of
its mineral freshness that it is a late intrusion. The isolated outcrops of
the non-granophyric diorites of the south-west make special difficulty in
interpreting their position in the sequence. Joint phenomena suggest
structures excluding contemporaneity with the granophyres. Mineralogi-
cally they ‘ fit in’ between the granophyres and the granite. They show
diversity of detail mainly in regard to hydrothermal alteration and to the
occurrence of epidote. The Croft-Huncote rock is of especial interest in
regard to the former. Here albitisation is advanced : analcite and laumon-
tite have been developed as vein minerals, and prehnite occurs within the
altered rock. The phenomena developed resemble those described by
Gilluly in his paper ‘ Replacement Origin of the Albite Granite, Sparta,
Oregon ’ (U.S. Geol. Sur. Prof. Paper, 175-C).

AFTERNOON,
Excursion 1: Demonstration of geophysical methods in the field.
Leaders: Dr. A. F. Hatitrmonp, Mr. A. T. J. DoLvar.

Excursion 2: The glacial geology of the Leicester district. Leaders:
Mr. W. Keay and Mr. Martin GIMson.

Yes ry

-

he ee ee ee

SECTIONAL TRANSACTIONS.—C. 477

Friday, September 8.

Discussion on St. George’s Land and the shore-lines of the Midland
Barrier during Carboniferous times (10.0) :-—

Prof. W. S. BouLTon.

Name proposed by Jukes-Browne for the continuous tract of land in
early Devonian time extending from Wales across St. George’s Channel to
eastern and central Ireland. Prolonged erosion of this part of the Cale-
donian continent was followed by submergence ushering in the Carboni-
ferous. ‘The delimitation of St. George’s Land during this period is the
main subject under discussion.

Repeated oscillatory movements during the Carboniferous and Permian
shifted the shore-line, so that it is necessary to refer the land margin at any
place to the particular time-division when it so stood. The ‘ Mercian
Highlands ’ of Midland geologists are the eastern extension of St. George’s
Land.

A map is exhibited showing the shore-lines in early Tournasian and late
Viséan times, and also the areas where Millstone Grit (sensu stricto) and Coal
Measures were presumably not deposited. ‘The points specially referred
to are:

(1) The advance of the shore-line northward followed by retreat south-
ward in the South-West Province during the Avonian, and the southward
advance in the Midland Province during the Viséan.

(2) The land boundaries in the Leicester area deduced from outcrop and
borehole evidence. A possible sea connection west of Leicester between
the Midland and South-West Provinces in Viséan time.

(3) Evidence from the pebbles and breccia-fragments of Permian
(Enville) beds points to eroded Avonian under the Triassic cover of the
Midlands.

(4) A brief summary of evidence from borings as to the extent of con-
cealed Coal Measures between the Birmingham and Leicester areas.

Mr. E. E. L. Dixon.

St. George’s Land appeared in Caledonian times, and during the deposi-
tion of the Upper Old Red Sandstone (Farlovian), its southern slopes
extended at least as far north as Brown Clee. Subsequent changes on its
northern side differed from those on the southern, and resulted in a southern
shift of the barrier, the northern side being progressively submerged, whereas
to the south land gained on the sea. The changes were due largely to con-
temporaneous earth movements, but the retreat of the sea on the south was
helped by the deposition of grits on the margin—the Cornbrook and
Drybrook Sandstones of Titterstone Clee and the Forest of Dean respec-
tively. The barrier was greatly enlarged by the mid-Carboniferous upheaval.
On the northern side the later depression which brought about the deposi-
tion of the true Millstone Grit (Namurian) and Coal Measures commenced
much earlier in the more central parts (N. Staffs., etc.) of the Midland basin
than near the barrier (S. Staffs., etc.).. The contrast in this respect between
neighbouring coalfields is so great as to suggest that the depression included
contemporaneous northward down-faulting between the contrasting coal-
fields. The southward encroachment of the Midland Province was only
checked by the mid-Carboniferous upheaval, and when sedimentation was
resumed it extended over what had formerly been part of the South-Western

478 SECTIONAL TRANSACTIONS.—C.

Province. ‘Thus Titterstone Clee, formerly part of the latter, was covered
with Coal Measures of Midland facies.

Dr. T. NEvILLE Grorce.—The Carboniferous shore-line in S. Wales.

The general Armoricanoid trend of the South-Western Province was
established in pre-Carboniferous times, and the Carboniferous sediments
accumulated in an oscillating geosyncline to the south of St. George’s Land.

Though generally the Lower Limestone Shales are conformable with the
underlying O.R.S., they locally transgress, and probably overlap north-
wards. Thus the shore-line at the commencement of the Carboniferous
can be fixed, and its movements in Lower Avonian times deduced.

The intra-Avonian unconformity, visible between the Vale of Neath and
Kidwelly, indicates a southward retreat of the shore-line in C,S, times,
followed by a re-advance, causing Sz beds to transgress probably down to
the O.R.S.

In D times the shore-line lay beyond the existing coalfield, though not
far distant to the north. At the close of the Avonian, regional emergence
accounts for the unconformity beneath the Millstone Grit; while the
overlap of higher goniatite zones over lower ones suggests an embayment
in the mid-portion of the North Crop between two southward-extending
headlands.

The east to west trend of the Armoricanoid axes was modified in places by
transverse structures which had considerable effect upon sedimentation
and coast-line configuration during the Carboniferous period.

Dr. E. NEAVERSON.

The Carboniferous Limestone of Flintshire and Denbighshire forms a
fringe dipping off various zones of Lower Ludlow rocks which formed the
Carboniferous land surface in this part of St. George’s Land. West of the
Denbighshire Moors the great Ordovician tract of Snowdonia extends
north into Anglesey. Carboniferous rocks occur in the eastern part of
this island and on the southern shore of the Menai Strait. The ancient
shore-line in North Wales is now modified by marginal faulting of com-
paratively slight effect as a whole.

The limestone often rests on a basement of red conglomerate and sand-
stone containing water-worn boulders of older rocks. In Anglesey these
are mainly pre-Cambrian and Ordovician rocks of local origin. Around
the Denbighshire Moors the red beds contain abundant boulders of Upper
Ludlow flagstone not known in situ in North Wales, but a former north-
ward extension from the type-area is indicated. ‘The junction of basement
beds and limestone corresponds approximately with the base of the Dibuno-
phyllum zone, thus dating the Carboniferous transgression from the north.

The Carboniferous Limestone is formed almost entirely of marine organic
debris ; hence peneplanation of the adjacent land mass is inferred, or perhaps
a cliffed plateau protected against marine abrasion by offshore shoaling.

In the Vale of Clwyd the lithology of the D, limestones suggests a
landlocked bay with slight tidal range. ‘There is some evidence of overlap
at the southern end of the Vale, though nothing higher than D, occurs on
the western side. The present Clwyd Range was possibly separated from
the western massif in D, times, and there was probably an extension up the
Dee Valley to Corwen in D, times. The occurrence of knoll-limestones
in North Flintshire is noteworthy.

In Flintshire the Holywell Shales have yielded marine faunas representing
several goniatite zones. Above these are typical Coal Measures which

SECTIONAL TRANSACTIONS.—C. 479

connect with the Midland Coalfields. In the Vale of Clwyd the limestone is
overlaid by the Purple Sandstone, usually ascribed to the Lower Coal
Measures. Coal Measures of limited extent are known under the Drift
in Anglesey.

Carboniferous rocks were probably never deposited on Snowdonia, the
Denbighshire Moors and the Clwydian Hills. The western extension of
St. George’s Land across the Channel to Ireland is questionable.

Mr. T. Eastwoop.

South Staffordshire furnishes examples of proximity to land during
Upper Carboniferous times—the ‘ Silurian banks,’ extending as north-to-
south peninsulas or islands to the north of St. George’s Land. ‘These
banks were completely submerged before the Upper Coal Measures were
deposited, though land still occurred to the south as is evidenced by the
overstep of the Halesowen Group and by other facts.

In Warwickshire there was land, probably an island, north of Nuneaton.
South of Nuneaton basal Coal Measure Shales rest upon Cambrian Shales
indicating deposition in quiet waters some distance from a shore-line.
Later, at Dosthill, an island of Cambrian Shales contributed breccia to the
Etruria Marls, while in the same locality the Productive Measures show
few signs of proximity to land. "The Cambrian Shales also contributed
material to the Etruria Marls at Nuneaton; but farther south the latter
formation is barely distinguishable from Productive Measures, and this
suggests a northerly provenance, though land probably lay some distance
to the south and furnished material for the Corley conglomerates.

Between the Warwickshire and Leicestershire Coalfields the Trias rests
on older rocks probably folded along meridional axes of pre-Triassic date.
In borings at Chilcote and Desford rocks were encountered which may be
interpreted as shore-line deposits.

Dr. W. R. Jones.—Silicosis : the minerals which cause it (12.15).

The definition accepted at the International Congress on Silicosis at
Johannesburg, in 1930, was, ‘ Silicosis is a pathological condition of the lung
due to inhalation of silica dioxide,’ and that ‘ to produce the pathological
condition, silica must reach the lungs in a chemically uncombined con-
dition.’ Also, under English law (Silicosis Scheme for compensation), free
silica is the basis: ‘ For the purposes of this Scheme (No. 342 of 1931)
silica rock means quartz, quartzite, sandstone, gritstone or chert, but does
not include natural sand or rotten rock.’

Cases in the anthracite district of South Wales came under the direct
notice of the author, however, where no rock of the type named in the
Scheme occurred in the underground working-places of the deceased,
although post-mortem examination confirmed silicosis as the cause of death.
It was therefore decided to investigate the possibility that rocks other than
those included in the Scheme caused silicosis. This was done by examining
the mineral residues from twenty-nine lungs, each from a person whose
death had been certified as due to silicosis or to silico-tuberculosis. "The
cases include potters, colliery workers, a stone-mason, and a silica-brick
worker. Residues from other lungs have also been examined (fifty-one in
all) ; they include pulmonary cases other than silicosis, and a normal lung
used as control.

The bulk of the mineral residues obtained from each of the silicotic lungs
consists of minute fibres of sericite. ‘This mineral is abundantly present
also in all the rocks which gave rise to the inhaled dust ; it is present in these

480 SECTIONAL TRANSACTIONS.—C,

in the size and form in which it is found in the residues and in sections of
silicotic lung tissue. Silica in the uncombined state (quartz) is also present
in these residues as relatively coarse and fine grains ; it occurs, however,
in amounts subordinate to sericite. Especially is this so with regard to the
small number of quartz particles as compared with the countless fibres of
sericite. One of the largest of these grains of quartz contributes as much
silica, in a chemical analysis of a residue, as 1,630 fibres of sericite of the
size found in the residue and in the lung tissue.

Silica in the uncombined state is not the chief cause of silicosis. This
appears to be established by : (a) the examination of the mineral residues
and sections of silicotic lung tissue under the petrological microscope ;
(6) the chemical analyses of these residues ; (c) the numerous cases of silicosis
where rocks containing sericite are worked (e.g. South Wales Coalfield, the
Rand, South Africa), and the complete absence of silicosis where silica rocks
containing as much free silica (Scottish Coalfields) and even a higher per-
centage (Kolar Coalfields, India) have been exploited by thousands of
underground workmen for a long period of years ; (d) many cases of silicosis
in mines where the ore and adjacent rocks contain only a low percentage
of free silica ; and (e) by the fact that no silica rock hitherto investigated
has given rise to silicosis-producing dust except those which contain sericite
or fibrous minerals.

It is submitted, therefore, that it is mainly the presence in the exploited
rocks of fibrous minerals, be they sericite, sillimanite, tremolite, etc. (or
a fibrous form of free silica as in chert, or a fibrous rock as in pumice), in
aggregates which become freed into the atmosphere as individual fibres,
that enables sufficient material in course of time to enter the lungs to cause
silicosis.

AFTERNOON.

Excursion to the Carboniferous Limestone inliers of the Breedon

district. Leader: Prof. H. H. SwINNERTON.

Saturday, September 9.

Excursion to the Pre-Cambrian and Cambrian of the Nuneaton district.
Leaders: Prof. L. J. Wits, Dr. F. Raw, Mr. F. W. SHoTTON.

Sunday, September 10.

Excursion to the Pre-Cambrian of the Charnwood Forest area.
Leaders: Prof. W. W. Warts, F.R.S., Mr. H. H. Grecory.

Monday, September 11.

Dr. A. Ratstrick.—The microspores of coal and their use in correlation (10.0).

The microspore-content of coal samples can be extracted and isolated by
the use of solvents such as Schultz solution, followed by ammonia, which
remove the oxidisable coal matrix and leave the spore exines and micro-
spores untouched. The microspores are mounted for micro-examination,
and are dealt with statistically, in the same way as tree pollen in peat investi-
gations. Microspore types are very varied and very definite, and their
determination in the micro-separations is a matter of precision. There is

SECTIONAL TRANSACTIONS.—C. 481

good evidence that particular coal seams are characterised, over a wide area,
by an assemblage of certain groups of microspores present in fairly definite
proportions. ‘The principal microspore types are illustrated and described.

Prof. G. Hickiine and Mr. C. E. MarsHaLi.—Recent studies of plant
structure in coal (10.35).

Improvements in the technique of section-cutting and photography have
made it possible to show that coal consists largely of plant-remains in which
the details of the original structure are preserved with remarkable perfection.
This detail, in some respects, far exceeds that which can be observed in the
familiar calcified or silicified petrifactions or coal-balls, since in the coal most
of the original substance of the plant remains, while in the petrifaction it has
been replaced. By the study of isolated sheets of bark and portions of wood
which are preserved as coal in the coal-measure shales the microstructure
of the plants can be studied in relation to their external form. ‘The bark-
structures of Lepidodendron, Bothrodendron and Sigillaria have been so
studied, as well as certain woods. In certain cases it appears possible to
demonstrate conclusively that the existing coal consists in part of the original
plant-substance and in part of additional organic material which has been
absorbed by the plant after death.

Mr. A. T. J. DoLLaR.—The dike-swarm of Lundy (11.30).

The Lundy dike-swarm comprises 122 dominantly vertical rock-sheets
of basic and intermediate composition which occur respectively in the pro-
portion of 91:9. It includes typical crinanites, olivine- and analcite-
dolerites, quartz-dolerites and tholeiites, together with orthophyres, vitreous
and non-vitreous andesites and pitchstones. Extreme types are repre-
sented by metallic ores, gabbroid rocks and very vitreous pitchstones. The
assemblage as a whole is distinctly Tertiary in affinity.

These dikes cut both the coarse granites and Devonian sediments of the
island with an average frequency of 26 per linear mile of coast. The mean
thickness of an individual sheet is about 4 ft., but the basic varieties range
between 3 in. and over 20 ft., while the less abundant types of inter-
mediate composition generally exceed 10 ft. in breadth. The width of the
swarm is approximately coincident with the north-south length of the island,
and a crustal extension of 3 per cent. has been produced in this direction
by the minor injections.

Apart from intermediate and basic intrusions there are numerous thick
and thin inclined sheets of microgranite which are confined to the major
granites of the island, while many quartz veins cut both the granites and
sediments. The two kinds of microgranites are remarkable for their
similarity to granophyric rocks of the Mourne Mountains, Ireland.

The distribution of intermediate and basic dikes is rigidly controlled by
jointing and fan-fractures. The latter radiate from centres which appear
to lie on submarine planes of weakness. Magnetic properties of the basic
dikes have been investigated and are comparable with those of corresponding
British Tertiary rocks.

Dr. FREDERICK WALKER.—The Crinanite dike of Maiden Island, Oban

(11.45).
The bulk of Maiden Island (about 13 miles north-north-west of Oban)
consists of a north-north-west crinanite dike of great breadth and con-
siderable diversity of composition. The west contact of the dike is not

482 SECTIONAL TRANSACTIONS.—C,

visible, but the eastern one shows a junction with a quartzite conglomerate.
The length of the visible portion of the dike is just under 400 yards, while
the greatest breadth is 125 yards. ‘The crinanite occurs as medium-grained
and very coarse varieties which have sharp, unchilled junctions, and segre-
gation veins are abundant: ‘These veins include felspathic, zeolitic, and
picritic types. ‘The last type occurs as a contemporaneous marginal modi-
fication, and thus affords an interesting problem in differentiation. The
mutual relations of the various modifications are discussed in this paper.

AFTERNOON.

Excursion to Corby ironstone district. Leaders: Prof. W. G.
FEARNSIDES, F.R.S., Dr. A. F. HALLIMOND.

Tuesday, September 12.
Discussion on The origin of red sedimentary rocks (10.0) :-—

Prof. G. HICKLING.

There has long been almost universal agreement that ‘ red rocks’ are of
non-marine origin; but the exact conditions under which they have been
formed are still open to discussion. "They show two marked facies : un-
stratified sandstones, and red marls of peculiar composition which often
contain saline deposits. Normal limestones are absent, but magnesian lime-
stones may be developed. Breccias and conglomerates of several unusual
types are commonly found. Fossils are rare and occur sporadically in very
restricted areas. Except in the occasional magnesian limestones, which
may yield stunted marine forms, the fossils are restricted to fishes, land
vertebrates and a limited flora. Long duration of stable conditions is
indicated by the occurrence of faunas of widely different ages in a sandstone
mass without any determinable stratigraphical break between them. ‘The
red coloration is attributable to prolonged exposure of the sediments above
the ground-water level, though they may have been subsequently distributed
and deposited by water. It is aided by the total absence of carbonaceous
colouring matter which results from a restricted flora and the complete
oxidation of any organic remains. Red rocks may show a lateral passage
to a marine facies, usually with an intermediate zone of alternating conditions.
It is suggested that the rocks are the product of arid or semi-arid delta or
flood-plain conditions, and that the explanation of the different types of
deposit is to be sought mainly in variations of humidity and temperature,
coupled with the effect of earth-movement in bringing the surface of deposi-
tion above or below the level of the ground-water.

Prof. W. S. BouLTON.

Arising from his studies of the Red Rocks of the Midlands, the speaker
refers to breccia- and conglomerate-formation in relation to contem-
poraneous earth movement. Attention is drawn to peculiarities of recurrent
coloration in sands, and to peculiarities in Spirorbis limestones. I

Prof. W. T. Gorpon.

The evidence of the plants as to the physical and climatic conditions
during the formation of the red beds.

SECTIONAL TRANSACTIONS.—C. 483
Mr. F. W. SHOTTON.

Examination of the cores of a group of three boreholes near Coventry led
to the discovery of a typical ‘ Permian’ breccia band in the middle of the
’ Allesley Conglomerate Division, well below the first appearance of breccias
previously known in the Warwickshire coalfield. A detailed study of the
constituents of all the pebbly horizons in the boreholes provided some data
which has a bearing upon the mode of deposition of breccias and con-
glomerates during the formation of the Midland Hercynian ranges.

In the first place, the small quantity of pre-Cambrian material in the
conglomerates is always angular, while any Silurian or Avonian fragments
in the breccia are well rounded. Hence it is concluded that the production
of a breccia or of a conglomerate depended mainly on the nature of the rocks
that were undergoing erosion.

Secondly, there is a deposition-cycle from conglomerates (mainly of
Avonian pebbles) to a breccia of pre-Cambrian material and back to a con-
glomerate. Now since it is likely that the cores of the Hercynian ridges
would be mainly pre-Cambrian rocks, a general uplift with increased
velocity of the rivers would lead to the distribution of pre-Cambrian pebbles
in the intermont basins where previously only the more local Avonian and
Silurian material had been transported. From this it is deduced that the
observed cycle of deposition coincides with a period of uplift of the adjacent
mountains, followed by their gradual lowering by erosion.

Dr. BERNARD SMITH, F.R.S.

In general red rocks contain less iron than non-red rocks. The colour is
due to dehydration of ferric oxide, which takes place most rapidly in warm,
moist climates under conditions usually productive of heavy vegetation.
Residual soils of such regions may be distributed by streams without losing
their ferric oxide. If subjected to powerful reducing action in swamps or
the sea they usually lose their red colour.

A residual soil underlies part of the Carboniferous Limestone of West
Cumberland, and in the Carboniferous Basement Beds of part of North
Wales red beds derived from residual soils give place upwards to marine
lagoon-phase deposits.

Most of our red beds were doubtless formed under desert or semi-arid
conditions ; yet the question arises whether certain sediments laid down in
comparatively arid tracts were not derived from uplands with residual soils
formed under warm, moist conditions. We may, indeed, have to reconsider
some of our views.

In normal Coal Measure times the hinterlands may have supported
a considerable upland flora and a red residual soil. ‘There would be oxida-
tion of this vegetation in situ, and reduction of the ferric oxide of the soil
swept into the swamps.

In Upper Coal Measure times, when coal swamps were at a minimum,
telative uplift of the land (of which there is internal evidence) probably
brought about a freer drainage, entailing less chance of reduction of ferric
oxide to the ferrous state.

True aridity, however, seems to have set in towards the end of the period.

.
©.

Dr. H. C. Versey.

In the Penrith Sandstone two periods of coloration are found: i.e.
pre-cementation and post cementation. . Part of the iron oxide is, apparently,
precipitated from colloid solution, but much is detrital. ‘The impossibility

484 SECTIONAL TRANSACTIONS.—C.

of marked climatic difference between the highland source area and the
area of deposition leads to the conclusion that the red coloration is only in
part due to dehydration in the arid Permian climate, but mostly to detrital
iron oxide formed in the monsoonal conditions of the Upper Carboniferous. -

Prof. D. M. S. Watson, F.R.S.

The speaker reviews the evidence afforded by the contemporaneous
fauna as to the conditions in which the red beds were formed.

Mr. J. H. Taytor.—Contribution to the petrology of the Mountsorrel
igneous complex (12.0).

The paper deals with two aspects of the complex which have received
little attention : (1) the nature and characteristics of the accessory minerals ;
and (2) the processes by which the several members of the complex were
formed and emplaced.

Under (1) some twenty mineral species are recorded from the area and
described in detail, particular attention being given to the widespread and
varied zircon and apatite. Points of special significance are the corrosion
of many of the zircons, and the occurrence of dark, sometimes almost
black, apatites.

Under (2) the view is expressed that both granodiorite and quartz-mica
diorite are of hybrid origin, resulting from the action of acid magma on
basic rock. The latter was almost certainly the gabbro of Swithland
reservoir, while some indication of the nature of the acid magma is afforded
by a thin marginal facies of the granodiorite that has the composition of
alkali granite. "The granodiorite was formed below present ground level,
and was subsequently injected into the position it now occupies.

Three new chemical analyses are quoted and discussed, and comparisons
are made with rocks of the Channel Islands, Dartmoor and the Isle of Man.

Dr. F. Raw.—On the Triassic and Pleistocene surfaces developed on some
Leicestershire igneous rocks (12.15).

The well-known grooved and polished surfaces exhibited by some of the
Leicestershire igneous rocks have long been regarded as dating from the
Triassic period, and as bearing evidence of formation by natural sand-
blasting under desert conditions. The author has reached the conclusion
that these features are here due to the Pleistocene glaciation.

AFTERNOON.

Excursion to the granite area of Mountsorrel. Leaders: Mr. H. H.
Grecory, Dr. E, E. Lowe.

Wednesday, Septémber 13.
Dr. L. S. B. Leaxey.—The age of part of the Rift Valley in Kenya (10.0). ©

In East Africa, work during the past seven years has thrown much new
light upon the age of the Great Rift Valley, which was formerly considered
to be an event of Mio-Pliocene age, with only small secondary movements
during the Pleistocene.

SECTIONAL TRANSACTIONS.—C. 485

On the new evidence it would appear that the greatest period of faulting,
when faults of a throw of over 1,000 ft. took place, occurred during the latter
part of the Pleistocene, long after man was in the country.

The evidence is discussed and compared with similar evidence from the
other parts of the Great Rift Valley, both north and south of East Africa.

Dr. S. W. Wootpripce and Mr. J. F. Kirxatpy.—The longitudinal
profiles of certain rivers in southern England, and their bearing on the
eustatic theory (10.40).

A comparison is instituted between the longitudinal profiles of the
Kentish Stour, the Mole, the Rother (East Sussex), the Rother-Arun, the
streams of the Hampshire basin and some of the East Anglian rivers.

In all cases the curves are composite, indicating successive phases of
rejuvenation with respect to successive marine base levels. For the area
of the Weald and the Hampshire basin the close correspondence of rejuvena-
tion features points to a general absence of differential warping during
Pleistocene times—a conclusion also enforced by the attitude of the higher
and older erosion surfaces. There seems thus to be good ground for
supporting the application of the eustatic theory to the classification of the
Pleistocene deposits of the area; though it has been very generally ignored
by British workers on the wholly inadequate grounds that it does not apply
to regions like Scandinavia, East Anglia, etc., whose physiographic history
is, in fact, entirely different.

The composite character of the curves is also used to invalidate the
common assumption that terraces fall on a curve parallel to the present
valley bottom. In many cases this is demonstrably not the case, and the
consequences in the field of palzontological and archeological correlations
are noteworthy.

Mr. H. C. Cooke and Mr. W. A. JoHNstToN.—Possibilities of increasing
the gold production of Canada (12.10).

The Canadian Shield, from which 92 per cent. of Canada’s gold now
comes, is likely to yield still larger amounts in the next few years. The
three gold-producing provinces of Manitoba, Ontario and Quebec have all
shown a rapid increase in annual production during the last seven years, and
analysis of the causes of the change indicates that further important increases
are to be expected, particularly in Ontario.

Unless new discoveries are made in the near future, lode gold production
from British Columbia will probably not increase notably in the next few
years, and may even decrease somewhat with exhaustion of the Premier
mine, the largest present producer.

Placer gold production from Yukon may increase in the next few years
if the number of dredges in use is increased. In British Columbia, hydrau-
licking is the chief method of placer mining and will continue for many

, years, but the annual output of gold from this method of mining may not
much exceed the present output. More efficient methods of recovery of
fine gold, for example by flotation, offers some prospect of success for dredg-
ing of bar deposits on streams in British Columbia and Alberta. Extensive
prospecting that is being carried on may result in the discovery of new fields.

Report oF RESEARCH COMMITTEE on Critical Sections of Tertiary and
Cretaceous rocks (12.30).

486 SECTIONAL TRANSACTIONS.—D.

SECTION D.—ZOOLOGY.

Thursday, September 7.

PRESIDENTIAL AppreEss by Dr. J. Gray, F.R.S., on The mechanical view
of life (10.0). (See p. 81.)

Mr. E. Heron-ALten, F.R.S.—Diffusion and extension phenomena
observed in the behaviour of living protoplasm (11.0).

Dr. G. P. Bripper.—The energy of flagellate cells (11.30).

My estimate of the work done per second per gramme weight of sponge
flagellate cells (Brit. Ass, Report, Leeds, 1927, p. 73) was a modification of
calculations explained to the Society of Experimental Biology in 1924,
based (a) on velocities observed in isolated cells compared with rate of
vibration of their flagella ; (b) on a priori calculations from size and rate of
vibration of the flagella; (c) on the observations of velocity from the vent
of Leuconia (= Leucandra) aspera, resistance in its channels, and the number
of its collar cells, described to Section D at Hull (O.7.M.S., 1923, p. 293).

Through Prof. Dohrn’s kindness, I made in 1932 new experiments at
Naples on the current from the vent of L. aspera, afterwards weighing
alive in sea-water the sponges used. The improved experiments have
made it possible to calculate the oscular velocity from each observation of
the further part of the jet ; they verify the theoretical conclusion (O.7.M.S.,
1923, Pp- 320) that the oscular velocity is characteristic of the species, and
irrespective of size of individual. With this velocity the determination of
the protoplasmic volume gives a solid datum for a more certain estimate of
the useful work done per gramme of collar cells—necessarily very small
compared with the efficiency of purely motor protoplasm.

Dr. V. B. WiccLeswortH.—The réle of water in the physiology of
excretion in insects (12.0).

The elimination of waste products, particularly the elimination of nitrogen,
with the least possible loss of water is one of the chief problems with which
insects, in common with all terrestrial animals, are faced. Insects discard
their nitrogen chiefly as uric acid, which can be readily precipitated and
excreted in solid form. In the blood-sucking bug, Rhodnius prolixus, the
precipitation of free uric acid is brought about by the secretion of urate in
solution in the upper parts of the Malpighian tubes and the reabsorption
of base and of water in the lower parts. In many insects a further mechanism
for the recovery of water exists at the hind end of the gut, where the so-called
rectal glands, or the general rectal epithelium, reabsorb water from the
excrement before it is allowed to leave the body. In the aquatic larva of the
mosquito, the so-called anal gills, which bear a superficial resemblance to
prolapsed rectal glands, absorb water from the surrounding medium so
that a constant supply is available for excretion, and only when this absorp-

tion is prevented experimentally does solid uric acid appear in the excretory
system.

Dr. Georcr SALT.—Experiments on the behaviour of insect parasites (12.30).
Most animals are capable of increasing their numbers very rapidly, -but

are prevented from doing so, partly by carnivorous animals that prey upon —

SECTIONAL TRANSACTIONS,—D. 487

them. In this connection the group of insect parasites known as parasitoids
(‘ refined predators ’) are very important and haye been used in many parts
of the world to limit the numbers of noxious organisms. The problems
involved in the use of these beneficial insects are obviously problems of
population, since they deal with the numerical interaction of the parasites
and their hosts ; but they are also problems of animal psychology, since the
behaviour of the individual parasites and hosts must be considered.

One of these problems is that of the selection of suitable hosts by the
parasite. It has been supposed that parasites are distributed in a given
host population at random, and on this assumption a theory of parasite dis-
tribution has been developed. But the field observations and the laboratory
experiments described show that the basic assumption is not true. Some
parasites have the ability to discriminate between suitable hosts and those
that have already been parasitised, and they distribute themselves much
more efficiently among the host population than chance would do. This
result is discussed from the two points of view, of populations and of insect
behaviour.

o
AFTERNOON.

Dr. G. C. Rosson.—The limitations of adaptability in the animal kingdom
(2085).

The main phyla and the subordinate groups of the animal kingdom differ
markedly in their range of adaptability (i.e. specialisation for a particular
mode of life). Differences of this kind are probably to be found in all
animal activities, e.g. in the incidence of parasitism, methods of getting
food, ete. The author dealt chiefly with the question of habitat-occupation,
and pointed out that, whereas several of the main animal groups had been
highly successful in colonising a large range of habitats, other equally large
groups have a far more limited range. Thus the Insecta have failed to
produce more than a few truly marine forms ; the Cephalopods have not
established themselves in water below normal marine salinity ; the Echino-
derms have not made their way into fresh water, though a few occur in
estuaries. ‘The incidence of habitat-occupation in the various families of
Gastropods was described and sundry cases of apparently idiosyncratic
adaptability were given. The adaptive achievements of certain groups were
then contrasted with their limitations, and the failure of the Lamellibranchs
to establish themselves on land and of the Cephalopods to colonise either
land or water of less than normal marine salinity was discussed. The
nature and origin of the factors limiting adaptation were considered. The
writer felt that individual predilection could not be excluded from the
various factors determining habitat-occupation.

_ Mr. A. Rorsuck.—The rook in the rural economy of the Midlands (3.0).

Rooks have been studied in five midland counties—Leicestershire,
Derbyshire, Nottinghamshire, Lincolnshire, and Rutland.

A census of the whole area, repeated after an interval of four years, showed
the rook population to be constant.

About ro per cent. of the rookeries change their sites annually,
__ There is no evidence that migration materially affects the problem in
the Midlands.
__ The distribution of their roosts during the winter is considerably different
from that of their nesting rookeries, although many remain on the same
sites all the year round.

488 SECTIONAL TRANSACTIONS.—D.

Except for a brief period rooks are restricted to a limited area for a feeding-
ground, the area in the vicinity of the rookery. ‘Those roosting at a distance
in winter return daily.

The census gives the rook population when it is at its lowest.

The nesting season is coincident with the emergence of insect life and
their rapid reproduction.

During the months of March to July, when the young are reared, the
proportion of insect food in the diet is at its highest.

The greater proportion of the annual food is also consumed in this
period.

The quality of the food eaten varies somewhat in different localities and
is necessarily associated with the type of local husbandry.

Mr. M. A. C. Hinton.—The musk-rat and its problems (3.30).

Friday, September 8. ,
Prof. D.M.S. Watson, F.R.S.—The origin of land-living vertebrates (10.0).
Mr. G. L. Purser.—Some points in the anatomy of Calamoichthys (11.0).

Mr. J.T. CunnincHAM.—Conditions of life and reproduction in Lepidosiren,
the South American lung-fish (11.30).

The eggs and larvee of Lepidosiren develop in a nest-burrow at the bottom
of a tropical swamp. The larve are provided with external gills, and the
male parent, which is found with its progeny, has long vascular filaments on
its pelvic limbs. ‘These filaments are absent or rudimentary in the female,
and developed only in the breeding season of the year. It was proved
experimentally by Carter and Beadle in 1927-28 that the water at the bottom
of the swamp contained little or no dissolved oxygen, and by Cunningham
and Reid in 1930-31 that oxygen was emitted by the filaments when the
fish bearing them was placed in deoxygenated water. It must be concluded
that the respiration, and therefore the life of the eggs and larve, depend on
the oxygen given off by the filaments of the male parent. This is the first
case in which evidence has been obtained of the emission of oxygen to the
external medium as the normal function of special organs in any animal.

The evolution of the filaments is discussed in relation to modern theories
and concepts, and the theory that the peculiar conditions have acted only
by selection, direct or indirect, of mutations not caused by these conditions
is rejected.

Miss A. M. Brpper.—The alimentary canal of the Cephalopoda (12.0).

The structure of the digestive system in a representative series of Cepha-
lopoda (including Nautilus pompilius) was examined, and the results com-
pared with existing descriptions. Where possible, living or fresh material
was used, Gut-contents showed a macrophagous carnivorous diet for the
whole group. :

The digestive tract consists throughout the group of (1) a buccal mass
containing beak-like jaws and radula ( he last absent in Cirromorpha only) ;
(2) esophagus ; (3) a muscular stomach, or gizzard; (4) a more thin-
walled cecum; (5) intestine. Fore-gut glands open into the buccal mass,
and mid-gut digestive glands into the cecum. (Esophagus and stomach
are lined with a cuticle, cecum and intestine with a ciliated mucous

SECTIONAL TRANSACTIONS.—D. 489

epithelium. Itwas found that the cecum hasan elaborate structure constant
for the group, and contains a ciliary collecting mechanism.

Principal variations are ; (1) presence or absence of a‘ crop’ ; (2) relative
size and form of stomach and cecum; (3) length of intestine; (4) size
and form of the glands. ‘True size of an organ is very difficult to determine
owing to individuals differing in (a) state of feeding ; (6) fixation. Dis-
cussion follows of function in the various parts, and possible functional
significance and mutual relationships of variations in (a) internal volume,
(b) internal surface area of the gut, and (c) size and nature of the mid-gut
gland.

Mr. P.S. Mitne.—The distribution of insects by currents at various levels
in the atmosphere (12.30).

Insects which are being carried about by air currents are filtered from the
atmosphere by the action of the wind upon a conical collecting net supported
above the ground by a system of kites.

The net is sent up closed to the desired height, is allowed to fly open for
a predetermined period, and, after closing again, is hauled down for an
examination of the catch. The opening and closing of the net are controlled
by a simple chemically-operated release mechanism.

By this means a knowledge of the influence of wind upon the distribution
of insects is being obtained. Particular attention is being paid to agricul-
tural pests, and their possible introduction into this country from the
Continent at high altitudes.

AFTERNOON.
Visit to the Midland Agricultural College, Sutton Bonington.

‘THE MEMBERS OF THE SCIENTIFIC StTaFF OF Discovery II.—The effect of
currents on the plankton distribution in the surface waters of the
southern oceans (2.15) :—

Mr. G, E. R. Deacon.—Hydrology.

There are three kinds of surface currents in the southern oceans : antarctic
surface currents, sub-antarctic currents and sub-tropical currents. These
currents are movements of antarctic, sub-antarctic, and sub-tropical waters,
and their speeds and directions are directly responsible for the distribution
of the three types of surface water. There are generally well-defined con-
vergences on the surface between the different waters, and these divide the
southern oceans into antarctic, sub-antarctic, and sub-tropical zones. The
waters of the three zones differ in their characteristics and consequently in
the type and quantity of life which they can support : the differences are due
partly to the origin of the waters and partly to the climatic conditions of the
zones in which they are found. The hydrological conditions in each zone
are almost uniform and only change gradually with latitude. The greatest

differences are found in the antarctic zone, where, south of 65° in the

Atlantic and Indian sectors and south of about 68° in the Pacific sector,
the surface water flows westwards. North of this current the water
flows eastwards. The eastward-flowing antarctic water receives additions
from the westward-flowing current, and also mixing of antarctic and sub-
antarctic surface waters takes place in a few areas where the antarctic

currents are deflected northwards by the configuration of the land or by

irregularities in the topography of the sea-bottom. The easterly antarctic
s

490 SECTIONAL TRANSACTIONS.—D.

current receives additions from the westerly near South Georgia and near
the Kerguelen-Gaussberg ridge; mixing of antarctic and sub-antarctic
water takes place across the Antarctic Convergence between the Falkland
Islands and South Georgia.

Mr. Ditwyn Joun.—Plankion.

The different surface waters of the southern hemisphere have distinctive
planktonic faunas. The recent work of the R.R.S. Discovery IT has led to
an extensive knowledge of those of the antarctic and sub-antarctic surface
waters ; series of tow-nettings were made across each kind of water in all
sectors of the hemisphere and at all seasons of the year. The boundary
which separates them, the Antarctic Convergence, acts as a hard and fast
barrier to the horizontal distribution of certain groups of animals though
not to others.

Two species of Euphausia occur only in the antarctic, four only in the sub-
antarctic : there is one species, an exception, which occurs in both. ‘Two
Chaetognaths, species of different genera, occur very numerously throughout
the surface waters of the antarctic and sub-antarctic, but in both species
there are two ‘ races,’ one confined to each kind of water. Few Copepoda
are limited in their horizontal distribution by the Antarctic Convergence.
In some places where there is a bend in the convergence and abnormal
hydrological conditions occur, areas of mixed antarctic and sub-antarctic
plankton are found. The extent to which the power of vertical migration
is involved in this horizontal mixing is discussed.

The surface current of antarctic water flowing to the west, south of 65° S.,
has planktonic forms peculiar to itself. They are carried north, even to the
convergence, where the configuration of antarctic land deflects this water
northwards. The most interesting and important example is the wide
distribution of whale-food, Euphausia superba, in the sector of the antarctic
which is affected by the Weddell Sea current.

Mr. F. S. RussELL.—The behaviour of marine plankton animals in
relation to the conditions of their surroundings and to their life-

cycles (3.15).
Mr, P. ULLYott.—Vertical movements of the Zooplankton (3.45).

Saturday, September 9.
Excursion to Charnwood Forest. Leader: Mr. W. E. Mayes.

Monday, September 11.
Mr. L. C. BEADLE.—Osmotic regulation in Gunda ulve (10.0).

Dr. Stewart MacLacan.—The prediction of insect outbreaks in Britain
(10.30).

Discussion on The structure of protoplasm (Mr. J. E. Harris; Dr. D.
Jorpan Lioyp; Mr. W. T. AstBury) (11.0). ce

SECTIONAL TRANSACTIONS.—D. 491

AFTERNOON.
Dr. H. O. Butu.—The experimental study of conditioned responses in

fishes (2.15).

Dr. C. F. A. Pantin.—Nerves and nerve-nets in Invertebrates (3.0).

Nervous action in the Invertebrates is often said to differ fundamentally
from that in the Vertebrates. But in fact there appears to be only one
important difference. Except in the Vertebrata, ‘ peripheral facilitation ’
is enormously developed, especially between nerve and muscle. That is,
the first nervous impulse passes into few or none of the muscle fibres, while
each succeeding impulse is increasingly successful in doing so. This is
responsible for the varied muscular responses of the Crustacea, the Actinozoa
and probably the Echinoderms. ‘The special properties of the nerve-net
in the latter groups are due to facilitation.

The natural responses of the Actinozoa are effected by well-defined
muscles, which fall into two groups according to their relation to the nerve-
net. In one the net acts as'a simple conducting unit from the site of the
stimulus to the muscle ; facilitation occurs only between the nerve-net and
the muscle. In a second group the nerve-net supplying the muscle is
partly isolated from neighbouring regions of the net. Between these
regions inter-neural facilitation takes place. This analysis throws much
light on the nature of autonomy in the nerve-net and on the origin of polar
conduction. A fairly complete picture ¢an be drawn of the Actinian
nerve-net and of the manner in which it subserves the organism in its
natural environment.

Tuesday, September 12.

Joint Discussion with Sections I (Physiology) and K (Botany), on
Genetics :—

Prof. J. S. Huxtey.—Physiological genetics (10.0).

Prof. R. R. Gates, F.R.S.—The general nature of the gene concept
(10.30).
Dr. C. C. Hurst.—The significance of genetics in evolution (11.0).

The science of genetics has advanced rapidly during the last decade.
The mechanism of heredity and variation, which was unknown to Darwin,
has been revealed to us by the microscope. Experiments show that mor-
phological, physiological, and psychological characters are alike organised
by sets of genes carried by the chromosomes of the cells. Consequently
it is now possible to re-arrange the old indefinite Linnean species into
definite genetical species which are experimentally determinable by their
gene-chromosome complexes. ‘Thus taxonomy becomes an exact science
and the genetical species provides a measurable unit of evolution.

The gene is the unit and basis of life and progressive evolution can be
traced from the monogenic species of Bacteriophage of molecular size to the
polygenic species of the Primate Man carrying a genechromosome complex
which produces a conceptual mind. The exercise of this in scientific
research is rapidly bringing power and freedom to man by gaining more con-
trol over nature and life. Experimental hybridisation of genetical species

492 SECTIONAL TRANSACTIONS.—D.

and bombardment of their germ-cells by X-rays have already created
numbers of new species and forms, and the time is at hand when natural
selection can be replaced by human selection and man himself will be
able to control evolution and in a large measure determine his own destiny.

Dr. K. B. BLackBurN.—The synthesis of species (11.20).

Recently new true breeding species have been produced experimentally
by crossing two other species and these do not, as a rule, produce fertile
offspring when backcrossed with their parents. The secret of their origin
is revealed by their cytology. Lack of fertility in a species hybrid is often
due to incompatibility of the chromosomes of the parents, but most of these
new species have been produced by a doubling of the complete complement
of the hybrid, thereby producing two equivalent sets to pair at meiosis.
This gives the pure breeding character which marks them off from the
hybrid swarms produced from crosses which are more or less fertile in the
first instance. Such forms have been produced by crossing species (Primula
Kewensis, Nicotiana digluta, Crepis artificialis) or even genera (Raphano-
Brassica, Atgilotricum). Similar naturally occurring forms have now been
recognised (Rosa Wilsoni, Spartina Townsendii), but the crowning piece of
evidence for this as a natural method of species building is the production
by Miintzing of plants indistinguishable from the common hemp-nettle
(Galeopsis tetrahit) by crossing two quite distinct species, G. pubescens and
G. speciosa.

Dr. IRENE Manton.—The analysis of species (11.40).

Col. C. J. Bonn, C.M.G.—Hormones and genetics (12.0).

The importance to physiology of the particulate discontinuous nature of
the heredity process, as established by Mendel.

Diabetes a familial disease ; the pancreatic defect on which the disease
depends is heritable. ‘Treatment with insulin ameliorates symptoms, but
does not remove the defect. Effect of this on racial welfare.

The evidence derived from a study of binovular twins, one of which may
be a Cretin, or achondroplastic dwarf, and the other normal, throws light
on the genetic factors concerned in thyroid and pituitary abnormality.

Tissue cell susceptibility to hormonic influences may vary on the two
sides of the body. Examples. The gynandromorphic pheasant. Asym-
metrical spur development in hens. Asymmetric polydactyly in fowls.
Gynandromorphism in insects.

Acquired immunity and genetics. The immunity reaction in bacterial
or coccal infections compared with that in virus diseases. ‘The influence
of size of the infecting agent on the permanence of the reaction. If cell
descendants (not offspring) are to remain immune, the nuclear heredity
mechanism of the somatic cell must be concerned in the reaction.

GENERAL DIscussION (12.20). (Prof. F. A. E. Crew; Dr. E. Asupy;
Mr. J. T. CunnrincHAM; Mrs. C. B. 5. Hopson.)

AFTERNOON.

Mr. Micuart GraHaM.—Prediction of North Sea cod fisheries (2.15).

It is known that fluctuations in the yield of certain fisheries, e.g. herring,
plaice and cod, in the North Sea are largely determined by the degree of

SECTIONAL TRANSACTIONS.—D. 493

success in survival of broods some years previously. The proportion of
particular broods is estimated when the fish are large enough to be taken
in trawls. Having found that the important fisheries depend on fish of
a restricted age, say, five to six years old, estimates of the yield at that age
can be made some years in advance, from the abundance of fish of, say,
one to two years old.

The particular case considered, the cod in the North Sea, is interesting
in that :

(1) The area populated by small fish is so extensive that adequate sampling
of small cod can only be obtained in the trade statistics of landings, cause
being shown for considering the magnitude of certain seasonal changes in
the statistics as a measure of brood strength.

(2) The age of the cod (by which landings of small cod are related to
brood years and to subsequent yield of large cod) has to be obtained in-
directly, from size ; partly because of the said sampling difficulty and partly
because the more usual determinations of age from scales or otoliths are un-
reliable for this fish (in the North Sea). The necessary analysis involves
somewhat unconventional methods, which are, however, justified by the high
correlation found. (See (3).)

(3) Formulz are deduced from the investigations of (1) and (2) and relate
brood strength to subsequent yield per unit of fishing power, in a perfectly
rigid manner, so that, up to a point, the prediction is precise and depends
merely on arithmetic (its precision being estimated by prediction of the
‘probable error’). High correlation has been found between the estimate
of brood strength and subsequent yield,

Mr. E. Forp.—Growth in length and change in form with increasing age
in fishes, especially the herring (2.45).

The communication deals with changes in form brought about by the
different rates at which the various parts of a fish’s body increase in length
during the transition from a transparent larva to a fully scaled adolescent,
and with the subsequent growth in length of the body as a whole, by the
addition of progressively diminishing annual increments throughout life.
Simple mathematical treatment of observed data raises interesting questions
in phylogeny and ontogeny, and suggests a convenient method for the
comparison of growth in different geographical regions.

Dr. C. H. O’DonocHuE.—Fasper Park, Rocky Mountains : its biology
and fisheries (3.15).

In 1925 the Biological Board of Canada requested the author to investigate
the lakes in Jasper Park with a view to improving their fishery value. It was
considered worth while to conduct the examination on broad lines, since
no similar survey had been made within a radius of 2,000 miles, and the
mountainous character of the country, its altitude and essentially virgin
conditions made it unique in North America. This report covers two
summers’ field work and their results. One noteworthy problem was the
entire absence of fish from the Maligne-Medicine drainage system. The
answer to this question was found in the peculiar geological conditions of
the outlet of this system into the Athabasca valley, whereby the system is
cut off from the possibility of fish immigration. A fairly full investigation
of the physical and chemical constitution of certain types of lakes was made
and also a survey of their flora and fauna. Resulting from the survey

494 SECTIONAL TRANSACTIONS.—D, E.

various suggestions were made, among them the planting of the Maligne-
Medicine drainage area with Speckled Trout, Salvelinus fontinalis. Most
of the experiments were successful, and a report made for the Board this year
states: ‘ The stocking of the Maligne-Medicine system with speckled ‘trout
has given results second to none in the history of fish culture.’

SECTION E.—GEOGRAPHY.

Thursday, September 7.

Mr. M. Gimson.—The water supply of Leicestershire, with special reference
to human settlement (10.0).

The subsoil of Leicestershire consists mainly of impervious clays—the
Lias Clay and the Keuper Marl—in which water, when obtainable at all,
is found at considerable depths.

Water near the surface is only found in:

(a) The Valley Gravels.
(b) The Glacial Gravels.

The former are found on each side of the principal rivers, and provide
good sites for villages, when in the form of River Terraces, with water
easily accessible.

The latter occur mainly on the higher ground, where the glacial covering
still remains. 'This covering is principally Boulder Clay, but water-bearing
sands and gravels are found associated with it in places.

Such sands and gravels form the only source from which water could,
in early days, be readily obtained away from the main watercourses, and
their influence in deciding the position of settlements is clear. It is particu-
larly well shown in East Leicestershire, where, almost without exception,
villages on the uplands are situated on small isolated patches of sand or
gravel, and where in the southern portion there are many such villages,
while in the northern part large areas of the higher ground are scantily
populated, owing to the glacial covering being devoid of sand or gravel.

Miss G. M. Sarson.—The growth of population in Leicester (10.45).

The city of Leicester is situated in the valley of the river Soar, from
which the ground rises eastward and westward. To the east are the
Spinney Hills and the Victoria Park, the former 264 ft., the latter 289 ft.
high, while westward are the Dane Hills, over 200 ft. above sea level. The
oldest part of the city was situated on a gravel terrace on a spur 190 ft. to
210 ft. high, on the right bank of the Soar, which formed a boundary and
a defence on the western side. To the north the ground sloped downwards
to the marshy meadows of the Soar, 20 ft. lower than the gravel terrace.
The Fosse Way entered from the north-east, to cross the river at the present
West Bridge, and afterwards passed in a south-westward direction towards
High Cross. In medieval times life centred round the abbey and monastic
houses. ‘These declined in importance, but there was an increased trade
in the markets, the chief of which—the Saturday market—was in the south-
east corner of the town. Here the agricultural produce of the district was
sold, for Leicester was the market centre of the county.

The population until the end of the seventeenth century has been estimated

SECTIONAL TRANSACTIONS.—E. 495

at 5,000 people, but by the end of the next century the number increased
to 16,953, due chiefly to the establishment of the framework knitting
industry, and the beginning of the manufacture of boots and shoes. The
latter half of the nineteenth century was a time when the greatest increase
in population took place, and by 1921 the census statistics show that
Leicester had a population of over 240,000. Other industries, in addition
to the two chief occupations of hosiery and boot and shoe manufacture, are
the making of machinery, manufacture of optical instruments, and printing.
Thus, after remaining through many centuries a community of approximately
4,000 people, the city developed from a small country town into one of the
most densely populated centres of modern commerce of the north-east
Midlands.

Dr. P. W. Brran.—Preliminary survey of land utilisation in the City of
Leicester (11.30).

Mr. H. H. Peacu.—Regional planning and the Leicester district (12.15).

The study of the cultural landscape and value to town and country
planning. The necessity of study of planning, not only by experts but by
the ordinary man, to save the country from disfigurement. Schultz
Naumburg’s studies on cultural landscape referred to.

Rapid development of land by economic circumstances and breaking up
of old estates, where planned development used to be carried out, is having
serious effect on landscape. Difficulties in planning by local authorities
and distrust of same felt by many. New Town and Country Planning Bill
and what can be done. Local problem of Charnwood Forest. Economic
value of planning in development. Leicester rapidly developing town,
clean, little planning, much ribbon development.

Dreariness of new suburbs. Officials and destruction and disfigurement
of trees. No control of elevations. C.P.R.E. and Advisory Panel system,
a help towards suitable building. Local housing schemes compared. Parks
and allotments. Need of walking ways. New Walk example. Advertise-
ments and planning. Curse of enamel sign. Industry finding need and
value of taste in design and lack of training in schools, a vital matter in
planning. Engineer and expert often spoil good plans by bad taste.
Leicester City Council and Art Advisory Committee. Need of more
co-operation and neighbourliness in building and planning.

AFTERNOON.

Tour of the City of Leicester to study land utilisation and general
position.

Friday, September 8.

Dr. Vaucuan Cornis.—The visualisation of landscape (10.0).

_ The science of physiological optics, which has been long and successfully
pursued, provides reliable information as to the extent of the surrounding
‘sphere which it is possible for the eye to perceive ; the distance to which
stereoscopic vision extends ; the perceptible contrasts of light and colour ;
and, generally, as to that which it is possible for our eyes to recognise in the
surrounding landscape—when we try.

496 SECTIONAL TRANSACTIONS.—E.

The pleasurable, or zsthetic, impression of landscape has, however,
relatively little to do with what we can see when we try, but, on the contrary,
depends upon what we notice when we make no conscious effort. ‘The
investigation of this branch of psychological optics is ‘herefore indispensable
to the creation of an esthetic science of scenery. In the present paper the
author describes the methods which he has employed to ascertain the modes
of selective action by which the eye unconsciously provides the ordinary
man with a vision of the landscape which is, in fact, an artistic composition.

The review includes examples relating to impressions of tone, colour,
form, magnitude, multitude and movement in the landscape of different
climates and latitudes.

Mr. J. A. Steers.—Scolt Head Island: a study in physical geography
and ecology (10.45).

Scolt Head Island, on the Norfolk coast between Hunstanton and Wells,
affords excellent scope for the study of (1) constructional coast forms,
(2) comparatively rapid erosional changes, and (3) the relations of plant
ecology to shore-line studies.

It is a National Trust area, and is best known as a bird reserve. But
the geographer has much to interest him both on the island and along the
adjacent coast.

The origin of the island is rather uncertain, and is here discussed. One
of the more interesting problems that yet await solution is the possible
light that archeology may throw on this problem. ‘Two ancient encamp-
ments are very close to the area, one being in marshland. Their excavation
may afford very interesting results. This island is a long sand and shingle
formation, with numerous recurved ends running back from it. Within the
main beach and between the laterals is an admirable development of
saltmarshes, with characteristic flora.

On the mainland side of the creek which separates the island from the
land are some other shingle ridges which have apparently been built in a
direction (i.e west to east) opposite to that of the main island. They are
directly comparable with the ridges still forming on the distal end of
Brancaster Golf Links.

Near by is a submerged forest, the future investigation of which should
afford some data for the chronological history of the island.

Col. M. N. Macteop.—The mapping of the Empire (11.30).

The mapping of the Empire has barely begun, and the lack of maps is a
serious obstacle to ordered development. Much money has been wasted
in the past on this account.

To remedy this situation the first thing is to find the money. Surveya
are most necessary in those colonies least able to pay for them. Progress
will be slow unless the money can be borrowed. ‘The Colonial Development
Fund was established for such purposes. Having found the money, the
next thing is men. Enough trained surveyors are not available. Air
survey provides a new and suitable technique, but is hampered by the high
cost of photography and the lack of geodetic foundation.

Geodetic surveys of the Empire are particularly backward eae more
energetic prosecution is especially necessary. Finally there is the question
of revision. Every scheme for systematic survey should include provision
for periodical revision.

SECTIONAL TRANSACTIONS.—E. 497

Lt.-Col. A. B. CLoucu, O.B.E.—The preparation of maps and illustrations
for geographical articles and theses (12.15).

Geographers wishing to illustrate their articles by maps can either :
(1) Draw the map de novo from their own survey material or by copying
or tracing from existing maps ; or
(2) Use an existing map as a topographical base on which to overprint
their special information.

In all such cases where they are preparing drawings in any form for
reproduction, some knowledge regarding the processes of reproduction will
be found very helpful.

In the case of (2) above, the Ordnance Survey can supply impressions in
non-photographic blue of detail or water or contours or of any combination,
on which the special material can be drawn in its correct position. This
special drawing can then be reproduced as an overprint in any colour on
the chosen map sheet, the basic topographical detail being printed either in its
normal colouring or in grey, dependent on whether it is desired to emphasise
or not the special information in comparison with the topography.

For Great Britain a choice of Ordnance Survey maps ranging between
the large scale 1/2,500 to the small scale 1/million is available.

When compiling material for subsequent reproduction in conjunction
with an Ordnance Survey map, it is wise to use the appropriate Ordnance
Survey map as the key and not to use other maps of nominally the same
scale. Otherwise subsequent difficulties in register may ensue.

AFTERNOON.

Prof. Lt. RopweEtt Jones and Mr. F. H. W. Green.—Rainfall in Kenya
and Uganda (2.15).

In Kenya there are some 230 rainfall stations, of which only 80 have
records for a period of more than fifteen years. 'The corresponding numbers
for Uganda are 35 and 14.

In both countries the stations are unevenly distributed, and in some cases
the records obviously unreliable. Even so it seemed possible to construct
maps which should aid a rapid assessment of the rainfall conditions and do
no serious injustice to the general facts.

A 1/250,000 contoured map exists for much of the area, and the isohyets
were drawn with constant reference to the relief. The usual methods of
interpolation were used in respect of the records of short-period stations.
Maps showing distribution by months for the long-period stations have
also been prepared. Amongst much else it emerges definitely that a rain
shadow is formed by the Eastern Highlands, and that there is a difference
in the distribution type for places in the same latitude but on opposite sides
of the Northern Rift.

From hourly velocity readings windroses were prepared for the three
first-class stations for selected months.

At Kampala the chief influence appeared to be the land and sea breezes
of the northern verge of Lake Victoria. 'The same phenomenon, for definite
hours, causes a deflection in the otherwise monsoon directions evinced at
Zanzibar.

Mr. E. W. GiLBert.—The human geography of Mallorca (3.0).

Mallorca, the largest of the Balearic Islands, is 1,350 square miles in
extent, almost the same size as the county of Cornwall, and contained about

s2

498 SECTIONAL TRANSACTIONS.—E.

270,000 inhabitants according to the census of 1920. The object of this
paper is to examine the distribution of population in relation to the physical
and economic geography of the island. Mallorca can be divided by its
relief into four regions. The principal feature of the relief is a range of
mountains, 45 miles long and about 10 miles broad, which form the north-
western part of the island and rise in places to heights of nearly 5,000 ft.
The south-east of the island contains a range of hills of much lower general
altitude than the northern mountains, the maximum height being only
1,500 feet. ‘These two regions are separated by a wide central plain, whose
general level is interrupted by a fourth region, the isolated mass of Randa.
The four major regions can be subdivided on the basis of the natural and
cultivated vegetation. The whole of the central plain is cultivated and
forms a vast orchard of fruit trees, principally almonds. The climate
makes irrigation essential, by wells on the plain and by tanks in. the
mountains.

Palma is the principal settlement and with its suburbs contains nearly
one-third of the population of the island. With the exception of Palma
there are no large coastal settlements. ‘The area of greatest density of
population occurs along the southern foot of the northern mountains.
A marked feature of the distribution of population in the central plain is
the absence of hamlets and villages, as population is concentrated in small
towns containing 1,500 or more inhabitants. The population is, however,
more dispersed than it was a hundred years ago.

Prof. C. DaryLtt Forpe.—Variations in the native economy of arid
regions (3.45).

A comparative review of the native economies of the arid regions of the
world shows clearly that the general climatic conditions are of less signi-
ficance than (a) particular physiographic and biological conditions, and
(6) the cultural history of the larger areas of which these desert regions
form a part. Climatic divisions into ‘ hot’ and ‘ continental’ deserts and
gradations from winter to summer precipitation appear to be largely
irrelevant to the classification of native economies.

Areas climatically and vegetationally closely similar exhibit fundamental
contrasts. | Even at the lowest economic levels the peculiar features of a
particular habitat are all-important. ‘The Coahuilla of the Mohave Desert
and the Bushmen of S.W. Africa are the one almost entirely collectors of
wild fruits and the other dominantly hunters. This differentiation is not
dependent on divergence of general physical conditions but on the sharp
contrasts in the relative abundance of particular forms of plant and
animal life.

Every type of economy is represented in arid areas, and the introduction of
various domestic animals and types of agriculture has profoundly modified
the distribution and density of settlement and the seasonal rhythms of
activity and settlement. Food-gathering economies have long been largely
extinguished in the Old World deserts of the northern hemisphere, and
comparisons of the Badawin and Saharan Berber economies on the one
hand with those of the Bushman and Aranda on the other, and of the Kazak
economy in southern Turkestan with that of the Paiute of the Great Basin,
bring out some of the profound consequences of pastoralism and access to
marginal settlements of higher culture. The penetration of higher economies
is often partial and is sometimes delayed by cultural factors. Maize culti-
vation under conditions of natural flooding has been practised for more
than a millennium in parts of the arid region of south-western U.S.A. and

|

SECTIONAL TRANSACTIONS .—E. 499

northern Mexico, but the special physiographic conditions have been utilised
only over a relatively small and fluctuating area. Considerable areas in
which springs and flood waters afforded opportunities for agriculture were
occupied by non-agricultural peoples. This region, in which sheep
pastoralism has developed among the Navajo in post-Columbian times,
affords an interesting example of the co-existence of three contrasted
economies practised by different peoples occupying a single region.

Saturday, September 9.
Excursion to Holwell Iron Works and the Melton District.

Sunday, September 10.
Excursion to Leicester, Uppingham, Peterborough, Wisbech.

Monday, September 11.

PRESIDENTIAL ApprRESS by Rt. Hon. Lorp Mesron, K.C.S.I., on
Geography as mental equipment (10.0). (See p. 93.)

Sir Epwarp A. Gait, K.C.S.I., C.I.E—Races and languages of India
(11.15).

India contains a remarkable diversity of languages and peoples. The
223 indigenous languages belong to four distinct linguistic families—
Dravidian, Austric, Aryan and Tibeto-Chinese. There is nothing definite
to show where the first two originated, but the last two were brought by
immigrants from the north-west and east respectively. Aryan languages are
now spoken by three-quarters of the population.

The ‘ Aryan’ physical type predominates in the north-west, and the
Mongoloid in the east. The people in the south, known as ‘ Dravidian,’
are a composite race. North of the ‘ Dravidian’ there is a blend, on the
west with Aryan and on the east with Mongolian.

The post-Aryan invasions did not much affect the physical type, but
those of the Afghans and Mughals brought the Muhammadan religion now
professed by one-fifth of the population.

'The existing divisions are based mainly on religion and language. The
most notable is that between Hindus and Muhammadans. The linguistic
groups may be regarded as distinct races, but in their religion and traditions
the Hindus throughout India have a bond of union which has been
strengthened by the wide diffusion of English which serves as a lingua franca.

Discussion on India (11.45).

AFTERNOON.
Sectional Lunch (1.0).

Prof. F, DrseNHAM.—Report on the Polar Year (2.30).

Dr. E. H. Se_woop.—Classification of communities by means of occupations

(3.0).
The standard set up last year at York that if 40 per cent. of the workers
are engaged in any one occupation it was sufficient to characterise that

500 SECTIONAL TRANSACTIONS.—E.

community is maintained in Scotland and Ireland. In the latter agriculture
rises in the west even to 90 per cent. of the total workers. ‘The Dublin area
differs from the remainder of the southern part of the island.

‘ Craft ? (manufacture) is confined almost entirely to the north-east, the
Dublin, Waterford and Cork areas. There is, however, one town, Clara,
which in composition is strikingly like Buckfastleigh in Devon.

In distribution the Personal Attendants class differs from that of the
other island ; whereas in England and Wales the average in rural areas is
about 14 per cent., in Ireland an average of only about 5 per cent. is noted.

Attention is called to the correlation between occupations—in some cases
the coefficient rises even to + 0-60, pointing to common governing factors,
and it is hoped that as these governing factors are isolated, a more definite
determination of governing conditions may be made.

Tuesday, September 12.

Dr. H. C. Darsy.—The geographical conceptions of a medieval bishop
(10.0).

The scholarship of the Middle Ages was far from being the narrow super-
stition we are sometimes told it was, and fewer individuals demonstrate
this better than Robert Grosseteste (c. 1175-1255). He stands a repre-
sentative figure of the medieval renaissance of the twelfth and thirteenth
centuries. Embodying Ancient Greek and Arabic learning, his writings
are characterised by their appeal to reason as distinct from tradition,
and by their critical faculty. In them is to be found the scientific geography
of the time—discussion of the sphericity of the earth, the distribution
of land and sea, causes of regional differences on the earth’s surface,
meteorological problems, and the features of oceanic phenomena. ‘Though
not free from theological preoccupation, the discussion of these topics by
Grosseteste presents an intelligible view of contemporary geographical
theory, in itself an intelligent achievement.

Dr. L. DupLey Stamp and Mr. E. C. WILLaTTs.—Changes in the utilisation
of land in the south-western part of the London Basin, 1840-1932

(10.45).

This paper represents an attempt to use one of the first sheets to be pub-
lished by the Land Utilisation Survey of Britain (1-inch, England and
Wales, No. 114, Windsor) as a starting-point for a detailed study of changes
in land utilisation in the south-western part of the London Basin. From
the MSS. records kindly made available by the Ministry of Agriculture.and
Fisheries of tithe apportionment made under the Tithe Act of 1836 it
has been possible to identify the individual fields and so to construct, for
certain parishes, a land utilisation map for the period about 1840. The
parishes especially considered in the paper are White Waltham, Berkshire
(Chalk, Reading Beds and London Clay) ; Winkfield North (mainly London
Clay, comparatively remote from the influence of London); the group
formed by Egham, Wraysbury, Staines, Ashford and Stanwell (forming a
strip from the Bagshot Beds, through London Clay to the Thames Gravel
and alluvium) ; Ashtead and Headley (Chalk and Plateau Gravels of the
North Downs and London Clay).

Apart from housing development, there has been, contrary to common
generalisation, remarkably little change in some areas—even an extension

SECTIONAL TRANSACTIONS.—E. 501

of arable land—but enormous changes in other areas, especially on tracts
of heavy soil. Amongst the factors specially considered have been soil,
slope, accessibility, value and desirability for residential purposes and
economic factors consequent upon the growth of London. A further
extension of the work has been possible in one or two areas by using
seventeenth-century manorial maps.

Prof. E. G. R. TayLor.—Economic geography of early Stuart England
(11.30).

The economic problems of England three centuries ago, as they are dis-
cussed in the literature of the period, are strikingly similar to those dis-
cussed in newspapers to-day. Over-population, the decay of rural life,
urbanisation, unemployment, the burden imposed by high wages and
rising prices on the upkeep of great estates, the ruin of the roads by heavy
traffic for which they were not designed, the dangerous depletion of timber
supplies, ‘ unfair’ foreign competition in the fishing industry, free trade
and the balance of trade, the need for improvement of internal water-ways,
for the control of flood-waters, for the reclamation of fens and marshes,
for the improvement of methods of husbandry—all these had their geo-
graphical aspects, and their brief discussion is intended to throw light on the
geography of early Stuart England.

Mr. H. C. K. HENDERSON.—Downland agriculture of East Sussex (12.15).

During the last 150 years several surveys of land utilisation on the South
Downs have been made. The first is an unfinished map of Sussex, four
sheets of which were published in an incomplete state in 1780 : the published
map is on a 2-inch scale, and was constructed by Yeakell and Gardner
in competition for the prize for large-scale county maps. Between 1836
and 1851 the tithe maps were constructed for each parish, and the roll in
most cases records land utilisation ; fortunately Sussex was almost entirely
tithable. In 1875 the Ordnance Survey issued the first edition of the
25-inch maps of Sussex, together with area books which include utilisation
details. The extent of arable activities and the crop distributions have
been mapped on a 6-inch scale for 1931, and also, for part of the region
concerned, for 1918 and 1927, by the writer.

Each of these larger-scale surveys has been reduced to the common scale
of t inch to 1 mile, whence a direct comparison of the varying extent of
arable cultivation can be obtained.

Finally, a statistical summary of crop distributions relative to various
factors has been compiled from the actual field distributions of crops in
1931.

AFTERNOON.

Excursion to Charnwood Forest.

Wednesday, September 13.

Mr. K. C. Epwarps.—Some aspects of the Luxemburg iron industry
(9.45).
For more than a century before the exploitation of the munette ore of
Lorraine (mainly since 1870) there existed in central Luxemburg one of the
important iron-working regions of Europe. The mineral was obtained

502 SECTIONAL TRANSACTIONS.—E.

from alluvial deposits and the workings, though widely scattered, were
situated in relation to the forests and streams. Furnaces and forges were
often far apart, and coal and coke were not in general use until after 1865.

The working of the minette ore in the southern extremity of the Grand
Duchy caused a striking change in the location and character of the industry.
The delay in this development was due almost as much to the lack of trans-
port facilities as to the fact that the ore demanded special treatment. ‘The
interesting sequence of changes accompanying the evolution of the industry
is shown by a study of the works at Fischbach (1768), Eich (1845), and
Esch-sur-Alzette (1870).

The progress of the modern iron and steel industry has exercised important
effects upon the distribution of population, emigration and immigration,
agriculture, and upon economic relations with the neighbouring countries.

Mr. R. E. Dicktnson.—The metropolitan regions of the United States of
America (10.30).

(1) The distinctive characteristics of a metropolitan city. The criteria
to be adopted in selecting cities which have attained some degree of metro-
politan development (population, per capita sales of manufactures,
wholesale and retail goods, distribution of merchandising space, markets,
Federal Reserve banks).

(2) On the basis of these criteria, the selection and classification of those
cities which have attained metropolitan proportions.

(3) The character and extent of the ‘ zones of influence ’ of a metropolitan
city, illustrated with specific examples from the United States (twin cities,
Chicago, Philadelphia).

(4) The areas served by the metropolitan cities of the United States in
some of their distinctive functional capacities, based on an examination of
maps showing areas of supply of live stock and grain markets, wholesale
trade areas, areas served by district branch houses of representative com-
panies, Federal Reserve districts, newspaper circulation areas, etc.

(5) The delimitation of composite metropolitan regions, and an attempt
to classify the metropolitan centres, on the basis of function and growth,
in relation to the extent and character of the regions they serve.

Miss H. G. WaNKLYN.—The Niemen River: a neglected waterway
(11.15).

The Niemen River rises in the marshes of White Russia and flows into
the Kurisches Haff just south of the Baltic port of Memel. It could be made
navigable as far as the Russian village of Naujas Svierzenes, about 892 kilo-
metres from its mouth, but as yet only the lower reaches have been regulated.

Before the war the Niemen basin was the natural hinterland of the
German port of Memel, as wood, the main export from Memel, was
floated down the Niemen from the forests of White Russia and Russian
Poland.

By the re-alignment of frontiers after the war, the transit trade of the
Niemen River was interrupted by two frontiers : that between Soviet Russia
and Poland, and that between Poland and Lithuania. ‘The river also forms
the boundary between Germany and Lithuania. The multiplication of
frontiers in this area has been especially disastrous, as owing to the dispute
between Poland and Lithuania over the Vilna region there has been a com-
plete severance of relations between the two countries for the last fourteen

years.
Passenger traffic between Poland and Lithuania is diverted through Latvia,

SECTIONAL TRANSACTIONS.—E, F. 503

and the doubtful absorption of the German Memel territory by the new state
of Lithuania has also added to economic difficulties.

In consequence the dredging of the Niemen has been neglected and the
timber trade has declined steadily. The victim of bad political relations
has been the Memel port, whose chief export commodity is now relegated
to the Vistula waterway.

The undesirability of the boycott is dawning on both governments.
Poland, by seizing the Vilna district by force, has stultified its economic
development and deprived it of its natural outlet. Lithuania has lost the
greater part of her transit trade.

SECTION F.—ECONOMIC SCIENCE AND
STATISTICS.

Thursday, September 7.

Sir Grorce BucuanaNn, K.C.I.E.—The economic position of Burma (10.0).

Burma has always been famous for its rice, but a tremendous impetus
was given to paddy cultivation by the opening of the Suez Canal in 1869,
which, by lowering freights between East and West, greatly stimulated the
demand for rice in Europe.

Burma has in half a century reclaimed and brought under cultivation for
paddy 124 million acres of land, and is to-day the greatest rice exporting
country in the world, with an annual export of 3 million tons of cleaned
rice.

This great work carried out entirely by Burmese peasantry; initial
advantages being large areas suitable land; regular rainfall ; single crop
over whole area, and cheap labour from India. No capital in country ;
cultivators financed by Indian moneylenders, supplemented by co-operative
societies, which began well but ultimately collapsed. Milling of rice and
its export in hands of Europeans and Indians. World distribution and
value. Other agricultural products and development of oil and teak
industries. Total value of Burma’s export trade and how distributed.
Burma not a manufacturing country and dependent on outside sources for
all manufactured goods. Extent and value of import trade, penetration of
Japan in textile requirements.

The political situation and introduction of politics in country not con-
ducive to happiness and prosperity of people.

Revenue and expenditure and balance of trade.

Disastrous effect of world crisis and unfortunate dependence of Burma
on one staple trade. Increasing competition with other rice-producing
countries. Seventy per cent. of population engaged in agriculture, prin-
cipally paddy cultivation ; unless fair price obtained for paddy, which again
is dependent on price of rice in world’s markets, whole economic structure
must fall to ground and people revert to primitive standard of living.
Alternative : development of other agricultural products and make country
self-supporting by creation of industries ; this difficult because no coal in
country, nor possibility of hydro-electric power in Lower Burma at
economic price.

PRESIDENTIAL AppRESS by Prof. J. H. Jones on The Gold Standard
(11.30). (See p. 109.)

504 SECTIONAL TRANSACTIONS .—F.

Friday, September 8.

Prof. ARNOLD PLaNnt.—Economic theory of patent and copyright law
(10.0).

There has not so far been sufficient discussion by economists of the
economic effects of the systems of patents for inventions and of copyright
for literary and artistic production. ‘Two contrary assumptions have been
made concerning the relationship between the patent system and the display
of inventiveness. On one side it is asserted that without patents there
would be no inventions ; the profusion of innovation in our own time in
fields which fall outside the range of patent legislation suggests that this is
unlikely. On the other side it is assumed that the patent system has little
influence upon the amount of inventing that takes place, but that it serves
to direct inventing into the fields of greatest social advantage ; an assump-
tion which in turn conflicts with normal expectations concerning the dis-
position of the factors of production in a monopolistic regime. 'Thecon-
ditions making for the display of inventiveness are analysed and the patent
system is shown to influence the amount of invention of the type that is
induced by changes in economic conditions. Light is shed upon these
questions, and upon the relation between variations in prosperity and
variations in the output of ‘inventions,’ by an analysis of the statistics
relating to applications for patents in various countries. ‘There are reasons
for concluding that the patent system results, at least in the short-run,
in misdirection of the factors of production. ‘The arbitrary and clumsy
nature of this system of encouraging an infant industry is examined.

The closely parallel copyright legislation is shown on economic analysis
to be equally arbitrary in its provisions and lacking in clear basic principle.
The peculiar treatment of the right of mechanical reproduction of musical
compositions, under existing English law, is contrasted with the provisions
relating to literary and artistic works, as compared with the device of the
“Licence of Right’ in post-war patent legislation. An extension of the
application of this device would probably reduce the amount of restriction
of output made possible by this type of legislation. ‘There are, however,
administrative difficulties.

Sir ARNoLD Witson, K.C.I.E., C.S.I., C.M.G., D.S.0O., M.P.—The
effect of Suez Canal dues upon tnter-continental trade (11.30).

A statistical comparison of the incidence of tolls—both on vessels and on
cargo passing through the Suez and over the Panama Canals respectively—
shows that dues levied differ by nearly 334 per cent. in favour of the latter.
An examination of the figures indicates that the difference is sufficient to
divert trafic between London and certain Australian and Far Eastern
ports, and between New York and other ports.

The method of calculation of the dues in each case is contrasted, and it is
pointed out that they are based in each case not on the weight or bulk of
cargo carried, but on the carrying capacity of the ship. This tends to place
an unduly heavy burden on raw material as compared with manufactured
goods.

Monday, September 11.

Discusston on Technological and economic progress (Mr. R. F. Harrop ;
Prof. J. A.S. Watson ; Dr. K. G. FENELON) (10.0).

SECTIONAL TRANSACTIONS .—F. 505

Prof. H. M. Hatiswortu, C.B.E.—The work of development boards
(12.0).

Tuesday, September 12.

Prof. P. S. FLorence.—Types and supply price of entrepreneur and business
administrator (10.0).

Economists are still apt to assume that management is mainly in the
hands of an entrepreneur highly sensitive to variations in profit. In reality
there are to-day a number of types of business administrator in control of
industry, many of them with weaker pecuniary incentives.

These types include the self-made entrepreneur, the head of a family
business, the financier, the guinea-pig and ex-professional-man director,
the ex-foreman, the ex-technician, and, finally, the trained administrator.
Each type has different incentives and reacts differently to the vital problems
upon whose solution large-scale efficiency depends. Each must be assessed
differently in respect of efficiency in initiating large-scale expansion, in
co-ordinating the several departments and functions of the firm, in re-
investing capital, in making appointments, and in co-operating or combining
with other firms.

The self-made entrepreneur often fails to adapt himself and his organisa-
tion to large-scale planning and technique ; his education, experience and
individualist habits are not conducive to the successful co-ordination and
reintegration of specialists or to co-operation with other firms. The
family-head entrepreneur does not always wish to expand business in
response to the chance of higher profits; he has the fixed though high
standard of living of the gentleman of leisure, and the chance of a higher
supply price will not necessarily increase his output. The trained adminis-
trator offers on the whole the best hope that large-scale operations may be
expanded with the same initiative that the entrepreneur displays when
expanding his small-scale undertaking.

Mr. E. L. Harcreaves.—The problem of business recovery (11.30).

General view of industrial fluctuations. The different phases of fluctua-
tions. The stage of recovery. The various explanations of how recovery
occurs. The inadequacy of these explanations. The conception of an
oscillation round an equilibrium level. The neglect of long period or
secular movements. The various types of secular change and their inter-
dependence. Relative rates of change of long-period factors. Inter-
relations of cyclical and secular movements. The explanation of the
differences in different cycles. Historical considerations and some quali-
fications. Economic progress and future tendencies. Questions of policy.
Conclusions.

Wednesday, September 13.
Mr. J. Syxes.—Public expenditure and public works (10.0).

The aim is to examine some of the fundamental arguments advanced
for and against the policy of promoting public works during depression,
with more particular reference to the contemporary situation.

506 SECTIONAL TRANSACTIONS.—F, F*.

Mr. GILBERT WALKER.—A rational and economic division of function
between road and rail (11.30).

Legal regulation of railway charges makes it profitable for road carriers
to undercut the railways for all goods classed as General Merchandise, and
to operate only where trafficis dense. A rational division of function should
enable the railways to charge rates for General Merchandise competitive
with road charges, and it should ensure that road carriers find it most
profitable to compete for traffic where it is least dense.

The classification upon goods classed as General Merchandise must be
abolished and the railways allowed to charge rates competitive with road
charges. ‘They must be permitted to discriminate against goods carried
along the lighter traffic routes, and to close all unprofitable lines.

The railways will become smaller organisations ; the road hauliers will
have to work less lucrative routes, and the competitive relations between
traders will be disturbed. The alternative to this is a monopoly which must
include all lorries run in competition with the railways. In either case the
disturbance to vested interests may be great enough to make an economic
division of function unobtainable.

If the existing and most uneconomic division of function cannot be
avoided the railways must be protected from road competition by restricting
road transport much more severely than is attempted by the Road and
Rail Traffic Act.

DEPARTMENT OF INDUSTRIAL CO-OPERATION (F*).

Thursday, September 7.

AFTERNOON.

Discussion on Organisation as a technical problem (Chairman: Dr. E. F.
ARMSTRONG, F.R.S.) (3.0) -—

Major L. UrwickK.—Organisation as a technical problem.

Importance of organisation. Principles which should govern human
association of any kind can be studied as a technical problem irrespective of
constitutional, political or social theory, the purpose of the particular under-
taking or the personnel composing it. The work of Mooney and Reilly.
Co-ordination as the main principle of organisation. The ‘span of control’:
Graicunas’ theory. Lack of recognition of the limitations imposed by the
“span of control.’ League of Nations organisation. 'The British Cabinet.
Methods of dividing up activities : the ‘ line ’ principle and the ‘ functional’
principle. Effect of increasing specialisation, due to increasied scientific
knowledge on co-ordination. Subdivision and delegation of the: work of
co-ordination. The ‘ staff’ principle. Two sets of factors to be studied
in any scheme, the allocation of duties and responsibilities and 1:he relations
which result. ‘The relations of a ‘ staff’ offieer in the British Army’. The
effect of such relations in the co-ordination of a single function : supply.
The co-ordination of all functions in a British division. A parallel problem
in industry: purchasing. Translating technical principles into operating
practice. The problem of personalities. The historical approach; an
army example. The importance of comparative study : an industf ial
parallel of to-day.

SECTIONAL TRANSACTIONS.—F*. 507

Mr. A. B. Biaxe.—Trade associations and combinations.

(1) Historical aspect.
(2) Extent.and significance.
(3), Types of combination:
A. Permanent.
B. Terminable.
(4) Aims, and inherent advantages and disadvantages.
(5) Legal status and legislative restriction.
(6) Formation. ‘
(7) Conclusion : constructive uses and the current trend.

Friday, September 8.
AFTERNOON.

Discussion on The réle of accountancy in scientific management (Chair-
man: Mr. ALFRED SALT) (3.0) :—

Mr. F. R. M. ve Pauta—The réle of finance and accountancy in the
management of large business combines.

The new problem that has arisen by the introduction of the modern
large-scale organisation. Successful administration, management and con-
trol are absolutely dependent upon a sound organisation throughout.

The administration of a large business combine, with its wide-flung and
countless ramifications, is affected by every movement in the economic life
of the world.

The point of action is often far removed from the seat of management.
The problem is how such an organisation is to be successfully managed and
controlled. Management itself is becoming a new science. Finance is
the basis of industrial enterprise. Finance, including accountancy, must
be one of the main divisions of the organisation of a large business, the others
being production, purchasing and selling. The placing of the finance division
in the organisation of a business. The functions and responsibilities of the
finance division and the part it should play in control and policy decisions.

The accountancy organisation and the interlinking of same with a system
of budgetary control, costing and statistical records. ‘The way in which
this organisation should be used in the management of such a business.
The type of personnel required and their training. An outline of the
organisation of the finance division, centralisation and decentralisation.
The great need for speed in the production of figures, reports, etc. The
objects of a budgetary control system.

Prof. WM. ANNAN.—The réle of accountancy in the average business.

Introduction.—Post-war industrial conditions outcome of invention,
scientific discovery, world-wide competition and high taxation. Indus-
trialists have sought to overcome adverse conditions by combination, and
formation of large units.

Classification of business—Big business favoured by Government and
Trades Unions. Encouragement of mergers and holding companies.
Reaction towards individualism and average-sized business. Proportion
of whole country’s trade carried by such.

Need for statistics. —Statistics necessary for average-sized business as for
large concerns. Possible without expert staff and expensive equipment if

508 SECTIONAL 'TRANSACTIONS.—F*.

book-keeping system properly planned. Réle of accountancy to plan
system and provide figures to guide principal. Freedom to concentrate on
manufacturing (or buying) and selling essential.

Education of book-keepers.—Methods of preparation of statistics insuffi-
ciently emphasised by current text-books. Elaboration desirable. Mean-
time, under proper supervision, book-keepers can meet requirements.

Kinds of statistics—No general forms. Each business own peculiar
problems. Attitude of owner and book-keeper. History of specific case.
Statistics produced without extra cost. Main statement comparison of
Working Capital monthly, and monthly Manufacturing or Trading and
Profit and Loss Account. Examples given and method of compilation
explained. Budgeting for sales, estimates of gross profit, expenses and
net profit, with proper form of standard costs. Periodic comparison

with actual results. All a preventive against price-cutting and ultimate
bankruptcy.

Monday, September 11.
AFTERNOON.

Discussion on The psycho-physiological requirements of modern factory
equipment, including particular instances of applied physiology and
psychology (Chairman : Sir Henry Fow ter, K.B.E.) (3.0) :—

Mr. G. P. CRowDEN.—The practical value of physiology to industry. 7

Physiology, the medical science which deals with the working of the normal
healthy body and the daily needs of man, has a dual field of application in
industry, namely, to the worker in relation to his work and to the products
of manufacture. Nearly sixteen million men and women in England and
Wales are engaged in industry, and the daily cycle of work, fatigue and
recovery must be in equilibrium if the health, comfort and efficiency of
these workers are to be maintained.

The execution of the work without undue fatigue; the intensity and
nature of lighting requisite fora given task ; the conditions of temperature
and ventilation in factories, workshops and mines compatible with human
comfort, efficiency and health ; noise, vibration, food and clothing in rela-
tion to occupation and environment—these are physiological problems
some of which have been studied in this country and abroad, but much
remains to be done.

The products of industry, lighting installations, heating and ventilating
systems, boots, headwear and clothing for this country and the tropics,
insulation in building and ship construction and passenger transport vehicles,
manufactured food-stuffs—all these things are bought by consumers for their
better health, comfort or efficiency, and therefore the physiological needs
of man should be studied and understood.

Industrial science and physiological science should be working hand in
hand—the latter prescribing and the former providing for the wants of man.

Dr. G. H. Mires.—The human factor in relation to the design of
factory equipment and machinery.

Factory equipment and machinery has in the past been designed from the
point of view of the engineer who desires to attain a definite mechanical
result. Modern management is interested not only in the result, but in
the efficiency with which the result can be repeated throughout each working
day. An important factor in efficiency is the human being who controls’

SECTIONAL TRANSACTIONS .—F*. 509

the machine. Designers of machinery and factory equipment should
therefore take into account the limitations of those who will use the
machinery and equipment. Some of the limitations are due to :—

(1) Fatigue, which may be caused by: (a) badly arranged controls or
working positions ; (b) unduly heavy muscular effort ; (c) harmful posture,
etc.

(2) Rhythm of machine operations which do not fit in with rhythm of
worker.

(3) Working or observation points being badly placed.

(4) Attention being distracted by moving parts.

(5) Attention being distributed in cases where concentration is essential
to efficiency.

(6) Frustration of effort owing to bad design, in setting up, stripping and
cleaning machines.

Human effort can and does overcome many of the defects of machine
design, but at a great loss of efficiency. The quality of work often suffers,
and the wholly unnecessary strain is detrimental to human well-being.
For the highest efficiency the machines should be designed to fit the human
being. In cases where there are insuperable mechanical or process limita-
tions, the workers should be specially selected to suit the peculiarities of
the machine or process.

Tuesday, September 12.

AFTERNOON.

Discussion on What are the essential basic data for the organisation of
economic distribution ? (Chairman: Mrs. EtHeL M. Woop, C.B.E.)
(3.0) :—

Mr. Lawrence NEAL.—From the viewpoint of the retailer.

In the triangle—consumer, distributor, producer—our basic knowledge is
remarkably small. Vis-ad-vis the consumer we have practically no market
analysis of his purchasing power by areas or by commodities ; no assessment
of major trends in habits of spending. Nor has there been any classification
of shopping districts.

The internal structure of distribution has similarly remained unexamined.
There are distributive costs in the sales organisations of the factory, in
wholesaling, and in retailing. Further, the last-named subdivides into
types such as the multiple chains, the departmental store, the small shop ;
yet we know little about the present functions or the performance of each.

Vis-a-vis the producer, mass-distribution may be usefully viewed as the
last stage in the chain of productive processes. It requires, therefore, a
very real knowledge of the economy of the factory. The possibilities and
limitations of a material or a product in manufacture ; the dependence of
costs on the size and regularity of the market ; elasticity of demand and new
uses—such questions can only be satisfactorily solved where there is
co-ordination between production and distribution.

For a practical study of this subject attention might well be concentrated
on actual examples of individual and successful experiment.

Mr. G. I. AKEROYD.—From the viewpoint of the ‘ manufacturer-
retailer.’

Instances of the practical value of basic data obtained where manufacturing
and distributing outlets are centrally controlled and co-ordinated.

SECTIONAL TRANSACTIONS.—G.

SECTION G.—ENGINEERING.

Thursday, September 7.
PRESIDENTIAL ADDRESS by Mr. R. W. ALLEN, C.B.E., on Some experiences
in Mechanical Engineering (10.0). (See p. 129.)
Mr. Wo. Taytor, O.B.E.—Historical and engineering features of Taylor,
Taylor & Hobson’s works (11.15).

Mr. JoHN CHAMBERLAIN.—The mechanisation of knitting (11.30).
Although the invention of the first knitting machine by the Rev. Wm.
Lee, of Calverton, Notts, in 1589, was a triumph of mechanical ingenuity,
the machine was, of necessity, crude, and many scientific developments
were required before the mechanisation of that type of machine could be
achieved.. Onthe contrary, the latch needle, invented by Matthew’ Townsend
of Leicester, in 1849, was definitely adapted to mechanisation soon after
its invention. Many types of machines were introduced in the nineteenth
century, but mechanisation proceeded much more rapidly after this time,

510

and, broadly speaking, developed on the following lines :—
(1) The replacement of manual operations by automatic devices.
(2) The development of scientific methods of loop forming and loop

manipulation.

(3) The introduction of stop motions for yarn breakage, etc.

(4) The improvement in machine tools for knitting machine production.

The following table shows the extent of the progress made.

Apparatus Machine (C ee gs
» ourses or er in.
Date. or Machine. co = Revs. per a per
Se: Min.). Operator.
To A.D. 1933 | Knitting pins — — 200 to 300
or crochet
hook
A.D. 1589 | Hand stock- | One-at-once, 20 courses 1,920
ing frame 12-gauge.
A.D. 1775 | Hand warp | 20-in. wide, | 20 ,, 4,800
loom 12 needles
per in.
A.D. 1864 | Cotton’s Four-at-once, | 40 ,, 38,400
frame 30-gauge.
A.D. 1868 | Latch needle | 4 machines, | 20 revs. 192,000
circular 4 feeders,
machines 600 needles.
A.D. 1933 | Cotton’s 24 - at- once, | 70 courses 829,440
system 48-gauge.
A.D. 1933 | Locknit warp | 2 machines, | 200 __,, 1,200,000
looms 100 in. wide,
30-gauge.
A.D. 1933 | Circular 8 machines, | 27 revs. 3,110,800
machines 12 feeders,
1,200 needles.
A.D. 1933 | Seamless hose| 10 machines, | 200 ,, 600,000
machines 300 needles
X 34 in. dia.

DISCUSSION (12.15).

SECTIONAL TRANSACTIONS.—G. 511

AFTERNOON.
Visit to works of Messrs. Taylor, Taylor & Hobson.

Friday, September 8.

Mr, R. S. Capon.—The reduction of aircraft noise (10.0).

Audiometer measurements have been made of aircraft noise in flight, and
of the noise of airscrews and engines on the ground. The experiments are
described and deductions are made as to the means by which the noise may
be reduced.

It is shown that the airscrew noise depends primarily on the speed of the
tips of the blades: lower tip speeds are therefore required for quietness.
The improvement obtainable in this way is limited by the engine exhaust
noise, which is about 80 decibels in cruising flight. Effective exhaust
silencers of the baffle type can be made, but they may involve some increase
of fire risk in the event of an accident. It is estimated that the noise level
in a single-engined aircraft might be reduced to rather less than 70 decibels
(approximately that in a train with open windows) by the use of an exhaust
silencer and a low-speed airscrew.

Reduction of noise in cabins by sound-proofing the walls is briefly
considered, and some reference is made to the reduction of aircraft noise
heard on the ground.

DIscussION (10.30).

The film in engineering—Opening Statement by Mr. H. E. Wimprris,
C.B.E. (11.0).

Cinemaphotography is found to be an increasingly useful tool in scientific
and technical investigations. It may be used in three quite different ways.
The simplest of all is its use to record the rapidly changing indications on the
dials of instruments in cases where it is impossible to have an observer, or
where, if there were one, he could not make and record his observations
quickly enough ; an example is the ‘ automatic observer ’ used in the testing
of single-seater aircraft.

Another use lies in the ability of the cinema camera to make at any desired
speed a record of the position or attitude of some moving body, the films
being afterwards measured up under a microscope. An example of this,
again drawn from aeronautical engineering, is the study of the motion of the
spin of a free flying model ; another the study of the full scale motion of
porpoising in a flying-boat.

The third method of using the film is to take slow-motion pictures of
rapid movements so that they are easily followed by the eye, thus enabling
the quality of the action to be studied or demonstrated—e.g., the study of
the launching of an airplane from a catapult.

A series of short films prepared by the Empire Marketing Board are
shown to illustrate some of the methods employed in aeronautical research,
together with another Empire Marketing Board film illustrating the technical
development of a motor transport train to open up undeveloped territories
in Africa.

Examples :
Mr. H. E. Wimperis, C.B.E.—Aeronautical research (11.10).

512 SECTIONAL TRANSACTIONS.—G.

Sir Henry FowLer.—An oversea motor unit (11.30).

Some five years ago, following certain committees, the Overseas Motor
Transport Directing Committee was formed under the Chairmanship of
Sir James Currie, K.C.M.G., K.B.E. The object of this committee was
to investigate the question of motor transport in the Dominions and Colonies,
in undeveloped areas which were not ready for railway transport. After
considerable investigation the Committee, with financial assistance from the
Empire Marketing Board and the Dominions and Colonies concerned,
decided to build experimental 15-ton units capable of traversing difficult
country, the design being largely due to a member of the Committee,
Mr. Herbert Niblett, C.B.E., D.S.O.

The film shown is that of one of these 24-wheel vehicles, which has
been successfully running in the Gold Coast since March 1933, and depicts
very clearly not only the performance of the unit, but the various engineering
difficulties which were met with and overcome by the unit.

Mr. W. WILson.—Testing electrical switch equipment (11.50).

The kinema camera is destined to play an increasingly important. part
in the testing of electrical equipment. Its principal uses are first, the
recording of the visual results of tests, more especially those effects which
may be too transient for reliable detection by the eye; and secondly, the
keeping of a continuous record of instrument readings. Examples of the
first category are breaking capacity and instantaneous carrying capacity tests
on electrical circuit breakers, for which the kinema is specially useful for
recording the emission of flame and the moving or springing of the various
parts. One of the commonest visual phenomenon is the electric arc, and
since the duration is short, it can be recorded by a simplified form of kinema
_ camera capable of very high speeds, and taking only say 12 or 24 successive
frames on a single glass plate. Half a dozen illustrations are given of
records taken with the kinema and the high-speed camera, including a
short circuit at a Grid sub-station, the blowing of a similar fuse by DC
and AC short circuits, the operation of a lightning arrester, the flash-over of
rotary converters and its extinction by a high speed circuit breaker, and the
continuous recording of no less than 17 instrument readings simultaneously
during the sea trials of an electrically propelled vessel.

Mr. Atec RopGeR.—Some psychological tests (12.20).

This film though intended primarily to illustrate a number of the more
practical tests used by the National Institute of Industrial Psychology,
shows the application of the film to that side of engineering which deals
with the selection of operatives. It also illustrates the use that can be made
of the film completely to record definite examples of dexterity and quickness
in manipulation, and in judgment, also to establish comparisons between

alternative methods.

AFTERNOON.

Visits : (i) to works of Messrs. Mellor, Bromley & Co. Ltd.
(ii) to works of Messrs. Wildt & Co. Ltd.

Saturday, September 9.

Visit to works of Messrs. John Ellis & Sons Ltd., quarry of Mountsorrel
Granite Co. Ltd., Hallgates Filter House of the Leicester City Council,
and Cropston Waterworks Pumping Station.

SECTIONAL TRANSACTIONS.—G. 513

Monday, September 11.
Discussion on Sewage treatment and disposal (10.0) :—

Mr. J. Duncan Watson.—Introduction.

One of the indispensable needs of a great city is a copious supply of potable
water, but after that water has been used and fouled, there is sometimes
a temptation to discharge it into the nearest river, regardless of consequences.

Thanks to progress in sanitary engineering, aided by biological and
chemical discoveries, there is less excuse for inefficient treatment than
formerly ; but the multiplicity of industrial wastes admitted into sewers
accentuates the problem of what is the best form of treatment.

Land irrigation is a sound and reliable method of purifying sewage, but
it is unsuitable for the majority of urban districts.

The percolating filter has taken the place of the contact bed, but its
universal popularity is on the wane, chiefly because it tends to give rise to
smell and to engender flies in summer.

Bio-aeration or activated sludge treatment now takes first place; it is
devoid of both smell and flies, and is mechanically adaptable to the pro-
duction of an effluent which meets the requirements of the stream.

Sludge digestion is at last receiving the attention it deserves. It is

economical, efficient and final. It produces a valuable non-smelling gas
—methane—and yields a humus which is easily dried, containing about
3 per cent. of nitrogen. This method of sludge treatment has come to
stay.
Public opinion may have been slow to appreciate the work of the sanitary
engineer. Still, it has advanced steadily, and it is evidenced by recent
legislation—e.g. the Local Government Act, 1929, which contemplates
the co-ordination of urban district authorities with the object of reducing
the number of sewage purification works. The predominant example of
this is found in the county of Middlesex, where one up-to-date plant is
being substituted for twenty-nine existing sewage works.

Mr. H. F. Arter.—Legal aspect of river pollution, with special
reference to the Rivers Pollution Prevention Act, 1876 (10.10).

The Joint Advisory Committee on River Pollution in 1928 reported that
there was no lack of administrative authority for enforcing thelaw. ‘ Never-
theless it is admitted on all hands that many of our rivers are seriously pol-
luted and that the law designed to prevent avoidable contamination is to a
large extent not put into operation.’ This paper examines the provisions
of the existing law, more particularly the Rivers Pollution Prevention Act,
1876, and suggests means by which it may be more effectively enforced. The
Act deals in separate parts with solid refuse, sewage and trade refuse. It
applies to all non-tidal rivers and streams, and the duty of enforcing it is
entrusted to County Councils, Borough Councils, Urban and Rural District
Councils and Fishery Boards. The procedure is not expensive, as the
County Courts have jurisdiction to deal with all offences. The Act also
enables local authorities to give facilities to manufacturers to drain their
trade effluents into the sewers, and thus enables sewage and trade refuse to
be purified at one centre under expert management.

Prof. W. E. Apenry and Dr. A. G. G. Leonarp.—Purification of
sewage by natural processes (10.25).

Results of laboratory experiments which elucidate certain fundamental
principles involved in the aerobic purification of sewage liquors are given.

514 SECTIONAL TRANSACTIONS.—G.

By the extraction and analysis of the gases occurring in polluted waters
undergoing oxidation it has been possible to study the changes accompany-
ing the destruction of impurities occurring in true and colloidal solution in
such waters. Thus it has been established, within the limits of experi-
mental error, that equal volumes of the same polluted water undergoing
aerobic fermentation consume equal quantities of oxygen and give rise to
products which are constant in quantity, provided always that dissolved
oxygen be present in excess.

The rates of solution of oxygen and nitrogen by fresh and salt waters
have been determined and a well-defined mathematical equation obtained
connecting rate of solution, surface exposed, volume of water, temperature
and degree of saturation.

Air dissolved by water at its surface does not remain concentrated in the
surface liquid but sinks more or less rapidly, causing aeration to depths of
at least 10 ft., a process for which the term ‘ streaming ’ has been adopted.

Mr. JouN Hawortu, M.B.E.—Bio-aeration or activated sludge
(10.40).

Mr. Frank C. Voxes.—The treatment and utilisation of sludge

(10.55).

Toward. the middle of the last century the frequent epidemics, which
attacked urban populations, aroused public opinion, and gave rise to the
gradual development of pure water supplies, water carriage of the excreta,
the removal of the settleable solids from the sewage, and the oxidation of
the foul water.

Anticipations of a rich financial return from the general application of
the settled solids to the land have not been realised. In many cases it is
necessary to dispose of this offensive matter or sludge on site. Its character
can be completely altered by subjecting it to a process of digestion.

At the works of the Birmingham Tame and Rea District Drainage Board
is treated the sewage from a population of 1,200,000. The watery mass of
highly odorous material known as sewage sludge is digested in separate
tanks in two stages, pumped on to drying beds, lifted and dumped. There
is no nuisance from smell.

The size of the works required for carrying out this process has been
materially decreased recently by utilising the gaseous products of the
digestion process. The power required for other purposes has been
supplied continuously by consuming the sludge gas in engines having
a total of 1,000 horse power, the waste heat abstracted from the engine
cylinders and from the exhaust gases being used to raise the temperature
of the digesting sludge.

The rate at which digestion occurs depends very largely upon temperature,
and the provision of means for maintaining the digesting sludge at a uniform
temperature enables a sewage works to be independent of any outside source
of power.

Mr. H. R. Lupton.—Machinery for dealing with sewage (11.10).

The paper is intended primarily as an appendix to those dealing with
sewage treatment. It deals only with the mechanical appliances involved,
not with constructional and civil works.

The mechanical appliances are divided into four categories according -as
they deal with (a) crude sewage, (b) sewage liquor, (c) sludge, (d) screenings.

SECTIONAL TRANSACTIONS.—G. 515

Under the first category are described (i) pumps and ejectors, with special
reference to unchokeability, (ii) settling tank mechanisms and screening
plant.

Under the second category, in addition to (i) pumps, fall (ii) aeration
devices, including agitators and surface aeration plant, sprinklers and air-
compressors with diffusers, and (iii) dosage apparatus including chlorinators
and devices for adding precipitants, etc.

Under the third category fall (i) pumps and ejectors, (ii) stirrers, gas-
collectors, heating mechanism, etc., (iii) sludge presses and driers, grease
extraction apparatus, etc.

In the fourth category are included (i) conveyors, (ii) disintegrators.

In addition to the above, brief reference is made to special valves, floating
arms, etc., which are used in connection with sewage manipulation.

DISCUSSION (11.30).
AFTERNOON.

Visits : (i) to sewage works of Birmingham Tame and Rea Drainage
Board.

(ii) to Fort Dunlop.

Tuesday, September 12.

Mr. JosEPpH GOULDBOURN.—Shoe manufacturing machinery and some
special problems in its design (10.0).

The paper outlines the comprehensive character of the machinery and
summarises categories of special machines developed for performing certain
important operations of the many different ones into which the manufacture
of shoes has become divided. In illustration of peculiar problems which
the designer has had to solve, salient features of several machines are
discussed. These are a stitching machine, which will set a lockstitch
reliably at a selected depth in a sole as much as # of an inch thick while
sewing 1,000 or more stitches per minute ; metallic fastening machines com-
prising means for marshalling and delivering both headed and headless nails ;
a pulling over machine pneumatic mechanism for simultaneously inverting
and delivering a number of tacks to an equal number of tack driving
mechanisms ; a lasting machine for securing the upper to the insole by
staples which clinch themselves in the thickness itself of the comparatively
thin insole; a sole edge burnishing machine in which, while the sole
edge is traversing across the tool, both are automatically adjusted to the dual
sole curvatures by systems of feelers operating machine controls through
hydraulic relays, and, lastly, a pattern grading machine embodying duplex
pantograph mechanism.

Prof, Mites Wa.ker, F.R.S.—Great engineering works of profit as a cure
for unemployment (11.0).

During the last twenty years many sane engineering projects have been
brought forward in different parts of the country—underground railways
-in large towns, bridges over rivers, extensions of electric power generation
and transmission, the change from tramways to Diesel-driven omnibuses,
the change from steam-driven locomotives on our main-line railways to
Diesel-electric locomotives especially of the type containing torque-con-
version apparatus. Projects of these kinds are still before the public. In

516 SECTIONAL TRANSACTIONS.—G.

many cases the possibility of a large margin of profit can be shown. In
many the margin of profit is not sufficiently enticing to stir the people to
action. The paper deals with some of the projects which promise a fair
return and would keep employed hundreds of thousands of workmen and
workwomen.

It also deals with methods of finance similar to those proposed in America ;
for enabling the people to purchase the things that they have made or for
contributing to the cost of the future wealth-producing projects.

Mr. M. Du-Piat-TayLor.—Sea defences and reclamation of land from
the sea (11.30).

The loss by coastal erosion and the gain of land by accretion around the
coasts of Great Britain about balance, but the land lost is generally good
agricultural land, and even parts of towns or villages, and the gain is orly
sand or shingle.

The loss can be prevented by coast defence works, such as sea embank-
ments or sea walls, the drainage of clay cliffs, and groyning. Although
reclamation of land from the sea for industrial purposes may be an economic
process it is not so for agricultural purposes unless it is carried out in
combination with dredging or the disposal of waste materials.

Material deposited on reclamation areas may be material dredged from
adjoining navigation channels, which can be pumped ashore by suitable
plant. This is often cheaper than sending it out to sea to be dumped in
deep water.

House refuse may also be used for raising the level of such low-lying
lands if economical means can be found for so depositing it. In London
alone, the quantity of house refuse to be disposed of annually is 1} million
tons, and in addition, 3 million tons of sludge from sewage disposal is sent
out to be dumped at sea. The Author suggests that means of disposing
of all this upon marsh or mud land should be investigated.

As regards coast defence works, various forms of protection will be dis-
cussed and approximate costs given; and finally, various schemes for
enclosure and reclamation which have already been put forward will be
examined from the point of view of probable ultimate profit and the relief
of unemployment.

Mr. WALTON Mauenan, M.1.Struct.E.— Some canal projects (12.0).

AFTERNOON.
Visit to works of British United Shoe Machinery Co. Ltd.

Wednesday, September 13.

Mr. A. M. McKay and Mr. R. N. Arnotp.—The effect of time and
temperature on the embrittling of steels (10.0).

The effect of stress, of temperature of heating, and of time of heating
on the embrittlement of steels are considered ; brief mention is made of
results obtained from tensile and hardness tests. Results of tests showing
the embrittlement with time of mild steel after quenching from moderate
temperatures are also given; an attempt is made to correlate results and
to suggest a possible explanation of embrittling phenomena.

SECTIONAL TRANSACTIONS.—G, H. 517

REPORTS OF RESEARCH COMMITTEES (10.45) :—
Earth Pressures.
Electrical Terms and Definitions.
Stresses in Overstrained Materials.

SECTION H.—ANTHROPOLOGY.

Thursday, September 7.

Mr. K. H. Jacxson.—An aspect of Celtic seasonal literature : the weather
prophecy (10.0).

The primitive mantic tradition in Ireland included prognostications of
weather and fertility as well as prophecies relating to human affairs, the two
not being separated but treated as general manifestations of prosperity or
the reverse, and traces of the same kind are found in Wales ; certain obscure
Irish poems are to be explained in this way rather than as charms or descrip-
tions, but the distinction between charm and prophecy is not always easy
to draw. Various systems of foretelling the weather other than by direct
inspiration, particularly from observations about New Year’s Day ; perhaps
originally part of the native mantic and seasonal lore, but later much
influenced by the Latin learned tradition and disinfected from the taint of
paganism by Christian formule. Survivals in modern Celtic folklore.

The possibility that weather prophecies influenced seasonal poetry ;
similarities of phrasing common to the mantic poems and prose weather-lore
are perhaps to be found in some of the Irish poems on the seasons, and also
traces of Welsh weather-wisdom in an early Welsh poem on winter.

Prof. Dr. Juttus Pokorny.—The origin of the Celts (10.45).

People usually look for the Celtic cradle to south-west Germany and
the Rhineland, where are found the greatest number of Celtic river-names,
and where later the historical Celtic La Téne culture originated from the
western Hallstatt culture; in the Bronze, Age the so-called Tumulus
culture was found there.

Of late it has become evident that at about 1200 B.C., important move-
ments of peoples and cultures had gone to transform the cultural aspect of
the greater part of Europe. ‘The people of the Lausitz culture or urnfield
civilisation, starting from eastern Germany and western Poland, seem to
have conquered great parts of middle and southern Europe, among them
the Celtic cradle, where they became finally absorbed by the earlier Tumulus
folk. In this way the Celts of history came into existence.

The language of the urnfield people gives us an important clue to the
origin of the Celts. The urnfield colonies in Hungary and Upper Italy
can be shown to belong to the Illyrians and Venetians, two branches of the
western Aryans, and the great number of Veneto-Illyrian place- and river-
names in the Lausitz territory point to the same direction. The linguistic
isolation of the Teutonic languages (for the relations with Celtic are late)
is easily explained by the fact that their southern and eastern frontiers were
occupied by Veneto-Illyrian peoples, of whose language, the ancestor of
modern Albanian, we know very little.

518 SECTIONAL TRANSACTIONS .—H.

The Celts must be the product of amalgamation between the Veneto-
Illyrians and the Tumulus people, which may be called Proto-Celts. Since
the Aryan invaders of Italy, whose language is most closely related to that of
the Celts, seem to have come from the same region, the Tumulus people
may be identified with the primitive Italo-Celts who had remained in their
old home after the Italic peoples had left for the south.

The speaker has been able to show for the first time the close relation
between the Veneto-Illyrian and Celtic languages, and has discovered many
linguistic traces of the Veneto-IIlyrian occupation in Celtic territory. The
Aryan elements in the language of the so-called Ligurians are probably
due to an Illyrian invasion as well.

PRESIDENTIAL ADDRESS by Rt. Hon, Lord RaGLaNn on What is Tradition ?
(11.30). (See p. 145.)

Mrs. H. Wrace E.tcee.—The Earth Mother cult in N.E. Yorkshire
(12.30).

The Earth Mother is found as the Old Wife in our Moorland area, this
name being attached to sacred stones, old trackways and burial sites. The
Old Wife is the name given to the last sheaf of corn cut at harvest, in our
area known as the mell-doll. Another name for the Old Wife is Carlin,
of Scandinavian origin. As a spring goddess she is preserved to-day in
Carlin Sunday. She was worshipped as Freya and Nanna in the ninth and
tenth centuries. We have ample evidence that she was guardian of the dead
throughout the Bronze Age, and a double-axe cult derived from Crete
pervaded the district. Not only the axe, but shells, necklaces and cup-
stones are all sacred symbols of the Earth Mother. She was also wor-
shipped in the Bronze Age as a sky goddess. A hitherto unrecognised type
of megalithic monument, groups of three standing stones, represent her in
her threefold aspect. We find many traces of her cult to-day, as, for
instance, in our inn signs and bee customs.

AFTERNOON.
Mr. W. Keay.—The Raw Dykes, Leicester : a Roman aqueduct (2.15).

On the south side of Leicester, within a mile of the centre of the City,
is a grass-grown earthwork known as ‘ The Raw Dykes,’ the use of which
has puzzled many generations.

It is constructed on side-long ground, on the ‘ give and take’ principle,
the excavation on the east side being deposited as an embankment on the
west side. ‘The channel thus made is 340 ft. long, 20 ft. wide at the bottom,
72, ft. at the top, and averages 10 ft. deep. ‘There is evidence to show that
the raat (within recent years) extended towards the city for nearly
a mile.

Former writers have ascribed its use as ‘ the bounds of a Roman Cursus
or Racecourse,’ others to ‘ Some defence to the Roman Camp.’

The author contends that it is the remains of a Roman. aqueduct
tapping the river on the upstream side, for the water supply of Leicester
(Ratz), and discharging it on the downstream side.

Mr. A. T. J. Dottar.—Prehistoric and some historic communities of
Lundy, Bristol Channel (2.45).

The presence on Lundy of undoubted microliths, well-finished round
scrapers of Bronze Age type and many manipulated blades of beach-flint

SECTIONAL TRANSACTIONS ,—H. 519

and quartzite which occur in association with lean-to dolmens, standing
stones, part of a stone row, stone circles, tumuli and kists indicates that this
isolated granite island in the Severn Sea was occupied by at least two pre-
historic communities of Cornubian affinity.

Evidence on the island suggests that an early and backward settlement of
Neolithic cultural type was absorbed or replaced by a subsequent population
of Mesolithic or Early Bronze Age culture.

The earlier community seems to have produced and employed distructive
tools, including rostrated round scrapers, deeply notched flakes, limpet-
lifters and limpet-hammers.

The later community is to be associated with the more elaborate tools of
blue flint, with the stone monuments and the graves. Discoveries of barrel-
shaped collared beads and fragments of a gilt-bronze ornament, together
with cylindrical and spherical beads of cobalt glass, point to an occupation
of Lundy by a Viking or Irish Early Iron Age people. An inscribed mono-
lith bears out the former conclusion.

The island was known to the Romans as Herculea, while it appears as
Caer Sidi, the Fortress of the Fairies in Welsh folk-lore. Its recorded
history, which begins in thetwelfth century, is one of many short occupations
by a succession of transient communities, including rebellious French nobles,
Scottish sea-raiders, Spanish pirates, Turkish corsairs, English privateers,
soldiers, farmers, monks and quarrymen.

Dr. A. Ratstrick.—Developed Tardenoisian sites in N.E. England (3.15).

Many surface finds of flints of Mesolithic type have been recorded in recent
years from the North of England, but only rarely have flint sites been excavated
in a position with clear stratigraphy, until the work of Buckley and Armstrong.
This paper records several sites from the north-east coast, which occur on
the boulder clay and are covered by the coastal sand-dune belt, and several
sites from the Pennines where peat (dated by pollen analysis methods) is
the cover. Some of the coastal sites are very rich and have yielded a few
thousand flint chips and implements, sufficient to warrant a statistical
summary of the culture. The main types of worked flint are very beautiful
elongated cores and core scrapers, small circular scrapers, blades with
secondary microlithic chipping, and geometric and semi-geometric ‘ pygmy ’
points. The culture shows local development from early Tardenoisian,
and is occasionally associated with finely chipped arrow points and early
types of Neolithic implements. The relation of the sites to the sand-dunes
and coastal ‘ forest-bed ’ peats has been investigated, as well as the age of
the peat cover of the Pennine sites.

Dr, F. OswaLp.—Margidunum, a Claudian camp on the Fosse Way (3.35).

Mr. BertraM Tuomas, O.B.E.—The first crossing of the South Arabian
Desert (5.30).

Friday, September 8.

Prof. C. DaryLL Forpe.—Native warfare on the Lower Colorado River
(10.0).

The tribes of the Lower Colorado River are remarkable for their cultural
divergence from immediately surrounding peoples. They are not transi-
tional between the Pueblo peoples to the east and the Central Californians
to the west and appear to have been uninfluenced by the westward infiltration

520 SECTIONAL TRANSACTIONS.—H.

of Puebloan concepts, although there is evidence that some of these reached
the Pacific coast. One of their outstanding characters is the existence
of strong tribal sense and its association with warfare. ‘These features
are lacking among the peoples of adjacent areas. An analysis of the military
conventions and insignia ot the Lower Colorado peoples suggests unexpected
parallels with the Western Plains area beyond the Rockies. This relation
is, however, not to be explained by a late westward diffusion of Plains con-
cepts, but rather to acommon basis of military tradition, probably of southern
origin. No elaboration of military societies has occurred in the Lower
Colorado region, but the belief that military success is essential to the well-
being of the tribe and that warfare should be conducted by tormal challenge
and set battle has led to prolonged hostility between traditional enemies
within the area.

No economic objective or territorial aggrandisement is sought in warfare.
Militarism is maintained and perpetuated by magical beliefs and by the social
prestige of bravery as exhibited in conventional forms and obligations.

Prof. V. Sux.—The Eskimos of Labrador and the extinction of primitive
races of man (10.30).

The latitude of the Labrador peninsula is about the same as that of England,
and Cape Chidley in the north corresponds with the North Cape of Scotland.
Yet, owing to the North Pole currents, the whole region has more or less
the character of an arctic country. Its aboriginal inhabitants were Eskimos,
yet, at present, there are beside 800 pure blood Eskimos many mixed breeds,
White and Eskimo, and White settlers as well. There is no doubt left that
the pure blood Eskimos of Labrador, who two centuries ago inhabited also
the South Coast, and at present are restricted to the North Coast, are
slowly dying out. It is the same with the Alaskan Eskimos, and not only
Eskimos, but many of the more isolated small groups of mankind are dying
out. It is certain that the Labrador Eskimos were, for the last hundred and
fifty years, fortunate enough to be under a very conscientious and peaceful
administration, yet, in spite of that, their numbers are diminishing. For
comparison we may consider the fate of the Australian aborigines, and a
close study of both groups indicates that the main causes show the same
features. So, taken altogether, the history of primitive groups of mankind,
the downward trend of their vitality and consequent extinction may be
summarised as follows: (1) Extinction by weapon, in the same sense as
many animals have been exterminated. This is, of course, now out of
question and only of historical interest, for, in fact, all over the world
we see the working of humanitarian bodies, as, for instance, Native Health
Service, Mission Societies, etc. (2) Extinction by sudden changing of the
respective milieu. (3) Extinction by imported disease. (4) Extinction by
destruction of the natural resources necessary for the aboriginal mode of
life. (5) Extinction by mixing. The items under Nos. 2, 3, and 4 we may
include under one heading as ‘ Effects of Europeanisation,’ and these, under
the modern aspects of general pathology and teachings on nutrition and
morbidity, are of greatest importance—in fact, Europeanisation is at present
almost the only factor to be taken into consideration.

This paper is based on personal observations among the Eskimos of
Labrador, on Dr. Hutton’s study of health conditions among the Eskimos
of Labrador, on the studies of the health status of Australian Natives by
Prof. Burton Cleland, on the study of the health status of different African
tribes by Orr and Gilk and on the works of R. McCarrison, Coonoor,
South India, on nutrition and disease.

SECTIONAL TRANSACTIONS .—H. 521

Dr. L. S. B. Leaxkey.—Kikuyu marriage customs and problems arising
therefrom as a result of contact with European civilisation (11.0).

Mr. James HorNELL.—Indonesian contact with East African culture
(11.30).

Indian contact with Sumatra and Java, commencing before the opening
of our era, gave rise to a rich civilisation, coupled with much maritime
activity and the construction of large sea-going vessels with double-out-
riggers. Voyaging in these, Sumatrans formed settlements in Madagascar
about the second to fourth centuries A.D. The voyages were probably
coastwise, with calls at Ceylon, Malabar, and the East African coast. Other
settlements were made in the tenth century or possibly rather later. African
slaves formed part of the tribute sent to China from Sumatra and Java and
an Arab writer mentions a slaving expedition from Indonesia in the tenth
century.

The Bantu strain in Madagascar is probably the result of the importation
of African slaves by the Indonesian colonists.

Technological evidence also points to intimate contact. The presence
of the coconut palm, the coconut scraper, the bar-zither and the double-
outrigger canoe in East Africa is strong evidence of long-continued
Indonesian influence radiating from coastal settlements. Arab writers
mention Sumatran and Malagasy voyages to Kilwa and Mogadishu, and one
records a definite tradition of the occupation of Aden by Malagasy people.
Their influence has penetrated inland by diffusion; the Baganda canoe
incorporates features of Javanese vessels, the bar-zither has penetrated to
Lake Tanganyika and some of the beads in Rhodesian ruins have Indonesian
counterparts.

Dr. M. Fortes.—Some eae: of kinship and the family in West Africa
(12.0).

An area in the northern territories of the Gold Coast has been selected,
and the structure and functions of the family investigated. The type of
family found is common in many parts of West Africa. It is a joint family,
acting as a unit in most departments of cultural life, under the control of
a patriarchal head. While the type is constant, many variations occur.
It is proposed to investigate, on the one hand, the factors which make for the
internal cohesion of this type of family grouping, and, on the other, how its
cohesion with the greater society is preserved.

Dr. Lucy Mair.—The growth of economic individualism among African
peoples (12.30).

The essential difference between native and European economic organisa-
tion lies, not in some form of communism, but in the fact that in the native
system the mechanism of distribution did not consist in a series of exchanges
of goods with a view to profit, but was closely correlated with the whole political
system. Wealth was the privilege of political authority, and was acquired
not by economic skill or effort but by the exercise of qualities approved
by those in authority, especially wisdom in council and courage in war, and
the desire for it was thus a motive for socially approved behaviour. Wealth
carried with it the obligation of generosity to relatives or subjects, and one
treason why it was sought was because it enabled the possessor to make the
gifts required by custom on a more lavish scale than his neighbours. This

T

522 SECTIONAL TRANSACTIONS.—H.

system worked satisfactorily, largely because native wealth consisted in
a limited range of commodities in which the point of satiety was reached
fairly early.

The introduction of European economic methods has profoundly modified
such systems. Wealth is now the direct result of individual economic
effort, and the opportunities of acquiring what he desires by wage-labour
make the individual independent of paternal as of political authority.
Economic privileges begin to be abused when there is so much to be gained
by disregarding the obligations that go with them. Thus the economic
progress of Africa is tending to be a cause of serious social disintegration.

AFTERNOON.

Mr. A. F. Durron.—Inheritance of acquired characters (2.15).

The fact that many eminent men were begotten by fathers of ripe age
suggests that capability may be in some degree an acquired character and
that the older the father the greater the chance of it being acquired. The
striking difference between the frequency distributions of the paternal
ages of one thousand eminent men and those of a more normal population
supports this view.

The reason is discussed why, when the inheritance of other acquired
characters is barely perceptible, the inheritance of a development of the
brain should be comparatively striking. Further evidence is adduced in
support of the thesis. ‘The question as to whether acquired characters are
inherited is considered to be not merely of academic interest but, so far as
man is concerned, one of paramount importance. ‘The eugenic implications
are briefly discussed.

Prof. R. Ruccies Gates, F.R.S.—The blood groups as an index of racial
characteristics (2.45).

It is now generally agreed that the A and B blood groups are inherited as
dominant Mendelian units, and that the factors A, B and O are multiple
allelomorphs. The A and B blood groups appear to have arisen as repeated
mutations from O. A and O only are present in such primitive or outlying
peoples as the Australian aborigines, Bushmen, Lapps and Polynesians.
On this and other evidence A is regarded as older than B. It has probably
spread, (a) by repeated mutations, (b) by inheritance, (c) by migration of
peoples. B, which is highest in Eastern and Southern Asia, where A is
also present, probably spread later from an Asiatic centre.

The Eskimos and American Indians, when pure-blooded, are probably
all O. This is difficult to account for, as they are relatively advanced and
Mongoloid, and might therefore have been expected to have received both
A and B before crossing Behring Strait. Tests of 300 coastal Indians of
British Columbia show that they also probably had originally no B nor A,
and are thus in agreement with other American Indians. The blood groups
also. throw further light on infiltration and race mixture in the case of
Australian aborigines, Bushmen, Maoris and Indians.

Dr. Harry CaAMPBELL.—The factors which have determined man’s evolution
from a primitive primate (3.15).
The evolution of man from a Primitive Primiate has. essentially been an
evolution of brain. A study of this evolutional phase brings into prominence
certain evolutional factors: (1) The apparent potency of natural selection

SECTIONAL TRANSACTIONS.—H. 523

as compared with the transmission of acquired characters: seeing that
cerebral neurons do not multiply after birth, phylogenetic cerebral increase
must have been due to the selection of innate cerebral variations. (2) The
stimulating influence of competitive social life. (3) The possession of
exquisitely prehensile hands conferring survival value on super-average
intelligence. (4) The scope factor, which widened out from the arboreal to
the semi-terrestrial life, and from this to the wholly terrestrial life. (5) A
hunting career, which, in the case of the proto-human (who lacked the
equipment, anatomical and instinctive, of the carnivore), caused success in
the hunt to depend largely upon the possession of a nimble intelligence,
thus enhancing the survival value of super-average intelligence. (6) The
influence of polygamy: the bravest and most intelligent leaders secured
the largest number of mates, and thus left the most numerous progeny.
(7) Inter-tribal warfare, which led to the elimination of the least intelligent
groups.

Mr. A. L. ArMsTtRoNG.—Summary of recent and current excavations at
Creswell Crags (3.45).

Dr. E. H. Hunt.—The Rafai fakirs of Hyderabad (5.30).

Saturday, September 9.

Excursion to Creswell Crags, Derbyshire; Southwell Minster ;
Newark Castle ; Margidunum (in the Fosse Way).

Sunday, September 10.

AFTERNOON.

Excursion to earthworks in East Leicestershire; Burrough Camp ;
Sauvey Castle, and Castle Hill Camp, near Hallaton.

Monday, September 11.

Mr. A. W. CarpDINALL.—The strengthening of superstitious beliefs among
the tribes of the Gold Coast (10.0).

It is commonly agreed that contact with Europeans has been to a con-
siderable extent destructive of African social, political and religious insti-
tutions. This is only partly true; actually in certain spheres the reverse
has been the case.

The most prominent features of religion as observed in the Gold Coast
are sumanism, nature-gods and witchcraft. Complementary to these are
the observance of omens and a deeply ingrained belief in luck.

In these European contact tends to increase superstition through example,
inquiry, acquiescence and even belief therein by individuals. Authority
has been forced on many occasions to recognise and support beliefs that
were dying out ; and in the case of witchcraft European Administrations
“have been placed in the dilemma either of recognising it in order to prohibit
‘its practice or of strengthening its power by forbidding measures taken by
the indigenes against its machinations.

524 SECTIONAL TRANSACTIONS.—H.

The numbing effect of omen-taking, consultations with soothsayers and
similar practices has not hitherto received the attention it deserves. Most
Gold Coast natives will do nothing without observing the ritual of the
omen. Thus he naturally tends to become more and more engulfed in
the ruts of custom. The introduction of new ideas by Europeans has
increased the opportunities and broadened the outlook of the native, and
thereby enlarged immensely the field and scope of this practice.

Finally the attribute of luck given to one who has power or success has
been inevitably attached to the European. This has resulted in magnificent
loyalty, which in turn has ensured success and therefore confirmed the belief.

Dr. R. S. Ratrray, C.B.E—Present tendencies of African Colomal
Governments (10.40).

The British system of governing her Colonial possessions in Africa may
be conveniently summed up in the phrase ‘ Indirect Rule.’ By this is
implied, (a) the administration of the African masses by or through Africans
on lines conforming to their own national customs and traditions, and
(6) that the European is only there to guide, with a minimum of interference,
being prepared eventually to quit, leaving the African ‘ to stand alone.’

A certain long-standing self-complacency, regarding this system—arising,
perhaps, from the fact that all lovers of Africa and her people desire to see
the African national genius preserved, and because ‘ Indirect Rule’ seems
the only way of attaining this end—has begun to give place, in the minds
of some of its staunchest adherents, to genuine doubts and grave anxiety.
It seems certain that the system will very soon have to withstand onslaughts
both from within and from without. The assault from the inside will come
from the masses of the people themselves, who are likely to become estranged
owing to the undoubted tendency of ‘ Indirect Rule,’ as now applied, to
build up centralised African autocracies, disregarding the bases of former
African constitutions and states, which were decentralised and democratic.
The attack from the outside will be delivered by that ever-growing educated
African element who feel aggrieved, because they sometimes appear to be
excluded by a system where Western education and Western lines of progress
seem at a discount.

Were neither of these dangers ever to materialise, there would yet be a
third. Does ‘ Indirect Rule’ mean that we are to build up states, which,
while perhaps being Arcadian for the anthropologist, and possibly a model
for barbaric or medizval sovereignties, would nevertheless be greatly
handicapped were their sheltered privacy to be rudely invaded, and were
they suddenly called upon to stand alone and unprotected amid the rough
forces of the ever-changing world around them ?

I believe I am voicing the opinion of the majority of educated Africans
when I state that ‘ Indirect Rule’ and ‘ Anthropology ’ are both regarded
by them as veiled attempts at ‘ keeping the Africans in their place.’ Yet,
without their co-operation, the whole structure of ‘ Indirect Rule ’ and any
permanent value accruing from anthropological research must surely
crumble. ‘These and other questions are briefly discussed.

Sir Ricumonp Patmer, K.C.M.G.—Stone circles in the Gambia Valley
(11.25).

(1) A short survey of the ethnic factors present in the Western Sahara
and Sudan in the period a.D. 600-1400, distinguishing between the stocks
known as Sarakolle, Jolof, Tuculor, Sereres, Mandinka, etc., the primitive
Saharan stock known as Nemadi.

SECTIONAL TRANSACTIONS.—H. 525

The Nemadi, it is believed, represent the peoples who, as far back as can
be ascertained, were the original Wangara—i.e. Hamite or Kushite nomads
and hunters, ‘people of a place’ or, perhaps, ‘ cave.’ It was intermarriage
between the Nemadi and the darker races round them which produced the
negroid Wangara or Wakori who were the subjects of the early kings of
Gana.

The term Wangara continued to be applied to the Mandinka negroids
after they invaded from the south the region called Aukar or Wagadu
about A.D. 1200.

The Nemadi, the Sereres, and possibly after A.D. 1200 Jula-speaking
Mandinkas, represent the Wangara or Gangari stock which fused with nomad
Fulbe Barbars in Hodh and Aukar about A.D. 900-1000, produced the so-
called Tucolor or Takrur, commonly called Fulahs or Fulani, and Taurud
by Sultan Muhammad Bello of Sokoto.

The Sarakolle, on the other hand, are the descendants of mixed marriages
between aliens of Jewish or, at least, Syrian origin, who towards the middle
of the first millennium a.D., by peaceful penetration, developed the ‘ gold
trade ’ with Bambuk from Morocco and Gana, and Sus.

(2) The ‘Stone Circles’ of the Gambia and Sine in Senegal are described,
and their probable connection with the mode of burial practised by the
Sarakolle kings of Gana is shown—a mode of burial which must have been
common to many Barbar or half-Barbar tribes extending across the Sudan
to Bornu and Borku in the period A.D. 600-1000.

In so far as burials are concerned, the interior of the circles presents the
same features as those excavated at El Walaji near Timbuctu, at Katsina,
and in Bornu.

The question arises, why were these burial mounds surrounded with
menhirs, and how is it that the stone-work of these menhirs is so good ?

The answer to the first question is that the menhirs correspond to the
stockade of a town or compound ; to the second, that the stone-work must
have been due indirectly to guilds of Jewish and Syrian stone-masons who
flourished at Sijilmessa in the eleventh century, as also at Kumbi, the Gana
capital.

The geographical distribution of the circles, as well as other considera-
tions, show that they were erected at a period when the influence of Gana
extended to the Gambia River, before the rise of the Malinki towards
A.D. 1200, and thus that traditions enshrined in the fourteenth-century
maps concerning the ‘ Nile of Gana’ should be interpreted as referring to
the towns which created these stone circles, and the ‘ Gambia River’ as
being the principal mouth of the ‘ Nile of Gana.’

Dr. J. H. Hutron, C.1.E.—Megalithic work in Assam (12.10).

AFTERNOON.

Mr. E. G. Bowen.—Hill forts and valleyward movements of population
in Wales (2.15).

A classification of the chief early earthworks of the Principality indicates
the importance of the following types : the contour camp, the promontory
fort, the rectangular earthwork and the motte-and-bailey castle. These
groups cover a wide range in time, and a detailed examination of the earth-
works of the county of Carmarthen shows that each has a distinct altitudinal
province. The average altitude of the contour camps is about 600 ft., the
promontory forts about 430 ft., the rectangular earthworks about 250 ft.,

526 SECTIONAL TRANSACTIONS.—H.

while that of the motte-and-bailey castles is about 180-190 ft. With the
exception of the promontory forts whose general altitude depends on
physiographical factors, it is suggested that this altitudinal sequence illus-
trates changes in human economy over the period represented by the age
of the earthworks concerned. ‘The contour camps, together with a large
number of the promontory forts, occur beyond the highest level of early
cultivation, and their occupants were interested mainly in mountain pastures.
Earthworks of rectangular form, situated mainly on the lower hill-slopes,
suggest that their occupants had but an intermittent interest in the upland
pastures, which they visited perhaps only during the summer season. The
location of the motte-and-bailey castles illustrates that the homes of the
newcomers were definitely in the valley bottoms, associated with an arable
as opposed to a pastoral economy. Though the conquest of the once
densely forested valleys was complete by this time, interest in the uplands
continued, as is shown, by the survival of seasonal transhumance in Wales
throughout the Middle Ages, and even into our own time.

This survey has been undertaken for the forthcoming History of Car-
marthenshire, and will form part of a section which is being prepared in
collaboration with Dr. Cyril Fox.

Mr. R. U. Savce.—The distribution of the belief in fatries (2.45).

Prof. W. W. Jervis and Mr. S. J. Jones.—The village of Congresbury,
Somerset : a study in land tenure (3.15).

Congresbury is situated 12 miles south-west of Bristol on the main
Bristol-Weston road. It has particular interest for the student of land
tenure because in two of its common meads—the East and West Dolmoors—
a curious method of annual, land allocation persisted until the local
enclosure Act of 1811. ‘The redistribution took place on the Saturday
before Old-Midsummer. Each man having a claim to land in the Dolmoors
had a distinctive mark which was cut on a number of apples equal to the
number of strips to which he was entitled. As each acre was measured,
with a chain the length of which had been checked along the central aisle
of Puxton Church, one of these apples would be drawn from a basket by
a small boy. The mark on it would be cut in the turf, and thus the owner-
ship of the acre for the ensuing twelve months would be decided. The
main objects of this paper are to study the manner in which these holders
settled jointly questions concerning these common meads, and to make
a contribution towards the solution of the problem of this curious survival.
The data presented is derived mainly from surveys and from the accounts
of the Overseers of the Dolmoors, the latter covering the period 1685-1766.
It is shown that the Dolmoors were comparatively poor land which con-
tinued to be allotted annually at a time when most of the better land had
been enclosed. The customs noted in connection with them probably
once operated over the whole of the village land. The Dolmoors are, in
fact, remnants of the common meads around which have persisted ancient
customs, the origin of which cannot yet be.definitely determined.

Dr. Cyrit Fox.—The colonisation of Britain with special reference to the
Midlands (5.30).
The geographical relation of Britain to the Continent is perhaps more

familiar than its structural character; both aspects are found to be’of
primary importance in the study of the colonisation of the island from

SECTIONAL TRANSACTIONS —H. 527

Neolithic times onwards. Broadly speaking, Britain south of the Forth-
Clyde isthmus consists of two parts, the Highland Zone to the west, and the
Lowland Zone to the east.

The structure and soil-character of Lowland Britain explain in large
measure the distribution of the population in this, the most important half
of the country, in early times. ‘The chalk formation forms the main frame-
work. To the west and north-west of this complex lie the limestone ridges
of the Mendips and the Cotswolds ; an extension of the latter (the Jurassic
outcrop) leads by way of Lincoln Edge to the Humber, beyond which is
a habitable outlier of chalk—the Yorkshire Wolds. Waterways such as the
Thames, the Fen rivers and the Trent provide easy access for invader or
trader to every part of the Lowland Zone.

The chalk and limestone downlands, gravel terraces by the rivers, and
sandy heaths as in East Anglia, provide the settlement areas most sought
after by early man; he shunned the claylands, the gradual utilisation of
which is the story of civilisation as expressed in geographical distribution.
The large extent of clay in the Midlands hindered the occupation and
development of this area of Lowland Britain.

EVENING.

A folk dance exhibition by a traditional team from Great Easton,
Leicestershire, and others, with local folk songs. Introductory remarks
by Mr. Eric Swirt (8.0).

Tuesday, September 12.

Mr. OLiver Davies.—Sotiel Coronada : an illustration of Roman mining
technique (10.0).

The paper describes the remains of Roman mining and metallurgy’ at
Sotiel Coronada and Sta. Rosa in south-west Spain on the Odiel. At
Sotiel there were two periods of working, one by a Roman capitalist about
the first century B.c., and the other probably by a government official trained
at Rio Tinto of a rather later date. The latter worked to rule, though his
knowledge was limited ; interesting evidence is to be found as to Roman
methods of prospecting and surveying, the sections of their shafts, and their
pairs of shafts. In the second period an iron tool was used, probably a gad ;
in the first, it is likely that the rilled stone hammer was still common, and
indeed this tool almost certainly continues until Roman times. Finally
some remarks are made about a metallurgical establishment exposed at
Sta. Rosa ; both liquation and cupellation seem to have been practised here,
and there were found a smelting furnace and what appear to be cupels.

Miss D, A. E. Garrop.—Excavation of the Mugharet el-Tabun, Mount
Carmel (10.30).

Mr. T. Burton Brown.—The Transition from the Neolithic Period to
the Bronze Age of Western Asia (11.0).

Prof. V. GorDON CHILDE.—WNotes on some painted potteries from India
and East Iran (11.30).

Corresponding to the uniform geographical area of alluvial cultivation
dependent on a single river system and the advanced urban civilisation

528 SECTIONAL TRANSACTIONS.—H.

developed under these conditions, the painted pottery of the Indus civilisa-
tion from Amri on the lower Indus at least as far as Harappa on the Ravi
500 miles away is astonishingly uniform and at the same time highly sophisti-
cated. Its individuality is expressed in a self-conscious style the distinguish-
ing peculiarity of which is the free use of repetition motives (i.e. motives
which can be repeated indefinitely in any direction). ‘Though doubtless
inspired by textile models, this style finds so far no parallels in the third
millennium or earlier except perhaps in Crete.

Baluchistan and Waziristan, broken up into a number of discrete valleys,
did not become the scene of a higher civilisation, but exhibit a variety of
barbaric ceramic groups. Both the black-and-red-on-red wares, com-
monest in Waziristan and the black-and-red-on-buff or cream, commoner
in Baluchistan and absent from the Zhob valley, seem closely allied one to
another and to the Indus ware both technically and in the motives employed.

Shahi-tump (funerary) ware is closely allied to that of Susa I both in
forms and in specialised motives, notably the ‘ Maltese square ’ decorating
the centres of dishes at both sites (and also at Samarra). Sherds could be
found illustrating the transition from the prevailing grey tint to a pink; in
Sistan the same transition is illustrated as well as that to a green tint indis-
tinguishable from that so common on al’Ubaid and Samarra wares. The
connection in the pot-fabrics is confirmed by other graves goods—lapis
lazuli beads, alabaster vases, stamp seals, axes of copper—common to Shahi-
tump and Susa I. The Shahi graves indeed reveal an extension eastward
of Frankfort’s ‘ Highland culture’ in a very pure form and precisely that
represented at Susa itself. Yet these graves cannot be earlier than the
third millennium and must be later than or partly contemporary with the
Indus culture. They therefore demonstrate the direction of the spread of
the Highland culture eastwards, not vice versa—but afford no clue as to the
sources of the common elements in the Indus and Sumerian ceramic
traditions.

The pottery from Nal and Nundara in Baluchistan is more sophisticated
and shows a deliberate style. 'The designs are outlined in black on a pale
slip and filled in with plum red and sometimes other colours. ‘This fabric,
though in time probably contemporary with the Indus black-on-red wares,
might be regarded as a development of the black-and-red-on-pale-slip ware
from Amri in Lower Sindh which is older than the classical Indus ware.
Amri ware in its turn has technical and stylistic affinities to the Jemdet Nasr
ware of Mesopotamia, while, on the other hand, some designs foreshadow
the typical Indus system of repetition motives.

Dr. C. L. WooLtey.—Ur : the archaic period (12.10).

AFTERNOON.

Dr. L. S. B. Leaxey.—Excavations at Apis Rock, Tanganyika Terri-
tory (2.15).

Mr. G. KincsLey RotH.—The decaying ee and crafts of Fiji (3.0).

Since the advent of European and other civilisations to Fiji which began
over a hundred years ago the practice of the arts and crafts of the indigenous
population has progressively decreased and processes have changed. ‘The
manufacture of bark-cloth and of pottery may be instanced as examples of
arts which in some districts are quite obsolete or in others have been

SECTIONAL TRANSACTIONS.—H. 529

considerably modified by the use of foreign tools or vessels. Such use of
introduced implements has in itself caused a number of ancillary occupations
to be forgotten. Similarly the means adopted for personal enhancement are
now largely those used by Europeans: clothing has replaced the use of oil
and native-made ornaments are now rare and becoming rarer because no
longer made. The Kava ceremony is an example of a custom which has
stood the test of pressure from extraneous influences, only, however,
because it is a ceremony essential to many social occasions. 'Tatuing is
not now practised, but the processes have not yet been fully described.
The old men to whom one naturally turns for information are passing out
and with them is being lost the possibility of recording customs hitherto
unrecorded, for the younger generation take little interest in the practices
of their forefathers.

Wednesday, September 13.

Prof. E. E. Evans-PritcHarD.—The nature of bride-wealth among the
Azande (10.0).

Dr. A. N. Tucker.—Primitive music in the Southern Sudan, with tllus-
trations on native instruments (10.40).

This paper is concerned only with the pagan tribes of the upper reaches
of the Nile, not with Arabs.

Music plays a great part in the life of these people, and has many aspects.
A very tentative analysis of Nilotic music is here given, obtained from
studying their songs and illustrated with some of their musical instruments.

Nilotic scale —Fundamentally pentatonic, but difficult for us to ascertain
which note may be regarded as the ‘ key’ note in any song. Certain notes
in any song seem to vary, within half a tone, according to the mood of the
singer, which have a profound influence on our interpretation of the song.
These the author calls the ‘ uncertain ’ notes.

This fluctuating pentatonic scale is illustrated on flutes from the Acholi
country, which give a reliable scale (since their intervals cannot be altered
by any ‘ tuning’; in other instruments, one has to rely on a conception of
native tuning).

Rhythm.—This aspect of African music is by far the harder for Europeans
to grasp. In playing the instruments here, the rhythm is relatively steady,
and is often marked by tapping the instrument or the ground. The main
rhythms are 4/4, 3/4 and a fast 6/8. Drum rhythms, which are the most
complicated, are not dealt with here.

Types of instruments.—F lute, horn, harp, lyre, sanza, and their distribu-
an in the Southern Sudan, and their probable origin. Songs to illustrate
their use.

Dr. S. F. Napvet.—Anthropological aspects of musical research, with
illustrations by gramophone records (11.25).

This paper demonstrates the réle which the study of primitive music
can play in anthropological research. Central phenomenon of human life as
it is, music becomes a paradigm of that complex interrelation and intersection
of the different scientific aspects which is so characteristic for anthropological
method. The study of music in primitive society can even claim to open
to anthropology new ways of approach to some of these aspects. Four

T2

530 SECTIONAL TRANSACTIONS.—H, I.

main aspects are dealt with in detail, and are illustrated on gramophone
records of primitive music.

(1) The sociological aspect. Music as general enjoyment and as social
privilege in primitive society. Professional musicians. Music as a central
factor in religious ceremony.

(2) The psychological aspect. General laws established by the psychology
of sound can explain certain widespread characteristics in primitive music.
Thus the fluctuation of intervals can be derived from psycho-physiological
factors, or the development of a certain primitive polyphony (the so-called
‘ Parallel-Organum ’) appears to be due to the elementary psycho-physio-
logical phenomenon of the ‘ similarity of tones.’

(3) The aspect of historical connection. Historical relations, borrowing
and diffusion, have to account, in certain cases, for corresponding musical
styles in different areas, thus checking very often the psychological aspect
(e.g. the ‘ historical’ explanation of the Parallel-Organum suggested for
certain areas). Musical instruments become here specially important.
Built on principles of physics, and bound up with measures, they offer
most accurate and objective criteria for establishing cultural relations
(e.g. the ethnology of the African ‘ marimba ’).

(4) The racial (biological) aspect appears to be tangible through music—i.e.
through certain musical characteristics which are deeply rooted in biological
factors (e.g. the motoric type of man). It is tried to illustrate this as yet
very tentative approach on the melodic motion-type characteristic for the
songs of two racial groups: the American Indian and the Austronesian.

SECTION I.—PHYSIOLOGY.

Thursday, September 7.

Dr. F. W. Epripce-Green, C.B.E.—A criticism of Roaf’s theory of
colour vision (10.0).

Whilst Roaf’s work on colour vision and very fair criticisms of the work
of others deserve great praise, his theory presents the same difficulties as
any form of the trichromatic theory. ‘There is no evidence of any trichro-
matic light perceiving apparatus in the human retina. Houstoun has shown
that the trichromatic theory is mathematically untenable. The chief objec-
tion to it, however, is that like every other theory but mine, it will not explain
colour-blindness, particularly those facts predicted by my theory. How, for
instance, can the fact that 50 per cent. of the dangerously colour-blind pass
the wool test be explained, or that 90 per cent. of the dangerously colour-
blind agree with the normal white equation, though they may make an
anomalous white equation ?

A dichromic or trichromic makes mistakes through defective discrimina-
tion and not through the defect of a light perceiving substance when there
is no shortening of the spectrum or defect in light perception. A man with
shortening of the red end of the spectrum may recognise a very feeble red
of shorter wave-length, so this condition cannot be due to a defect in a light
perceiving substance which is affected by all rays of the spectrum.

Joint Discuss1on with Section J (Psychology, g.v.) on Disorientation
and vertigo (10.30).

SECTIONAL TRANSACTIONS.—I. 531

AFTERNOON.
Visit to Messrs. Boots, Nottingham.

Friday, September 8.
Discussion on Ossification (10.0) :—
Prof. R. Rosison, F.R.S.

The development of the calcified animal skeleton may sipponded by
two routes, one leading primarily to calcified cartilage, the other
directly to bone. Though histologically distinct these processes manifest
the closest biochemical relationship. Hypertrophying cartilage cells
and osteoblasts both synthesise phosphatase; and both, at a certain
stage in their development, secrete in the intercellular spaces a highly
specialised ground-substance possessing properties distinct from those
of the enzyme but also essential for normal calcification. In the animal
the actual deposition of calcium salt may lag somewhat behind the
formation of this specialised matrix ; but the presence and extent of the
latter may be demonstrated by calcification in vitro. ‘Thus it is found that
in embryonic rabbit femora and tibie the hypertrophic cartilage is fully
calcifiable, possessing both phosphatase and the second essential mechanism
(Niven and Robison). In the rudimentary long bones of fowl embryos,
however, the cartilage hypertrophies and synthesises phosphatase but does
not at once become calcifiable. The full calcifying mechanisms are subse-
quently developed in parts of the cartilage, but part becomes eroded without
acquiring these powers (Fell and Robison). Similar stages in the develop-
ment of the calcifying mechanisms were noted in cultures of endosteal bone,
grown in vitro. The area of calcifiable tissue was sharply defined and did
not include the whole of the osteoid (Fell and Robison).

Other experimental work (Rosenheim and Robison) has thrown further
light on the phosphatase and second calcifying mechanisms, but has not yet
provided an explanation of the latter. The calcification im vitro of other
tissues, such as kidney and aorta, has also been effected by prolonged im-
mersion in calcifying solutions (Rosenheim and Robison) ; but these experi-
ments have emphasised yet more strongly the special properties exhibited
by the fully developed hypertrophic cartilage and osteoid tissue.

Dr. Honor B. FELL.

The classical conception of the osteoblast as a specific bone-forming
cell has recently been much questioned. It is sometimes held that
osteoblasts and fibroblasts are identical and that ossification is caused
by the presence of excess calcium in a young and highly vascular
connective tissue. This view is not supported by experiments in vitro, in
which osteoblasts from the embryonic fowl mandible and from the perios-
teum and endosteum of the developing limb-bones, when isolated from the
body and cultivated under standard environmental conditions, readily form
bone in vitro, whilst similar cultures of connective tissue growing under the
same conditions do not ossify. These results imply that the osteoblast
possesses inherent bone-forming properties which are lacking in the
ordinary unmodified fibroblast.

A close histogenetic relationship exists between the osteoblast and the
hypertrophic chondroblast, and tissue culture experiments have shown
that the one type of cell can be directly transformed into the other.

532 SECTIONAL TRANSACTIONS .—I.
Dr. H. D. Kay.

The work of Robison and his collaborators has shown clearly the import-
ance of phosphatase in the deposition of bone salts, and has incidentally
called attention to the fact, apparently forgotten for many years, that phos-
phorification as well as calcification takes place in growing bone. The
phosphatase mechanism is also probably concerned with bone resorption ;
in vitro experiments have shown that under certain conditions bone salts
can be transformed again into soluble phosphoric esters in the presence of
phosphatase.

Changes in the phosphoric ester content of the tissues in experimentally
induced abnormal bony conditions have been observed. The marked
increase in phosphatase content of the blood, which is frequently associated
with diseases involving the skeleton, has been shown to be reversible after
adequate therapeutic measures have been taken.

The production of experimental rickets in rats, on a normal diet containing
vitamin D, by adding small quantities of beryllium carbonate to the diet
has enabled evidence to be brought forward in support of the view that one
of the major activities of vitamin D is to stimulate the uptake of phosphate
through the intestinal wall.

Dr. LesLiz J. Harris. Vitamin action and bone formation.

The following theory of the mode of action of vitamin D explains the
known facts and has enabled predictions to be made which were subse-
quently verified : vitamin D acts primarily by raising the blood Ca x P,
causing increased absorption of Ca and/or P from the gut and diminished
excretion into the gut (i.e. increased ‘net absorption’); the increased
calcification in the bone is secondary to the blood change. It has been
shown that this theory accounts for the following known facts :—

(1) The association of rickets with high fecal and (2) low blood
Ca and/or P and (3) low bone Ca and P ;

(4) The rectification of these errors with vitamin D, (5) the rise in
blood Ca X P preceding the new calcification ;

(6) The influence of the dietary acid-base balance ; (7) dietary Ca-P
ratio ; (8) Be, etc.

(9) Differences in species susceptibility.

(10) Calcification im vitro (proportional to Ca x P).

The writer predicted from this theory that overdoses should cause
hypercalcemia and/or hyperphosphatemia, and hence excessive calcifica-
tion, e.g. at growing end of bone. These effects were duly found and have
since been confirmed by others, the bones and teeth in hypervitaminosis
showing highly characteristic abnormalities. (With maximal overdoses and
insufficient Ca and P available in the gut, some of the extra Ca and P may
be drawn from parts of the bony store.)

The widely advocated theory that vitamin D acts by stimulating the para-
thyroid has been disproved by showing that the latter, in contrast with
vitamin D, does not increase ‘ net absorption,’ and acts by withdrawing Ca
from bone, causing loss to the body.

The primary effect of vitamin C deficiency is to cause degeneration of
osteoblasts, odontoblasts, ameloblasts, etc. ; hence cessation of osteogenesis.
Other effects in the hard tissues are secondary.

Dr. DonaLD HUNTER.

The clinical worker is in a position to study ossification in patients under
treatment. Progress is followed by estimations of the blood chemistry and

.

SECTIONAL TRANSACTIONS.—I. 533

calcium balance, together with histological sections of bone and radiograms
taken by controlled methods. In rickets and osteomalacia, vitamin D
restores the blood chemistry and radiogram picture to normal. Investi-
gations suggest that the theory of halisteresis is erroneous, and that the
action of vitamin D is to calcify osteoid seams.

Clinical, biochemical, radiographic and histological evidence exists that
two hormones influence the metabolism of bone. The parathyroid hormone
raises the serum calcium, depresses the plasma phosphorus, and causes
excessive excretion of calcium in the urine. The thyroid hormone raises
the excretion of calcium in both urine and faces, but there is no increase
in the serum calcium. Calcium is removed from the skeleton both in
hyperparathyroidism and in hyperthyroidism, and in both the mechanism
of removal is a lacunar resorption by osteoclasts.

PRESIDENTIAL ADDRESS by Prof. E. D. ADRIAN, F.R.S., on The activity
of nerve cells (12.0). (See p. 163.)

AFTERNOON.

Col. C. J. Bono, C.M.G.—Some recent observations on certain phases of
leucocytic and erythrocytic activity (illustrated with the projection
microscope) (2.0).

(1) Incubated leucocyte films showing—
(a) active, (b) resting, (c) reactivated cells.
(2) Endothelial cells. Ditto.
(a) resting cells ; (6) active cells ; (c) phagocytosed red cells.
(3) Phagocytosis of pigment particles in active, resting and reactivated
cells.
(4) Leucocytes and dendrites (3).
(5) Living pus cells.
(a) active, (5) resting.
(6) Washed red cells, showing passage from disc, through prickled, to
the spheroidal shape.
(7) foot to disc form by addition of blood serum or soap (sodium
oleate).
(8) Auto (pseudo) compared with group agglutination.
(9) Effect of reagents on intracellular hemoglobin.
(10) Avian, amphibian and fishes’ red cells.

Dr. F. J. W. Roucuton.—Carbon dioxide transport in blood : recent
developments (2.45).

This paper surveys the changes in outlook which have occurred during
the past three years due to—

(a) The isolation from red blood corpuscles of an enzyme, carbonic
anhydrase, which accelerates the formation of carbon dioxide from
carbonic acid, and vice versa.

(6) The evidence that some carbon dioxide may be carried in direct
combination with the blood proteins, probably as protein carbamate.

Dr. THomas BeprorD and Mr. A. F. Durron.—WNose-opening rays (3.15).

Leonard Hill’s theory that there are ‘ nose-closing’ rays and ‘ nose-
opening ’ rays appeared to be of paramount importance in the study of the

534 SECTIONAL TRANSACTIONS.—I.

physical conditions conducive to human comfort. Hill’s observations are
not confirmed ; in well-controlled experiments with eighty-five subjects
no evidence whatever is found of ‘ nose-opening ’ rays.

Nose-closing is found to occur not only with a dull fire but also with a
bright fire. It can also be produced by heating the subject by convection
(heated air) or by conduction (warm fomentation). Even the sun is a
potent nose-closer.

The average person tolerates most heating effects without discomfort and
without recourse to mouth-breathing ; it is only in those who are peculiarly
sensitive (e.g. by reason of deflected septa) that any difficulty arises.

Monday, September 11.
Discussion on The chemical control of the circulation (10.0) :—

Sir H. H. Date, C.B.E., Sec.R.S.

The study of the chemical control of the circulation began with the dis-
covery of adrenaline and of the pituitary pressor principle. The former is
predominantly augmentor to vascular tone, though there is evidence that
its actions include a vasodilator effect; concerning the physiological
significance of the pituitary principle little is known.

It has long been improbable that there is any organ of internal secretion
which forms a hormone predominantly vasodilator in function, though
depressor substances were early found in most tissues. The first of these
vasodilator substances to be identified was choline. This was followed by
histamine which has been shown to exert a dilator effect on the minute
vessels, complicated to different extents in different species by a constrictor
action on larger arterioles and venules ; this substance plays an important
part in the effects of local injury to the skin. Another dilator substance,
an unstable choline ester and indistinguishable from acetyl choline, is
liberated as the result of stimulating various parasympathetic nerves and
the arteriodilator branches of sensory fibres. Further vasodilator sub-
stances which have been discovered in recent years are the adenosine series,
constituents of muscle extracts, and kallikrein, which appears to circulate
in an inactive form in the blood and to be rendered active by a rise of acidity.

Evidence seems still to be lacking for the direct action of any of these
vasodilator substances as a true hormone. In this respect there is a general
contrast between them and the true, mainly vasoconstrictor, hormones ;
this contrast, however, is by no means an absolute one, since it appears
possible that adrenaline may be held in an inactive form peripherally, to be
released by sympathetic nerve-impulses as a humoral transmitter of their
effects,

Prof. J. H. Burn.

It has previously been shown that vasoconstrictor substances such as
tyramine and ephedrine exert only a slight effect when injected into the
arterial system of the body wall and limbs of cats or dogs perfused by
defibrinated blood ; similarly stimulation of the sympathetic chain exerts
only a slight effect. "The constrictor action of tyramine, ephedrine, and of
sympathetic stimulation is increased if adrenaline is continually added to the
blood used for perfusion so as to maintain a uniform concentration. The
addition of adrenaline has the further effect of bringing to light dilator effécts
following the injection of ephedrine and the stimulation of the sympathetic

SECTIONAL TRANSACTIONS.—I. 535

chain. It is shown that the effect of a maintained concentration of adrena-
line on the tyramine response is exerted pari passu with its effect on the
histamine response, and also with a similar effect on the response to acetyl-
choline. The vasodilator effect of small doses of adrenaline is not seen in
circumstances in which vasodilatation from sympathetic stimulation occurs.
The effect of adrenaline is considered to be an effect on the vessel walls in
general and not on the neighbourhood of the sympathetic terminations in
the walls.

Dr. A. N. Drury.

Adenylic acid, isolated from muscle, has a depressor activity which is
shared by related compounds such as adenosine, yeast adenylic acid, and
yeast cytidylic acid. The last substance is of interest, as there is evidence
that in muscle extracts a depressor substance is present, in addition to
adenylic acid, which has very similar properties to yeast cytidylic acid.
The depressor activity of adenylic acid and adenosine is lost when the
amino group is split off, and this led to the idea that the effect is associated
with deamination, though recent work fails to give it support. Adenylic
acid has been isolated from the blood, and is considered to be the substance
responsible for the ‘ primary toxicity’ of fresh defibrinated blood. It is
liberated from damaged muscle and may therefore play a part in the dilata-
tion of vessels which accompanies injury. Moreover it produces a local
dilation and leucocytosis, and may be responsible for this phenomenon of
tissue damage. It is quickly inactivated by the tissues, so that it must be
liberated continually if it is to produce a lasting effect.

Dr. J. H. GappuM.

There are at least two vasodilator substances in some tissue extracts which
have hitherto baffled the chemists. ‘These have been arbitrarily called
kallikrein and P-substance. They are both unstable substances with rather
large molecules, and are both readily carried down from solutions by various
adsorbents. Both substances produce a fall of blood pressure in animals
which have received atropine, and so been rendered insensitive to choline.
They are both distinguished from histamine by the facts that they are
unstable in acid solutions and produce a fall of blood pressure in etherised
rabbits. They are distinguished from adenosine by the fact that they are
unstable in alkaline solutions.

Kallikrein has been obtained from urine and blood, but has been found
to be present in a particularly high concentration in the pancreas. It is
insoluble in alcohol.

P-substance is present in intestine and brain. It is distinguished from
kallikrein by its distribution, and by the fact that it is soluble in absolute
alcohol. ‘There are also various pharmacological differences, but it will be
difficult to obtain any certain knowledge of the general actions and signi-
ficance of these substances until better methods of purification can be
devised than those at present available.

Dr. W. FELDBERG.

Prof, R. J.S. McDowa_t.

When 5 per cent. carbon dioxide is administered to a chloralised cat
there may be no alteration of blood pressure, but it is not, therefore, to be

536 SECTIONAL TRANSACTIONS .—I.

presumed that the carbon dioxide has been inactive. Such percentages
of carbon dioxide have been shown by Jerusalem and Starling and others
to increase the output of the heart. New experiments are described which
show that the vasomotor centre has been stimulated, since there is a marked
increase in the resistance of a limb perfused separately and connected to
the animal only by nerves. It may therefore be concluded that, since the
output of the heart is increased and the vasomotor centre stimulated with-
out causing a rise of blood pressure, the carbon dioxide has caused a
diminution of peripheral resistance. ‘These results support the view
previously put forward that the carbon dioxide of the arterial blood has in
the periphery a dilator action which balances its central effect.

Prof. H. Harrripce, F.R.S. (12.25) -—
(a) Variations in skin resistance due to electrical currents.

Ebbecke found that the resistance of the skin to galvanic currents could
be decreased either by rubbing the skin or by the continued passage of a
galvanic current of such strength that whealing was ultimately produced.
Lewis and Zotterman, using small electrodes, obtained a similar drop in
resistance which they attributed to breaches in the horny layer, whereas
Ebbecke has attributed it to stimulation of the living cells which lie deep to
that layer.

I have repeated these experiments with electrodes of large area, and I find
the same fall of resistance. I have noticed, however, that on cessation of the
galvanic current the skin resistance rises until it reaches a value considerably
greater than that to which the galvanic current had depressed it. If the
explanation of Lewis and Zotterman is correct, one must conclude that the
breaches in the horny layer heal again with very great rapidity.

(b) An experiment in favour of the resonance theory of hearing.

A brass disc, about 12 in. in diameter, is provided near its circumference
with two concentric rows of slots. The inner row consists of ninety-six
equidistant slots ; the outer row also consists of ninety-six slots, at equal
distances except for one interval only which is half the distance of each of the
others, thus introducing a change of phase (a half wave-length). When the
disc is rotated by an electric motor and a stream of air is directed on to the
inner row of slots, a continuous musical tone of constant pitch is produced.
When the stream of air is directed on to the outer row of slots a musical
tone of constant pitch is heard, but this tone is interrupted once at each
revolution of the disc when the change of phase occurs. Since the interrup-
tion effect heard by the ears can be imitated by stopping up two neighbouring
slots of the inner row, I conclude that this is a true interruption and not,
for example, a change of pitch of the tone.

This confirms an earlier conclusion that a change in phase of a musical
tone causes it to be ‘ out of step ’ with the ear resonators, so that the latter
first are arrested and then recommence their vibrations.

(c) Competitive reaction time apparatus.

A number of neon lamps are connected so that each lamp has a separate
switch. The lamps and their switches are connected in parallel between
two buss bars, one of which is connected to one wire of the 200-volt D.C.
main, the other buss bar being connected to the other wire of the main
through a suitable resistance (usually 10,000 ohms). The current passing

SECTIONAL TRANSACTIONS.—I, J. 537

through this resistance (about 10 m.a.) is sufficient to strike one neon lamp
and to keep it alight, but when once this lamp has lit the resultant voltage
between the buss bars is insufficient to strike any additional lamps. Con-
sequently, when after turning on the main a neon lamp lights, it indicates
that the switch connected to that lamp was the first to be closed. The
apparatus can thus be used to ascertain which one of several individuals
takes the least time to close his switch after a given signal which corresponds
to the switching on of the main.

(d) Advancing and retiring colours.

‘Chromatic stereoscopy ’ (Hartridge, Journ. Physiol., lii, 222, 1918) is
not limited to coloured objects, for I find that it is possible for black and
white to be advancing and retiring colours when placed on backgrounds of
suitable colour. ‘Thus when they are placed on a red ground, black advances
and white retires ; but when they are placed on a blue ground, white ad-
vances and black retires. ‘These relative positions may be explained as
follows : A black object on a red ground is seen in the same position as a
red object on a black ground would be. A white object on a red ground,
however, is equivalent to a blue-green object, or a black ground plus a
uniform red ground without any object on it (as may readily be seen by
summing the colours). Now a blue-green object on a black ground retires
relatively to a red object on a black ground and, therefore, substituting the
equivalents we have just found, a white object on a red ground retires but a
black object on ared ground advances. Observation shows that a white object
on a blue ground advances, whereas a black object on a blue ground retires,
but a white object on a blue ground may be replaced by a yellow on a black
ground plus a uniform blue ground. We know, however, that a yellow
object on a black ground advances, whereas a blue object on a black ground
retires. Therefore we have explained the phenomenon in this case also.
For grounds of intermediate colour for red and blue, namely yellow and
green, the phenomenon is not so striking as it is for red or blue.

AFTERNOON.
Visit to Leicester Royal Infirmary.

Tuesday, September 12.

Joint Discussion with Sections D (Zoology, €8) and K (Botany) on
Genetics (10.0).

SECTION J.—PSYCHOLOGY.

Thursday, September 7.

Prof. C. W. VaLentine.—The early development of language in the
child (10.0).

Evidence based on observations of five children from the first day to the
age of 3, when all the main forms of language structure have been learned.

538 SECTIONAL TRANSACTIONS.—J.

The essential bases of language :
(a) Spontaneous expressions of feeling.
(b) Spontaneous babblings and practice in sound making.
(c) Association of sounds heard with feeling, objects, or general
situations.

Early effects of social influences.

Individual differences indicative of future development occur as early
as 1 and 2 months. (Slower speech development of A and B as compared
with Y indicated before 2 months.)

From 4 to 9 months practising of new sounds very important.

The ‘ understanding ’ of meaning of some words clearly established at
6 or 7 months.

‘ Understanding’ and ‘ expression’ far from identical. For expression
a different word from the word heard and understood may be used for the
same thing.

Prominence of feeling or conational aspect of early speech.

Importance of imitation, especially from 14 or 14 years onwards.

The generalisation of meanings; the specialisation of words.

Does the child originate words ?

Special characteristics of the period 13 to 2 years. Use of negative.
First questions. 'Two- or three-word sentences.

The great discovery— Things have names.’

From 2 to 3 years. Words indicating spatial and temporal relations.
Testing by experiments the understanding of prepositions. Subordinate
sentences : Why and Because. All forms of sentence structure now used.

Joint Discussion with Section I (Physiology) on Disorientation and
vertigo (10.30).

Dr. J. T. MacCurpy.

Dependence of spatial orientation on balancing system. (Examples.)
When latter disturbed, get disorientation and a secondary confusion
(psychological), which produces failure to recognise objects.

Under normal circumstances balance depends on postural and righting
reflexes. These are stimulated by changes in otolith organs, semicircular
canals, muscle tensions, deep pressure and vision. ‘The muscular system
is the most important (Garten’s experiments). It has incredibly low
threshold and speed of reaction and is unconscious. There is probably
awareness only for response, and for that only when exaggerated, i.e. when
balance is lost ; awareness is for disequilibrium, not equilibrium. (‘ Falling’
is a visual perception.) Disequilibrium is sensed by vision and vestibulo-
proprioceptive organs.

This is illustrated in flying, which demands an acquired balancing reaction.
Until this is gained visual orientation is difficult or impossible (Data).
Innate balancing reactions are made to actual direction and value of g, but
visually to aeroplane. Hence conflict and giddiness until aeroplane is
treated as part of body (acquisition of manipulative control). Conflict
leads to excessive proprioceptive stimuli because reaction does not abolish
stimulus as in effective balancing.

This leads to nausea via excessive and incoordinate reflex response.
Two types of sensitiveness, one to increase in value and one to change in
direction of g. Normal response to increased g (alighting on ground when
jumping) is tension in extensors and rigidity of abdominal walls to prevent
displacement of viscera. If rapid and effective, diaphragm does not move,

SECTIONAL TRANSACTIONS.—J. 539

and there is no consciousness of trunk muscle response. If ineffective, get
diaphragmatic tug (e.g. in lift). Co-ordinate response involves accurate
abdominal muscle contraction to balance g and, if this has to be maintained,
a change from diaphragmatic to costal breathing. With incoordinate
response diaphragm works against rigid belly wall, the abdominal contents
are squeezed as in vomiting, and if this persists the whole nausea-vomiting
cycle is evoked. In the other type there is a general rigidity of limbs and
trunk in an exaggerated and incoordinate effort to prevent displacement of
the body. This includes rigidity of abdominal muscles, and so the same
result ensues.

Flight-Lt. J. A. G. Hasta.

Experiences from flying relating to the subjects of the discussion ; these
will illustrate some of the points in Dr. MacCurdy’s paper (q.v.).

Dr. T. G. MaITLanp.

Rectilinear movement as a cause of general vertigo—

The relation of general vertigo to special vertigo in so far as they both
result from passive displacement. Among modern forms of locomotion
the best example of displacement causing general vertigo is the swift vertical
drop in a lift, and of that causing special vertigo the flat spin of an aeroplane.

Under which category do the movements of swings, switchbacks, of
aeroplanes passing through air pockets, of boats in a rough sea, fall? All
these movements have angular direction, but the resulting vertigo is general
rather than special, which implies the activity of a rectilinear factor.

What, then, is the relation of the semicircular canals to rectilinear move-
ment?

The reactions, both physiological and psychological, associated with general
vertigo would seem to demand another receptor.

The interpretation of vertigo and its biological significance.

Sq.-Leader E. D. Dickson.

Mr. R. J. BARTLETT.

Insufficiency of oxygen supply in brain owing to faulty breathing as
a cause. Disequilibrium not essential. In air and water travel dis-
equilibrium possibly a principal cause of faulty breathing. Train and
motor sickness not readily so explained. Partly explained by somatic
reactions to variations in speed. Complaints of vibration and noise.
Noise investigation results stress psychological factors. Some Effects of
Low Frequency Vibration on Body and Mind reported in 1930. ‘ Giddiness,’
* dizziness,’ ‘ dullness,’ ‘ sleepiness ’ and ‘ intense cold ’ induced by vibra-
tion. Accompanying pneumograph records show shallow, fluttering or
panting breathing punctuated with deep gasps. The pulse also affected.

Mechanical vibration not essential. A ticking metronome induces
changes in breathing of susceptible subjects. As metronome rate changes
breathing changes in sympathy until it becomés impossible to change
further, when there is great discomfort until subjective metronome rhythm
changes to one with which breathing can harmonise. ‘ Torture’ due to
the ‘ drip-drip ’ of water similar. Record of a case in which the water-
dripping frequency was slowing down and passed through the pulse rate.

External physical causes not essential. Purely physiological causes

540 SECTIONAL TRANSACTIONS.—J.

sufficient. Fear, dizziness and collapse apparently due to shortage of
blood in brain occasioned by digestive trouble.

Purely psychological causes effective. Fear and revival of unpleasant
past experiences often reported by subjects.

Practical questions: Is a volitionally controlled breathing that will
frustrate the tendency to engine control possible ?) Can such ‘ willed’
breathing be transformed into a ‘ habit’ ?

Dr. R.S. Creep; Sq.-Leader G. H. Rem.

AFTERNOON.
(Section meeting in two divisions.)

Division 1.
Miss A. G. SHaw.—Motion study applied to small assembly and machine
work (2.0).

Mr. A. Ropcer.—Why and how the vocational psychologist studies tem-
perament (3.30).

The term temperament may conveniently be used to cover such charac-
teristics as are represented by the words sociability, frankness, cheerfulness,
co-operativeness, neatness and cautiousness. For the purposes of the
vocational psychologist most temperamental characteristics may be regarded
as belonging to one of two main types; those which are displayed in an
individual’s attitude towards other people, and those which are displayed
in his attitude towards his work. It is clear that in some occupations it is
more important that a worker should possess certain of these characteristics in
high degree than that he should possess either outstanding general intellectual
ability or really good practical abilities. Psychologists have attempted to
devise numerically-scored tests for many of them, but so far their efforts
have met with scant success. The National Institute of Industrial Psy-
chology is endeavouring to break fresh ground by adopting what may be
called a ‘ biographical ’ procedure and by seeking definite assistance from
the parents and teachers of those who apply to it for vocational guidance.
This involves a study not only of an individual’s temperamental charac-
teristics as they are at the moment, but also of those characteristics as they
have been in the past. In this way some indication of their all-important
“trend ’ is obtained.

Miss R. M. GOLDTHORPE.—Effect of the distribution of practice periods on
the learning curve in industrial operations (4.15).

Division 2.

Dr. R. B. CaTTELL.—Friends and enemies ; their g,p, c, and w values (2.0).

A previous research has shown temperament and character traits to fall
into two broad patterns: the ‘surgent’ temperament determined by a
general factor c, and the will-character determined by a factor w
(Webb).

In a group of 62 students, who had been the subjects of estimates on
these factors, and who had also been tested for intelligence, perseveration,
and ‘ fluency of association,’ each student was asked to name two others
who were his especial friends and one other for whom he felt a particular

SECTIONAL TRANSACTIONS.—J. 541

aversion. It was hoped that, in spite of historical accidents operating
to determine many friendships and antipathies, some systematic trend,
according to temperament and character similarities or differences, would
be perceptible.

Indications of such relationships were found, particularly with p, c and w.
(The scatter of g was so small in this examination-selected group as to make
any analysis in this respect useless.) There is also an indubitable tendency
for popularity (number of friends) to vary with p and w. Thoughthe causes
of these trends are obscure, confirmation and extension of these findings
would make profitable discussion possible and, at the same time, throw light
from a new angle on the natures of p, c and w.

Mr, F. C. THomas.—A _ simplified synthesis of the factor and noegenetic
theories (2.45).

After a brief introduction, it is assumed that the existence of general and
specific cognitive factors (g and the s’s) is now adequately proven. These are
regarded as determining only a person’s maximum performance at a given
task. Factors of other kinds may, and normally do, intervene ; causing
his actual performance on any given occasion to fall short of what his g—s
equipment alone would lead us to expect of him. These ‘ quantitative
determinants ’ of cognition fall into three classes, as follow: (1) per-
severation, oscillation, constancy of cognitive output, persistence of motive
and conative control of cognition—which limit achievement by affecting g;
(2) Fatigue and retentivity, which affect the s’s; (3) ‘ Basic constitution ’
(= primordial potency), or factors of age, sex, heredity, and health, which
affect the other quantitative determinants. The three noegenetic processes
are then regarded as being the tasks that g performs when, under the
restraint of the quantitative determinants, it activates the s’s.

Dr, P. E, Vernon.—The applicability of quantitative methods to traits of
temperament and personality (3.30).

A temperamental or personality trait differs in many respects from an
aptitude or ability. It cannot be defined solely in terms of objective
behaviour, but is dependent upon the observation and interpretation of
such behaviour by human mentalities. A man’s traits are not so much his
own ‘properties,’ as relations between him and the persons who observe
him. The trait is a name for a very general class of behaviour, hence its
content is extremely ambiguous, It is impossible to find distinct dividing
lines between different traits, or to isolate any one trait as more fundamental
than another.

A single test, or set of ratings, cannot give an adequate measure of a trait;
instead a variety of diverse tests should be combined into a crude composite
score. In personality testing, unlike aptitude testing, no objective criterion
of validity is available ; but the inter-correlations within such a composite
indicate its theoretical validity. Though the tetrad difference technique
may be applied to these composites of personality tests, yet elaborate
Statistical treatment and factorial analysis are unjustifiable owing to the
inherent subjectivity of the trait concept.

Mr. F. H. Gace.—The quantitative aspect of brightness in visual sensations
(4-15).

At the meeting of the British Association last year, there was a discussion

on the quantitative relation of physical stimuli and sensory events. The

542 SECTIONAL TRANSACTIONS.—J.

following work has been performed with a view to investigating one of the
simplest cases in vision, the relation between the intensity of the stimulus
and the sensory brightness.

Experiments have been performed in which three white circular patches
are simultaneously presented side by side on a black background. ‘These
patches differ only in respect of their brightnesses. ‘The intensities of the
two outside patches bear a known ratio to each other, while the intensity of
the middle patch can be adjusted to appear equally spaced in brightness
between the outer patches, that is, its brightness is neither nearer one nor
the other. Using this method, it is shown that consistent observations can
be obtained, and that observers substantially agree in their estimations
although real differences appear between them, but that fundamental
difficulties arise which prevent a scale of brightness being constructed by
this method.

The experimental evidence is against the measurability of the brightness
of visual sensation.

Friday, September 8.

PRESIDENTIAL ADpREsS by Prof. F. AveLING on The status of Psychology
as an empirical science (10.0). (See p. 171.)

Dr. WILLIAM Brown.—The psychology of personal influence (11.0).

The problem of personal influence arises in a challenging form in the use
of methods of suggestion and hypnotism, and also in the phenomenon of
so-called ‘ transference’ in psychoanalysis. It is important to decide, if
possible, how far hypnotic effects may be explained in terms of transference,
and again what are the probable bases of temperamental compatibility and
incompatibility. Wider possibilities, of a spiritual and psychic nature,
should not be left out of account, so far as science can deal with them.

Prof. F. A. E. Crew.—An attempt to determine the factors operating in
Professor McDougall’s Lamarckian experiment (12.0).

AFTERNOON.
(Section meeting in two divisions.)
Division i.
Dr. R. H. TuHovutess.—Some practical consequences of phenomenal
regression (2.0).

The purchaser of a telescope for terrestrial observation wants objects to
‘look big’ and not merely to make a large retinal image. Apparent size is
not simply a function of retinal size. Distant large objects look larger than
near small ones when their retinal sizes are equal. The extent of this effect
(of phenomenal regression) differs in different individuals and under different
conditions of perception. Monocular observation through a blackened tube
is found experimentally to diminish phenomenal regression and it thus acts
as a mental factor reducing the apparent magnification of a telescope. This
is one reason for the greater satisfaction obtained by vision through pee
lars even when these are of lower power.

Similarly a condition of lifelike representation on a screen is that the

SECTIONAL TRANSACTIONS.—J. 543

scene. represented should look large enough. The stray light in a cine-
matograph theatre, which gives the screen the character of a definite object
at a considerable distance, favours phenomenal regression which increases
apparent size. For a small screen at a short distance (such as that of a
television apparatus) the best results would, on the contrary, be obtained
by conditions of observation eliminating phenomenal regression as far as
possible.

Ability to drive a car quickly and accurately through traffic obviously
depends on ability to judge the real size of a gap at whatever distance it
may be observed. Experiments have been performed in order to determine
how far this ability depends on the individual’s amount of the tendency7to
phenomenal regression (that is, on the amount of his tendency to see objects
in their ‘ real ’ sizes irrespective of their distance from him)

Dr. J. H. QuasteL.—Narcosis and mental function (2.45).

The psychological effects of oxygen want (anoxzmia) resemble in many
ways the reactions present in psychotic and neurotic conditions, and those
found also in alcoholism and light narcosis. ‘The study of the biochemical
basis of narcosis has shown that narcotics act, apparently, by preventing the
nerve cells from receiving the amount of energy necessary for their functional
activity. This they do by bringing about a condition equivalent to anoxemia,
not by interfering with the amount of oxygen present, but by diminishing
the ability of the cells to oxidise substances (glucose, lactic acid) which
form the main fuel of the cells. Further study has shown that substances
normally formed in the body and normally broken down in the liver have
effects similar to narcotics, so that a disturbance of the detoxicating powers
of the body might lead to conditions whose psychological reactions would
resemble those found in oxygen want. ‘The treatment of psychotic con-
ditions by prolonged narcosis is extremely important ; it is suggested that
the success of the treatment depends on the removal, during the narcotic
state, of toxic metabolites (or fatigue products) in the brain. The main
danger to the narcosis treatment is the disturbance in the carbohydrate
metabolism in organs such as the liver whereby intense ketonuria may be
established. ‘The introduction of the glucose-insulin modification of
prolonged narcosis treatment has removed this danger, so that the treatment
is now comparatively safe.

Dr. C. C. Hurst.—Genetics of intellect (3.30).

Two thousand one hundred and eighty-two parents and offspring in
406 families individually graded for general mental ability (Spearman’s g),
using scale of 11 grades (o-10) each approximately equivalent to 20 I.Q.
Data include 194 modern Leicestershire families, objectively graded by
author, and 212 ancient Royal Families of 11 countries in eight centuries
histriometrically graded by Dr. Adams Woods. Both groups show same
genetical types of families : non-segregating with like offspring and segregating
with unlike offspring. Neither family environment, simple heredity nor
free will can account for co-existence of these two family types exhibiting
dominance and segregation. Analyses show that 98:1 per cent. of data are
consistent with genetical formula of type Nu + (AaBbCcDdEe) where Nn
is a major pair of genes for Normal (N) and Abnormal (m) Intellect and
Aa. .Ee are minor pairs cumulatively modifying nn as in experimental wheats
where A. .E are increasers and a..e decreasers. ‘Thus NN and Nm produce
normal mediocre intellect of mid-grade 5, unaffected by the modifiers, while

544 SECTIONAL TRANSACTIONS.—J.

nn produce abnormal low and high grades o-10, according to the modifiers
present. The formula is relatively simple, involving only seven kinds of
effective gametes, and is of fundamental practical importance since it predicts
with considerable precision the results of any grade-matings. A scheme of
family allowances based upon it would maintain minimum number of high-
grade children necessary for preservation of modern civilisation.

Division 2.

Mr. R. J. BARTLETT.—The effect of so-called ‘ constant’ errors in sensory
comparisons (2.0).

Further work with geometric series of weighted containers. The ‘ con-
stant error’ increases in amount as weight increases or decreases from a
‘datum’ value. This ‘datum’ not a weight or a density but a value
depending on nature and size of the container. The error has sign and in
adults appears to be approximately proportional to the cube of the difference
between the weight lifted and the ‘ datum ’ weight. With children the error
appears to increase more rapidly.

With practice, the ‘ constant errors’ for a particular series decrease in
amount, and possibly would eventually become zero throughout the scale.
With the series used decrease is more rapid at the heavy end than at the
light end, and there are indications that after the first few sittings of a subject
the heavy weights are regressing towards a heavier and shifting datum, while
the light ones are still referred to the original datum or to one only slightly
heavier.

The common experience of subjects that discrimination is easier at the
heavy than at the light end is supported by the decrease in value of the scatter
error of the best equal value as the standard weight increases in value, and
indicates that the true ‘ Weber constant’ (freed from the masking effect of
the ‘ constant error ’) slowly decreases in amount as the stimulus increases
in value.

Mr. M. F. Lowe.—Alterations in blood distribution during mental work
(2.45).

In this communication experiments with the Mosso Balance, and also
with two modifications of it, are described.

Results from the simple Mosso Balance indicate that the ‘ head end ’ of
the apparatus becomes lighter during mental work, and not heavier as
Mosso had stated. Further, it is shown that the conclusions of Ernst Weber
in regard to the controlling influences of the position (in regard to the axis
of the balance) of the abdominal organs of the subject must be revised.

In the first modification the apparatus was arranged so as to rock from
side to side instead of up and down as the original Mosso Balance had done.
It is shown that the approach to sleep is accompanied by a gradual depression
of the left side of the balance, while mental activity is accompanied by a rise
of the left side.

In the second modification the balance was constructed upon the gimbal
principle so that deflections from the up-and-down Mosso motion and from
the side-to-side motion could be recorded simultaneously. From these
experiments it is shown that various mental states (e.g. activity, passivity,
sleep) can be connected with definite combinations of balance movements.

SECTIONAL TRANSACTIONS.—J. 545

Dr. G. SetuH.—Some clinical aspects of stuttering (3.30).

1. The incidence of stuttering among school children. The sex-difference
in the percentage of stutterers.

2. Accepted causative factors. The réle of heredity and imitation.

3. Developmental history of the stutterer. Other neurotic manifesta-
tions. The psycho-analytic theory of the disorder.

4. The stuttering character.

(Full Section Meeting.)
Prof. E. C. Totman.—The learning of rats (4.15).

Sunday, September 10.
Visit to Besford Court Mental Deficiency Institution, near Worcester.

Monday, September 11.

JornT SEssIon with Section L (Educational Science, ¢.v.) on The predictive
value of school examinations and psychological tests (10.0).

AFTERNOON.
Visit to Lowdham Grange Borstal Institution, Nottingham.

Tuesday, September 12.

Jomnt Discussion with Department A* (Mathematics) on The validity
and value of methods of correlation (10.0) :—

Prof. C. SPEARMAN, F.R.S.—The theory of two factors.

Foundation pillars of the theory.—Correlations between test scores ;
observation of regularities; allowances for sampling errors; deduced
constitution of scores ; other deductions.

Points on which objections have been raised——Correspondence of theory
with observation ; uniqueness of the factors; necessary existence of the
factors ; interpretation of the factors ; scientific significance of the theory.

Dr. WILLIAM Brown.

As an important example of the value of methods of correlation in psy-
chology, one may mention the employment of the tetrad-criterion
(112%34 — T13%¥2, = 0) to test for the presence of a central intellective
factor (g). The results of an extensive research, by Dr. W. Stephenson and
the present speaker, on a large and homogeneous sample of boys, using
nineteen carefully selected and standardised mental tests, show a frequency-
distribution of tetrad-differences in close agreement with a ‘ theoretical ’
distribution, such as may be expected from a random sample drawn from
correlations actually due to one central factor, thus supporting Spearman’s
theory of ‘g.2. The form of distribution approximates closely to a Type IIA
Pearson curve.

Dr. S. Dawson.

546 SECTIONAL TRANSACTIONS.—J.

Dr. J. WisHarT.—Sampling error in the tetrad theory.

Although much progress has been made with the establishment of the
tetrad theory on a rigorous mathematical basis, the difficulties inherent in
the study of the appropriate sampling errors have prevented a corresponding
advance in this all-important part of the work. In deciding whether a given
body of numerical data is in accordance with theory, we cannot expect the
tetrads to be exactly zero, and must therefore make allowance for the random
sampling error. This is usually done by forming the distribution of sample
tetrads (necessarily symmetrical if each is to be counted twice, once positive
and once negative), and comparing its standard deviation with an average
theoretical value obtained by admittedly approximate methods. In this
paper the inperfections of existing practice are noted, and some attempt
is made to formulate more exactly the problems to be solved before the
matter can be considered as settled. A full solution is not reached, but an
extension of some earlier work of the author, in which a tetrad of product
moments was used in place of that of the correlation coefficients, is sug-
gested as a reasonable method of approach to a more exact solution.
Illustrations are furnished from two series of numerical data supplied by
Prof. Spearman.

Dr. S. S. Witxs.—A criterion for testing the mutual independence
of several sets of traits.

Suppose that each of N persons has been measured on a set A of n

traits, t;, to, . . . ¢,. Furthermore, let A be subdivided into k groups
A,, Az, ... Ax, with the 7-th group A; having n; traits specified by
ta,, tan, . . . tay;, The question with which we are concerned is the

following : can this sample of Nn measurements be regarded as having
come from a population in which there is no correlation between any trait
of one group and any trait of another? For example, if several motor and
several mental abilities are measured on a group of individuals, it might
be important to ask if these two categories of abilities may be regarded as
independent of each other. Again, in the problem of fitting factor patterns
containing group factors to psychological data, which has been considered
by T. Kelley and others, it would perhaps be useful in some cases to group
the traits by a priori reasons and test for the significance of any dependence
between the groups before attempting to find coefficients of the overlapping
factors. Otherwise such coefficients may be insignificant. The same
questions of independence will arise when linear transformations of the
traits are considered.

If rpq is the sample value of the correlation coefficient between tp and tg
in A, D the determinant | rpq | of co:relation coefficients in A, and D; the
determinant of correlation coefficients in A; (i= 1, 2... k), then the
proposed criterion for testing the significance of the mutual independence
of the groups A,, As, ... Az is OQ = D/(D, D, . . . Dy). When the
hypothesis is true that these measurements have been made on a group of
persons which has come from a normal population in which A, Ao, . . . Ap
are mutually independent the sampling mioments are known, and in a
number of cases exact expressions have been obtained for the probability
integrals in terms of incomplete B-Functions. The QO criterion will be unity
when, and only when, all of the 7’s vanish in D which do not occur in
D,, Dz, . . . Dz—that is, when there is no correlation in the sample between
any trait of one group and any trait of another. @Q becomes zero as the
hypothesis of mutual independence becomes untenable, as far as the sample

SECTIONAL TRANSACTIONS.—J. 547

is concerned. QO may be regarded as a generalisation of 1—R?, where R is
the multiple correlation coefficient between one variate and several others.
The use of 1—R? as a criterion to test the significance of the independence
of one variate and a group of several others is well known. Ina similar
manner O may be used to test the significance of the mutual independence
of several groups of variates.

Dr. J. O. IRwin.

It is possible that coefficients of association have been used too much in
psychology. They should only be used after the most careful consideration
of the assumptions on which they are based, and should in any case be supple-
mented by statistical methods having a more direct meaning. An example
of their careful use is given from some of the work done for the Industrial
Health Research Board on ‘‘ Tests for Accident Proneness,” by Messrs.
Farmer, Chambers and Kirk.

Prof. H. T. H. Praccio.

How far is g determinate? Analysis of tests by Murdoch, Brown, and
Stephenson. No appreciable increase in determinateness possible by
further increase in the number of tests. New tests with greater g-saturation
needed.

AFTERNOON.
(Section meeting in two divisions.)
Division 1.
Prof. C. SpEARMAN, F.R.S.—The international plan for determining an
individual’s unitary traits (2.0).
Unprogressiveness of psychology ; revolution and evolution.
Scheme to determine unitary traits; Thorndike’s plan; formation of
committee ; extension of plan.
International aid up to the present ; fundamental objections ; constructive
suggestions.
Experimental investigations already in progress: London; New York ;
Nashville ; Washington ; Chicago.
Mathematical advances made in theory of factorisation.

Collaboration for the future: criticism; corroboration; supplementation ;
interpretation ; special controversies ; final general conference.

Dr. G. G. N. Wricut.—Personal relations and the small group (2.45).

Two minds come into relation with one another when each seeks expres-
sion in a frame of external circumstances of which the other is a part.
A sociological view of such an event must apprehend the points of view of
both persons as equally parts of one sociological situation which com-
prehends the relevant mental states and behaviour of both. When these
are in concord, and a common programme of activity follows, the dispositions
in both minds which determine it may be regarded as constituting a single
functional system or common mental frame. ‘The general lines of the more
primitive common mental frames are innately determined; but (a) they
undergo modifications specific to particular personal relations, and (0b) co-
operative relations may rest upon common mental frames which have
little or no innate basis but arise out of: (i) similar responses to a common
situation ; (ii) complementary responses to a common situation ; (iii) the

548 SECTIONAL TRANSACTIONS.—J.

pursuit of a common end ; (iv) the pursuit of interdependent ends. The
structure of human relations is further complicated by («) the develop-
ment of regulative mental structures, (8) volitional processes and other-
consciousness.

The structure of all groups small enough to be accessible for this kind of
study may be described in similar terms.

Miss M. D. VERNoN.—Binocular vision of flickering fields (3.30).

Differing fields illuminated by steady or flickering lights were presented
separately to the two eyes. ‘The critical frequency of flicker was higher
when both fields were flickering than when one field flickered and the other
was dark, showing that a binocular summation of brightness occurred.
If one field was illuminated by flickering light, and the other by a steady
light of equal or less brightness, no increase of critical frequency occurred,
showing that there was no binocular summation of brightness. If the
steady light was much brighter than the flickering light, the flickering
frequency was slightly decreased.

If figures of differing complexity were introduced into the steadily
illuminated field, or into both fields simultaneously, there was in
general a decrease in the flickering frequency. This seems to show that
the critical frequency of flicker is a function of the nature of the fields, as
well as of their brightness, and that perceptual factors are of importance in
determining the critical frequency.

Division 2.
Mr. N. M. Batcuin.—A psychological approach to market research (2.0).

It is a mistake to think of market research as a new development. There
has always been market research of a crude, unconscious type. Recent
workers have sought to make market research an exact, numerical science,
in which the consumer is wrongly considered as a mechanical and invariable
unit.

True market research is not, and cannot be, a mathematical science.
The collection, classification and numerical analysis of data are necessary
preliminaries, but the essence of market research lies in the interpretation
of this data, not in terms of numerically expressed fact, but in terms of
psychological tendency.

The examination of the present state of a market is the beginning of
market research, but its end, if it is to have a constructive value, is less
concerned with what people do than with why they do it, and less concerned
with what is than with what will be in certain changed circumstances.

If market research is to continue and develop, it must provide constructive
suggestions rather than statistical information. ‘To that end it must study
the psychology of the customer and his probable reaction to change rather
than his conditioned responses to present circumstances.

Market research must be a market barometer, not a market thermometer.

Mrs. W. RaPHAEL.—A comparison of the psychological effects of employment
by the Civil Service, by large companies, and by ‘ family ’ firms (2.45).
There is a tendency for the goodwill of the worker towards the concern
in which he is employed to vary inversely with the size of the concern.
An attempt is made to study the causes of this tendency, such as the
increased subdivision of labour in large concerns, the loss of direct contact

SECTIONAL TRANSACTIONS.—], K. 549

with the management, the reduction in opportunities for promotion and
the increase of interdepartmental jealousies.

The attitude of the lower grade civil servant towards his work is very
unlike that of the averag: employee of a business house. This may be
partly due to different methods of recruitment, but is largely the effect of
certainty of employment, regularity of promotion and the traditions of
the service.

The modern trend is towards larger groupings of employees, both in state
and in commercial undertakings. Suggestions are made for minimising
the resulting bad effects for the worker.

Mrs. N. M. Barnes.—The function of the psychologist in the administrative
scheme (3.30).

The psychologist should be a recognised factor in the scheme of every
local authority. His functions will be both practical and advisory. He
should keep in touch with the problems of the normal school, and be
prepared to give advice in those matters where his scientific training is
likely to be of special value.

It will also be his function to deal with variations from the normal, and
to examine and advise the cases of special difficulty of learning or behaviour.
He should be able to draft children to some school in the area where such
cases can be dealt with. He would act in an advisory capacity to such a
school and keep in touch with the children’s progress.

He should devise means for keeping in touch with the problems of
parents and teachers, of keeping them informed of such discoveries in
psychology as are of special importance to educators, since the success of
his work is dependent on the degree of intelligent co-operation he can
count upon.

SECTION K.—BOTANY.

Thursday, September 7.

Prof. A. C. Szwarp, F.R.S—The past and present floras of the Kerguelen
Archipelago (10.0).

The occurrence of the fossil coniferous wood in beds believed to be
Tertiary in Kerguelen Land has long been known. A few years ago
Dr. de la Riie collected several specimens of impressions, the best of which
are foliage shoots and cone scales of Araucaria ; he found also fragments of
ferns and imperfectly preserved leaves of Angiosperms and other plants.
A general account of the geological and physical features of the Archipelago
is given, and the main features and geographical relationships of the present
flora are discussed.

A brief description is given of the fossil plants, the age of which is
believed to be Tertiary. Special attention is paid to the geographical
range of present and past representatives of the genus Araucaria. The
main purpose of the paper is to draw attention to phytogeographical
and paleogeographical problems raised by the recent discovery, particu-
larly to the difficulty of finding satisfactory solutions without assuming
the movement of land masses.

550 SECTIONAL TRANSACTIONS.—K.

Dr. H. HamsHaw THomas.—The nature and origin of the Stigma (10.45).

The conventional view of the carpel is a purely subjective concept. An
objective treatment of carpel morphology at once demands a provisional
solution to the question of the origin of the stigma. ‘The suggestion that
the evolution of the stigma preceded the inrolling of the carpellary leaf
involves physiological improbability. In seeking a new explanation we
need to know more of the structure of the stigma, and of the cells or tissues
which conduct the pollen tubes to the micropyles. The existing information
furnished by Capus, Guéguen, Juel, and others has been almost entirely ig-
nored by English and German morphologists. ‘The stigma is only the upper
termination of the “‘ conducting tissue ”’ of the style > (Capus). This tissue
usually extends downwards as a definite band or bands on the ovary wall
to the vicinity of the ovules; it appears to originate from papillate cells with
specialised contents, but becomes much modified in certain families (e.g.
Composite), especially in the style. In many cases the conducting tissue
extends to the bottom of the gynzcium before entering the ovary, and it seems
only possible to explain this on the assumption that the conducting tissue
(and therefore the stigma) originated at the base of the ovary and later ex-
tended upwards. The structure and development of the carpel and stigma in
Alchemilla, Rhodotypus,and other members of the Rosacez supports this idea.

On this assumption a picture of the evolution of the stigma and carpel
can be drawn which is possible from both the morphological and physio-
logical standpoints, the carpel wall representing two fused pteridospermous
cupules. This view provides an explanation of what we know about the
early stages of carpel development, of the vascular system of the carpel and
of the anatropous ovule. We now know of fossil plants which exemplify
most of the earlier stages in the supposed sequence of events.

The angiospermous flower is not homologous with a vegetative bud, and
it is quite possible that the Rosacez may be one of the more primitive
families now living.

Joint Discussion WITH Section A (Mathematical and Physical Sciences,
q.v.) on The X-ray analysis of fibres (11.0).

Alternative programme for Members not attending the above discussion :—
Prof. H. S. HoLpeEnN.—On a new pteridosperm stem from Shore (11.5).
The specimen described is a stem which has a markedly stellate outline
in transverse section. There is a small homogeneous pith surrounded by
primary xylem with mesarch protoxylem. The leaf-trace is mesarch and

undivided. In common with the group of species described by Kubart, this
stem forms a link between Lyginopteris and Heterangium.

Prof. J. DoyLeE—The nature of heterospory (11.20).

Dr. T. M. Harris.—On the reproductive organs of some early Bennettitales
(11.40).

Prof. R. A. FisHer, F.R.S.—The genetical system responsible for ever-sporting
stocks (12.10).
_ An outline of Winge’s theory of doubleness in stocks, and of its implica-
tions, is given.
A simple method of diagrammatic representation, applied to Miss Saunder’s
data of 1911, shows both that the observed excess of doubles is due solely

SECTIONAL TRANSACTIONS.—K. 551

to their greater viability, and that one family there reported was exceptional
in giving one-quarter doubles, as should the progeny of a plant freed from
the pollen lethal.

The close linkage between the pollen lethal and the factor for doubleness
is due to selection acting automatically in the propagation of the ever-
sporting lines, which has thus built up the ever-sporting character.

AFTERNOON.

Prof. N. G. BaLL.—The effect of nocturnal illumination on the subsequent
opening of flower buds (2.0).

The flowers of certain plants, Turnera ulmifolia var. elegans, Asystasia
gangetica, Ipomea spp. and others, which normally open in the morning,
are markedly affected when the buds are subjected to light during the pre-
vious night. In buds which have been treated in this way, the petals,
although they become elongated, may fail to diverge, and short-lived flowers
may become withered while they are still in the closed condition. A some-
what similar result is obtained when the buds are illuminated two nights
before they are due to open, even if this is followed by normal conditions
during the second night.

In most species where this effect of light has been observed, the failure
of the flower to open is correlated with a partial inhibition of the normal
hydrolysis of starch in the petals. This inhibition is associated with a
decrease in the diastatic activity of the cell-sap.

In the case of flowers which react in this way, a comparatively weak
illumination during the night is sufficient to prevent the buds from opening.
When a screen which only transmits the red rays is placed between the light
and the plant, the result is the same as it is with white light, but the infra-
red rays alone do not have this effect. On the other hand, when buds
are exposed during the night to the blue and violet rays only, even when
the intensity of the light is considerably increased, they behave in a similar
manner to those which have been kept in the dark and open normally.

Dr. B. T. CRoMWELL.—Berberine in the metabolism of Berberis Darwinii
(2.30).

Experimental evidence leads to the deduction that the alkaloid
berberine is a waste product of metabolism, and that it is produced in
largest amounts when conditions favourable for protein breakdown are
realised. Accumulation of the alkaloid in the root and stem bark takes
place from year to year. Application of inorganic nitrogenous salts alone
does not lead to increased alkaloid production, but if, in addition, glucose
is supplied, or organic nitrogenous compounds, such as asparagine, are
applied alone, rise in berberine content is observed. Light is an important
factor in the synthesis, and all tissues growing in absence of light show high
values. In shoots which have been grown for alternate periods in darkness
and in light, only those regions which have made growth in absence of light
exhibit high percentages of alkaloid. Withdrawal of essential elements
leads to variations in yield. Under conditions of nitrogen starvation,
alkaloid still accumulates : therefore it does not play the part of a nitrogenous
reserve. Deprivation of calcium does not check berberine production, but
withdrawal of potassium appears to inhibit synthesis. It is suggested that
the alkaloid is synthesised from carbohydrate and protein residues.

Excursion to Charnwood Forest.

552 SECTIONAL TRANSACTIONS.—K.

Friday, September 8.

Miss L. I. Scorr and Prof. J. H. Prresttey—On the Monocotyledon
shoot from the standpoint of development (10.0).

Miss M. T. Martin.—The structural and other differences between Sueda
maritima and S. fruticosa (10.40).

Suceda maritima and S. fruticosa are both maritime plants found on the
coasts of Britain; the former is a small herbaceous annual inhabiting the
lower levels of salt marshes, and the latter is a shrubby perennial found
characteristically on maritime shingle banks. The present investigation
includes a morphological and anatomical study of the two species, together
with an attempt to correlate their outstanding features with some of the
environmental factors involved.

In the first part of the paper a brief account is given of the two species ;
their habit, distribution, and the chief features of their habitats. This is
followed by a brief summary of their anatomical characters, selection being
made of any features of special interest, and particularly of the main points
of difference between the two. Finally, an attempt is made to correlate
these results with the environmental conditions, and to point out any bearing
which they may have upon the general problems of halophytic vegetation.

Miss M. M. Cuattaway.—The development of the rays of the Sterculiacee
(11.20).

The development of the rays in the wood of the Sterculiaceze has been
studied by means of serial tangential sections. New rays originate either
by subdivision of a fusiform initial or by the splitting up of a large ray ; the
latter process appears to be closely related to a low surface-volume ratio
in the larger rays, and is achieved by the reversion of ray initials to the
fusiform condition, and not by the intrusion of adjacent initials.

The number of initials in the rays is increased either by the swelling and
division of existing ray initials, or by the addition of fusiform initials which
are converted into ray initials, this latter method giving rise to sheath cells
(hullzellen), which are characteristic of the Sterculiacez.

In what appear to be the more advanced woods of this family the size of
the rays is strictly limited, and fusiform initials are only converted to ray
initials for the formation of new rays. ‘These small rays are often very
numerous, their surface-volume ratio remains high, and the reversion to
fusiform initials and splitting of the rays does not occur.

Prof. F. E. Litoyp.—Is Roridula to be regarded as carnivorous ? (11.50).

The two species of Roridula (R. gorgonias and R. dentata) are conceded to
be carnivorous. 'This concession appears to be based on their taxonomic
position as Droseraceez and on their possession of glands which simulate
those of Droserainform. Fenner (Flora, 1904) showed, however, that their
histological structure is different. As he worked on herbarium material, he
naturally overlooked an important fact—namely, that the abundant secretion,
which does indeed trap insects, is not water-soluble, but is rather a resin _
or an admixture of resins. It is soluble in ether, acetone, etc., and is acted —
upon by alkali and acid, being changed into a brittle, frothy substance.
There are no glands which secrete a water-soluble mucilage, nor any glands
which might be regarded as digestive, comparable to those of Drosera. -

The gland in its simplest expression—i.e. a small one—consists of four

SECTIONAL TRANSACTIONS.—K. 553

longitudinal series of epidermal cells with a thick cuticle. In a large gland
the number of longitudinal series of cells is multiplied and the interior isnow
occupied by a parenchyma. Thus far, Fenner is correct. There are,
however, no pores or fissures in the cuticle, the sole opening being apical
and schizogenous (Lloyd, Trans. R.S.C., 1933). Leading to this opening
there are intercellular canals, one between each two longitudinal series of
epidermal cells and bulbous towards its proximal end. These are filled
with the resinous secretion, which escapes only through the apical opening.
The findings indicate a negative answer to the question proposed.

Dr. E. N. Mires Tuomas.—Recent work on the significance of seedling
anatomy (12.0).

AFTERNOON.

Prof. Dame HELEN GwYyNNE- VAUGHAN, G.B.E., and Mrs. H. S. WILLIAM-
son.—The development of Ascophanus aurora (Crouan) Boud. (2.0).

Ascophanus Aurora (Crouan) Boud. is a minute, coprophilous fungus ;
it is moneecious and homothallic. The antheridium is globular, borne at
the end of a stalk. The oogonium is ovoid, somewhat twisted, with a
multicellular trichogyne. The sexual nuclei fuse in the oogonium and a
few relatively large ascogenous hyphe grow out, in which the nuclei lie in
single file. After simultaneous division of the nuclei in the ascogenous
hyphez, walls are formed across the spindles, so that the hypha is divided
into a terminal uninucleate cell, a basal uninucleate cell, and an intervening
series of binucleate cells. Asci are formed in the usual way, and three
successive divisions give rise to the nuclei of the ascospores.

Miss M. Nosie.—The life-history and morphology of Typhula trifolit
Rostrup (2.30).1

The life-history and morphology of Typhula trifolit has been investigated.
Sclerotia are formed in multispore cultures, and these germinate freely and
produce the hymenophores ; the latter are also produced directly from the
mycelium,

The fungus is probably heterothallic ; clamp connections are present
in multispore cultures but are not found in the monospore cultures, and these
latter do not produce typical sclerotia or hymenophores.

The parasitism of T. trifolii is being investigated. The distinctions
between T. trifolii, T. bete and T. variabilis are not well defined.

Dr. B. Barnes.—British aquatic fungi (3.0).

The lower Phycomycetes have been little studied in Britain, but many
species have been described in Europe and in North America. Recently,
several interesting forms have been found in this country. They have been
obtained from masses of moribund alge, from twigs, and from other
vegetable debris taken from reasonably clean ponds and ditches. Such
substrata, when placed in small quantities in one to two litres of cool, clean
tap water, will sometimes develop crops of Phycomycetes in a week or so.
Sterilisation of the water is not necessary unless it is desired to show that
a given fungus occurs in a given body of water. ‘The fungi found include
species of Monoblepharis, Gonapodya, Rhipidium, Sapromyces, Pythiomorpha

1 In the absence of Miss Noble owing to an accident, the communication was
tead by Dr. A. H. Campbell.

U

554 SECTIONAL TRANSACTIONS.—K.

and Pythiogeton ; it is probable that further search will add Allomyces and
Araiospora to the British flora.

The peculiar Hyphomycete, Tetracladium Marchalianum, sometimes
occurs among dying alge.

Other interesting Phycomycetes, in particular Thraustotheca clavata and
Geolegnia inflata, have been obtained from the soil of a garden in South
London. These fungi, with species of Pythium, and numerous forms not
yet identified, developed on boiled cress seeds placed in a shallow layer
of water and soil and subsequently transferred to clean water.

All these forms deserve further study, as they are of great interest
morphologically, and of importance taxonomically.

Saturday, September 9.

Excursion to the Peak District.

Sunday, September 10.
Excursion through Rutland (via Oakham), Stamford, etc.

Monday, September 11.

PRESIDENTIAL ADDRESS by Prof. F. E. Luoyp on The types of entrance
mechanisms of the traps of Utricularia (including Polypompholyx)
(10.0). (See p. 183.)

Prof, J. McLean THompson.—On the acarpous nature of certain forms of
inferior ovary (11.30).

Within recent years the author has been privileged to examine a wide
range of Scitaminean plants, and in particular to examine the development
and morphology of their inflorescences.

He has been compelled to the conclusions that many forms of cymose
inflorescence in the affinity have arisen by reduction of branched cone-
bearing strobili, with flowers arranged in spiral order, and that sub-floral
branching is not involved. The final stages in reduction of the intermediate
cymes are simple spikes.

The flowers themselves are considered to have been crateriform, with
vegetative organs displayed} in spiral succession on the outer surface of the
crater and with microsporangiophores on and towards the rim. ‘There
were neither carpels nor styles, but the crater was occupied by mega-
sporangiophores produced in spiral manner. The latter are the modern
ovules. The crater is considered to have been reduced and its margin to
have been curtailed, so that upper microsporangiophores came to lie on the
inner rim. Here they were sterilised to styles, and their subjacent areas of
support within the crater became the modern placente. ‘The acarpous
view of the ovary is supported by evidence of progressive contribution of
the andreecium to the style without involving the organisation of the ovary.

Mr. F. F. Hype.—Notes on the floral morphology of the Campanuloidee
(12.15).

The structure of the flower in a number of genera is described with special
reference to the vascular anatomy. ‘The bearing of the investigation on

SECTIONAL TRANSACTIONS.—K. 555

such problems as those of the syngonous condition (epigyny) and the nature
of the gynecial members is indicated. Reference is made to the floral
development of some of the species. The paper constitutes a pre-
liminary account of an investigation of the floral structure throughout the
Campanulacez.

AFTERNOON,

Exposition of exhibits in the laboratories of the Department of Biology,
University College, Leicester (2.15).

Tuesday, September 12.

Joint Discussion with Sections D (Zoology, g.v.) and I (Physiology)
on Genetics (10.0).

Alternative programme for Members not attending the Genetics Dis-
cussion :—

Prof. F. A. F. C. Went.—Recent progress in the study of growth-substance
(Auxin) in plants (10.0).

Although growth substances in plants (auxins) have been studied else-
where, the present paper is limited to an account of the work done in the
Botanical Laboratory at Utrecht. As far as the influence of auxin on the
cell wall is concerned, Heyn is continuing the studies he began at Paris
and Leeds (i.e. X-ray investigations of cell walls), which led him to dis-
tinguish between plastic and elastic extension. The first of these is due
to the action of growth substance and is irreversible. "The elastic extension
can be explained by a relaxation of the outer layers of the cell wall, due to
the influence of strain. By studying the load extension relationship of
the wall he was able to provide an explanation of differences of elastic
extensibility, which occur as a result of changes of the rate of elongation.

A study of phototropism with seedlings of Raphanus and Lepidium made
by Van Overbeek has given results by which a synthesis of the theories of
Blaauw and F. W. Went could be obtained. Here the auxin is produced
in the cotyledons under the influence of light, and it flows towards the base
in a longitudinal direction so long as the seedlings are kept in the dark or
are equally illuminated on all sides. If, however, unilateral illumination
is used, the flow of auxin is diverted laterally, so that the shaded side gets
more growth substance than the other one and consequently grows faster.
A curyature therefore results.

On the other hand, light has a very distinct retarding influence on the
growth of these seedlings. It may be proved that this—which is obviously
the light-growth reaction of Blaauw—is due to a diminished sensibility
of the cells to growth substance. The same quantity of auxin with the same
cell gives a greater elongation in the dark than in the light ; whether this
is a direct action of radiation on the cell walls or not has yet to be seen.
Lateral illumination thus has two different effects on the seedlings of
Raphanus sativus—(1) it diverts the growth substance to the shaded side,
in consequence of which this side will grow faster ; (2) it diminishes the
reaction of the illuminated cells to growth substance, in consequence of
which the illuminated side will show a lesser reaction. Both effects are
additive, and the result will be a positive phototropic curvature, the amount
of which could be calculated by Van Overbeek. A somewhat similar

556 SECTIONAL TRANSACTIONS.—K,.

explanation, though not going so far, has been put forward by Du Buy for
the phototropic curvature of oat seedlings.

Dijkman, studying the geotropic curvature of seedlings of Lupinus, has
shown that here also the explanation of Dolk holds good. When these
seedlings are placed in a horizontal position the distribution of the auxin
is altered, the lower half getting more than the upper one ; consequently it
must grow faster, and a negative geotropic curvature results. ‘The amount
of the curvature may be calculated from the distribution of the growth
substance.

Bottelier has made a study of protoplasmic streaming in the coleoptile
of Avena. The influence of temperature is small in young plants, but in
older ones he obtained a ratio for the velocity of streaming at 16:5° C. to that
at 24° C. of 10 to 21-3, which is almost identical with the ratio found by Van
der Wey for the velocity of the transport of auxin. Light, especially of short
wave-length, has a very pronounced influence on the velocity of protoplasmic
streaming ; it is very remarkable that this influence is almost the same as
in the light-growth reaction according to the data obtained by Van Dillewijn
several years ago.

The amount of protoplasmic streaming was not always the same, but it
became evident that it changed with the sensitivity of oat seedlings to the
growth substance. This amount is small when the sensitivity is low, and
greater with a higher sensitivity.

An investigation into the factors which influence this sensitivity in a room
kept at constant temperature and constant humidity is in progress under
the auspices of Kégl, and is being carried out by Haagen Smit and J.J. Went.
There is sometimes a certain periodicity in this sensitivity, so that at a
certain time of the day it is high, at another time low. ‘They could get rid
of this periodicity by the use of metal boxes in the constant temperature
room. Whilst it was not necessary to make use of leaden boxes, they had
to be made of a good conductor of electricity. Hence it was clear that
cosmic rays had no direct influence on the phenomenon, but possibly the
electrical conductivity of the air played some part in it. The investigators
could alter the sensitivity of the seedlings by passing a feeble electric current
through them. When the tip is negative with respect to the base the sen-
sitivity is lowered ; in the opposite case it can be carried up to an amount
never yet found under natural conditions. ‘The currents necessary for
obtaining the same deviations of the sensitivity as under natural conditions
were of the order of 10-§ ampere. Oat seedlings are remarkably good
objects for such experiments, since the effect can be quantitatively measured
in them much better than in other cases.

Miss E. N. SparsHott.—Tuberisation, with special reference to the
development of Testudinaria elephantipes (10.40).

The adult tuber of Testudinaria elephantipes is semi-globular with a
flattened base from which roots arise centrifugally. Except at the apex
the surface is covered with cork, thin over the base, but thick and deeply
fissured elsewhere, owing to internal growth. Each season one or more
new climbing vegetative shoots develop in the axil of one of the scale leaves
surrounding the apex of the tuber.

The embryo shows no tuberisation. The plumule remains very short
and bears one relatively large leaf. Assimilates accumulate in the hypo-
cotyl, which rapidly undergoes tuberisation. Early thickening results from
division and hypertrophy of existing cells. 'Tuberisation is continued by
secondary growth mainly from a pericyclic ‘ growth zone,’ but also from

SECTIONAL TRANSACTIONS.—K. 557

successive phellogens. The ‘ growth zone’ resembles an inverted cup
with a hole in the bottom—i.e. beneath the apex of the tuber. Apex and
base are further developed from the surrounding meristem and respectively
produce a sympodium with reduced internodes and fibrous roots.
Adventitious buds may develop when a fissure penetrates beneath the
‘ growth zone ’ and causes its cells to collapse in that area. The conditions
thus brought about are comparable with those obtaining at the tuber apex.

Miss L. M. Wicxs.—The significance of the inverted bundle system (11.20).

In Amaryllidaceous leaves the development and course of the vascular
system was studied, especially in concentric leaves on account of the presence
of two systems of vascular bundles : (i) a system of large normally orientated
bundles ; (ii) an adaxial system of small inverted bundles. Throughout
the leaf-limb the two systems are connected by transverse commissures.
In the leaf-base the relationship of the inverted bundle system to the
normally orientated one and to the stem system varies, and the following
three types were found :

(1) The Ianthe type—Certain normally orientated bundles in the bi-
facial leaf-base curve round and enter the concentric leaf-limb as inverted
bundles.

(2) The Agave type—The inverted bundles are formed by special
branches given off from the normally orientated bundles in the leaf-base.

(3) The Narcissus type-—The most marked variation occurs in Narcissus,
where the inverted bundles pass down from the leaf-limb into the upper
part of the leaf-base, where they end abruptly in groups of small tracheids.

According to the Phyllode theory the concentric monocotyledonous
leaves are morphologically petioles, the inverted bundles resulting from the
flattening of a petiole with a circle of vascular bundles as seen in transverse
section. It is difficult to see how such variations as shown in the three types
here enumerated can be made to fit in with the phyllode theory.

The inverted bundles can be considered as secondary structures developed
during the evolution of the primitive monocotyledonous leaf, possibly to
increase the amount of vascular tissue in order to supply the increased
amount of assimilating tissue of the concentric leaf.

Prof. G. Senn.—The influence of light on the permeability of the plant
cell (12.0).

AFTERNOON.
Business MeerInG of the Section (2.0).
Discussion on The teaching of botany in courses of biology (3.30).

Prof. J. R. MatrHews.—Semi-popular lecture—The British flora and
some of its problems (5.0).

Wednesday, September 13.

Visit to demonstration by the Timber Fireproofing Co., Ltd., Market
Bosworth (10.0).

558 SECTIONAL TRANSACTIONS .—K*.

DEPARTMENT OF FORESTRY (K*).

Thursday, September 7.

CHarRMAN’s Appress by Major the Hon. RicHarD CoKE on A system of
forestry for the British Isles (10.0).

(1) The need for a system which is in accordance with nature’s methods
and which, besides aiming at the production of timber of the utmost com-
mercial value that is possible under the local conditions, has due regard for
sporting amenities.

(2) Reasons for and against planting large blocks of one species only.

(3) Reasons for and against uneven-aged mixed woods known as
‘ Jardinage ’ in France.

(4) The prevalent neglect of encouraging natural regeneration in the
British Isles, and the economic importance thereof.

Lt.-Col. E. Pratt, M.C.—Factors affecting the propagation and rate of
growth of Salix cerulea (11.0).

At its meeting last year, this section of the Association discussed the
systemity and origin of the cricket-bat willow, and Dr. Burtt Davy ex-
pressed the view, which was undisputed, that the Essex or Chelmer Valley
strain was, whatever its origin, the most reliable one for growers to plant.

Having decided on the correct strain, we need to consider the factors
which produce the growth of the large rings of white wood needed to make
the popular light cricket bat.

Salix coerulea is a tree naturally producing a red timber. The
cricket-bat manufacturer aims at a bat weighing a little over two pounds,
and the best way to obtain this is from trees which have made such a rapid
growth, that seven to eight years’ thickness of white sap wood is obtainable.
This can only be done by considering every factor which tends to produce
rapid growth, and by utilising the timber before that growth has been
checked.

The factors to be considered are, the wood of the original cutting and its
development into a strong pollard, the cultivation of the shoots of that
pollard to produce the quickest and straightest growth, the question whether
the set should be put in the nursery to grow a root before planting out,
the best conditions as to site and propinquity to other trees, the manuring,
pruning, and after-care of the growing tree, precautions against disease,
and, finally, the decision as to the best age at which to sell and the best
method of marketing.

Mr. Wo. Datiimore.—Trees and the countryside (12.0).

The important part played by trees in the landscape effect of the country-
side is emphasised, with special reference to park, field and hedgerow trees,
as apart from those grown in woods and forests. Some of the forces
operating against the maintenance of such trees are discussed, and sugges-
tions made for the better selection of trees for planting in small shelter
woods, and spinneys, and in hedgerows on large estates and farms, with
a view to maintaining the amenities of the countryside and bringing profit
to the owners. Reference is also made to the need for better cultural care
in the management of park and hedgerow trees. Attention is directed to
the danger to healthy trees by allowing dead, dying and otherwise worn-out

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trees, that have no definite historic value, to stand in fields, woods and
parks, and a plea is made for their removal and for planting young trees to
take their places.

AFTERNOON.

Excursion to Nanpanton, Loughborough via Thurcaston, Woodhouse,
visiting Olverscroft Priory and Bradgate Park (by permission of Alan
Moss, Esq.).

Friday, September 8.
Mr. H. Munpt.—Good forest and thinnings (10.0).

Foresters utilise results from the past, live by the present, and work for
the future. Aims and means ought to be discussed, understood, explained
by measurement, graphs and valuations, suitable for international inter-
course. Forests characterise a country and react strongly upon the life
of men. A complex of ‘ stands’ and ‘ cultures’ do not suffice; a forest
is required : natural, vigorous, with big trees and great values, in constant
activity everywhere, beautiful and still rooted in sound economy.

Thinnings every two to five years can transform the forest astonishingly
and augment both revenue and capital-value considerably. Where 10 to
15 per cent. of the volume each two to five years is a reasonable revenue,
three times as much every six to fifteen years will be destructive. By con-
stantly assisting the best and biggest trees, we can-improve the assimilation
system, the forest climate, self-sowing, the form of young plants and the
flora and fauna. Moderate volumes of great value and big increment can be
furthered and the periods of fallow, so ruinous for forestry-economy,
avoided.

Wonderful progress is obtained by new species of trees and better race,
but above all it is good forestry to make the most of what already exists
and carefully keep up that continuity which belongs to nature.

Mr. James MacponaLp.—Some effects of thinnings in coniferous plantations
(11.0).

Mr. A. P. Lonc.—The utilisation of thinnings (12.0).

AFTERNOON.
Visit to the timber yards of Messrs. W. Gimson & Sons.

Saturday, September 9.

Excursion to Boughton Estate near Kettering (by permission of the
Duke of Buccleuch).

Sunday, September 10.
Excursion to Belvoir (by permission of the Duke of Rutland).

Monday, September 11.
The Hon. Nicer A. OrpE-PowLett.—Forestry and sport (11.15).

Debt of forestry to sport in the past. Large areas planted for covert
that would otherwise have remained derelict, Original natural woods

560 SECTIONAL TRANSACTIONS.—K*.

maintained through early and middle ages solely for sporting purposes.
On majority of estates before the war little planting but for sport. Debt of
sport to forestry, very little owing to general absence of organised forestry.
Introduction of new species cuts both ways. Present-day position. Uni-
versal interest both in sport and forestry. Financial importance of both
subjects. Vital necessity of friendly relationship. Pessimism no excuse
for inaction. Points of contact. Very large areas of woodland are of no
value for sporting. Ground game should not come under sporting.
Pheasant and grouse shooting the only types of sport affected by forestry.
Very few grouse moors should be afforested from the financial or silvi-
cultural point of view. Pheasant shooting inevitably very closely bound
up with forestry. Requirements of pheasant pr serves. Coverts, nesting
ground, flushing points. Effects on these of systematic forest management.
Importance of size and distribution of woodland area upon the sporting.
Treatment of (a) large blocks, (6b) scattered woodlands. Formation of
flushing points for permanent covert.

Dr. M. C. Rayner.—An account of recent experimental work on Mycorrhiza
in relation to forestry.

Experimental evidence is offered that there exists a direct causal relation
between presence of mycorrhiza (where there is evidence of normal func-
tioning) and satisfactory growth in seedlings of several species of Pine.

On soils where formation of mycorrhiza by young trees is inhibited
or markedly delayed, it can be expedited by inoculation of seed plots,
previous to sowing, with small quantities of humus known to contain active
mycorrhizas of the host tree.

It is not believed, however, that this treatment alone will remove the
trouble permanently on certain soils, since the development and func-
tioning of healthy mycorrhiza is conditioned by the physiological state of
both roots and mycelium. This in turn is bound up with environmental
soil factors, and it may be expected therefore that experimental modification of
such factors will be reflected in the condition of the root system, both in
regard to the amount and kind of mycorrhiza formed.

Following the adoption of a working hypothesis that the correct environ-
ment is bound up with certain humus constituents of the soil, the results of
experiments involving the application of special organic composts are
described and illustrated by means of lantern slides.

Tuesday, September 12.

Mr. J. A. B. Macponatp.—Preliminary results from peat planting experi-
ments at the Lon Mor Experimental Station (10.0).

This area of poor Scirpus peat moorland was selected in 1925. The
exposure is full and the underlying rock an acid gneiss.

Before draining the dominant Scirpus was accompanied by much Erica
tetralix. In addition to Sphagnum species Rhacomitrum was frequent.
The lichen Cladina and the liverwort Pleurozia also occurred.

Previous investigations had shown notched planting to be radically
unsuited for this type of ground.

To permit plant roots to ramify without delay the system of planting,
later to be known as the ‘ shallow-turf ’ method, was devised.

From an early date it was intended to investigate mechanical means ‘of
draining and turf provision in order to reduce otherwise prohibitive costs.

SECTIONAL TRANSACTIONS.—K*. 561

Amongst projects tackled experimentally were the following :

(1) Method of inserting plants into a shallow turf and comparison of
single shallow turf-method with other systems of turf planting.

(2) Manuring and top dressing, chiefly with phosphates ; inoculating
with active peat.

(3) Effects of shelter.

(4) Effects of preparation in advance and of turf decomposition ; season
of cutting peat.

(5) Use of peat from different depths.

(6) Intensity of drainage.

(7) Age and type of plants.

(8) Trials of different species and races.

Several of the experiments embraced costing trials.

Experimental lay-out of various kinds has been used.

Preliminary results show amongst other things :

(a) The successful start made by surface planted trees.

(b) Beneficial effects from phosphatic manuring.

(c) Preparation in advance is, apparently, unnecessary.

(d) Shelter is of secondary importance.

(e) Surprisingly good growth of various exotic conifers compared with
species previously considered more hopeful.

While results obtained are only of a preliminary nature everything

points to the urgent need for—
(1) Cheap draining and turfing by mechanical means.
(2) Cheap supply of suitable phosphatic manure.

Mr. W. A. Rosertson.—Public opinion in the Empire upon forestry (11.0).

Forestry is an unpopular subject or, at best, of indifferent interest to the
public in the Empire and in the English-speaking part of the world. Why
is it so?

In the Dominions and probably most of England, forestry stands for
plantation work and little or nothing else, and plantation ‘is associated
mostly with conifers, and exotic conifers at that. Apart from this, forests
are only associated with collections of decaying veteran trees esteemed for
picturesque or sentimental reasons.

The reliance on imported supplies of timber is of very old standing,
while home woodlands are associated with sport only. Does this account
for public indifference to forestry ?

To get forestry properly appreciated in England and the Dominions
ought not the supporters of forestry to try to give emphasis to the position
of forests as part of the general land economy of the country and demonstrate
the continuity of forests: the employment they give, the tending, pro-
tection and management that they require ; and get away from the idea that
forestry means the planting of an area and its neglect until the owner wants
some cash? Some suggestions as to how this may be tried for, if not
definitely achieved.

Wednesday, September 13.

Excursion (with Section K) to the works of the Timber Fireproofing
Co., Ltd., Market Bosworth, near Nuneaton.

562 SECTIONAL TRANSACTIONS.—L.

SECTION L.—EDUCATIONAL SCIENCE.

Thursday, September 7.
TRAINING FOR BUSINESS AND ADMINISTRATION :—

Principal H. Stewart, C.M.G., D.S.O.—University training for
business (10.0).

(1) A function of University to train mind ; not a function to turn out
ready-made business man any more than complete engineer. Practical
training essential ; given outside, and preferably after, University course.

(2) Two types of training : (i) course without commerce bias ; (ii) course
with commerce bias. Opinion divided as to which is more suitable. Many
prefer former, regarding manner of training more important than subject.

(3) Limitations. University cannot provide the fundamental personal
qualities essential : those of character, not intellect. Prolonged academic
work unsuitable. University trainees more likely to develop established
business than build up from nothing.

(4) Advantages. Training to think, grasp principles and essentials.
This is the primary advantage. Secondary advantages are: (i) training in
use of language; (ii) moulding of character in microcosm of student life.
Cultural interests and athletic prowess less relevant. Given the fundamental
qualities, University education valuable for higher positions. Graduates in
early business career behind other recruits in technical knowledge, after-
wards definitely superior in judgment, vision, executive power.

(5) Changed attitude towards apprenticeship on probation at small
salary, as in engineering. Training after entering business. Difficulty of,
and case for, preferential treatment.

(6) University only one of several avenues, but of growing importance.
Increasing necessity and demand for well-trained minds in business.

Mr. T. Kincbpom.—Secondary school training for business (10.15).

General aims of secondary school education in preparation for life as well
as livelihood—cultivation of qualities as well as inculcation of knowledge.

The large increase in the numbers receiving secondary education means
that far more pupils must go into business. Ought this to mean any
modification in our methods and curriculum? Employers seem to be
satisfied on the whole with the product they get. ‘The School Certificate
gives a good general grounding in a variety of subjects. It should not be
confused with Matriculation. Roughly, only half the pupils in secondary
schools secure the School Certificate, and many pupils well suited for
business cannot pass it. Value of headmaster’s recommendation. Danger
of the black-coated professions securing the pick of the brains.

Qualities desirable in business, such as method, tidiness, courtesy, adapta-
bility, resourcefulness, initiative, and leadership, can only be developed
if pupils stay longer. A year’s course for business pupils of 16 plus,
whether they have passed the School Certificate or not, is very desirable.
Possible co-operation with technical colleges. Suggested curriculum to
include modern languages, economics, manual work, and perhaps shorthand.

Mr. E. I. Lewis —The requirements of a business career (10.30).

For many years secondary schools have been preparing boys for certain
professions and branches of industrial life, particularly in science and

SECTIONAL TRANSACTIONS.—L. 563

languages. ‘To make further provision for an educational type will there-
fore violate no principle. Any subject or any number of subjects can be
taught in a specialised manner, and almost any one of them can be entirely
educative. The study of industry and commerce is no exception. The
schools profess to prepare boys for work and leisure. Since industry and
commerce touch nearly everyone directly or indirectly, and everyone by his
franchise can influence their course, a well-educated man to-day should
know enough of them to understand at least what his daily journal seeks,
for the country’s sake, to teach him. The boy who enters industry or
commerce nowadays goes to an extremely complicated and highly depart-
mentalised institution. Leaders of industry of the future must inevitably
be more cultivated in business matters. ‘To prevent an early narrowness of
view, and to promote the growth of wide interests within business concerns—
to provide a bridge from school life to business life—a young man, before
he enters the office or the works, should have studied, in an educational
manner, some of the more pressing problemis of business life and organisa-
tion. The paper indicates briefly the scope and the principles upon which
to construct such a course.

Mr. F. W. Lawe.—Selection and training of university men in a depart-
ment store (10.45).

The actual process of the selection and training of University men in
one firm is examined, and some light thrown on the general problems of
transition and adjustment.

Two schemes of selection and training, covering eleven years in all, have
been tried by the Department Store in question. The first, which ran for
seven years, was characterised by liberality of outlook in selection and light-
handed control in training. The training course consisted, as in many
firms, of a sojourn in each of the important departments. The trainees
acquired their knowledge successfully or otherwise in accordance with their
individual characters. The results were not encouraging. Of eleven
selected, five remained at the end of a seven-year period, and only three
at the end of eleven years. All three remaining fully justified their choice.
The second scheme, which superseded the first, has been in action only
four years. Seven selections have been made. None have left. The three
first selections are already in responsible posts and promise well. ‘The
characteristics of the second scheme are (a) the limitation of entrants to
First Class or good Second Class Honours men; () the introduction into the
training course of methods specially devised for rapid and accurate learning ;
and a tutorial system intended to develop initiative and to foster the
adjustment of personality.

Mr. G. C. Wickins.—Training of the Post Office counter staff (11.0).

INTRODUCTION.—The detailed description in this paper applies to
the counter staff in the London Postal Service.

RECRUITMENT.—The male Probationary Counter Clerks are recruited from
Boy Messengers. The female Probationary Counter Clerks are recruited in
two ways : (a) open competition ; (6) limited competition. The‘ limited ’
candidates enter the service as Girl Probationers.

TRAINING.—(a) General—The fundamental principles underlying the
scheme of training are that it should be of a practical nature, and that the
instruction should be so arranged as to develop the interest of the students
in their own work, and to enable them to understand the relation which
that work bears to other Post Office activities.

564 SECTIONAL TRANSACTIONS.—L.

(b) Classes—Separate classes are arranged for male and female students,
and they are divided into :

Junior Class for new entrants—course, twenty weeks, half-day.

Senior Class for counter clerks who are working in post offices, but are
not yet qualified in the more important counter duties—two weeks’
course.

Supervising Class for counter clerks who are about to substitute on
supervising duties—one week course.

(c) Instructors—The instructors for the junior and senior classes are
senior counter clerks. Supervising officers take the supervising classes.

(d) Funior Class —(i) Syllabus—The Standard Time Tiable—Appendix I

—shows the subjects taught, and the order in which the lectures are

given.

(ii) Lectures —Summaries of the subjects dealt with in the lecture are
dictated at intervals to the students after the instructor has explained
the subjects. Accurate summaries are an important feature of the
work.

(111) Practical work —The students act in turn as counter clerk and
‘member of the public,’ and each transaction is completed in the same
manner as in actual business.

(iv) Tests.—Written, practical, and recapitulative practical tests
are included.

(v) Completion of training—The training is completed at a post
office counter.

(e) Senior Class—Co-operation and discussion between instructor and
students are encouraged. A précis of each lecture is distributed, on which
students make their own notes.

(f) Supervising Class—The main features are lectures by heads of

departments on general questions of supervision, and practical instruction
in Post Office counter accounts.

DIscussIoN (11.15). (Principal J. Cameron Smalt, O.B.E.)

REPORT OF COMMITTEE on Science Teaching in Adult Education (Prof.
J. L. Myrss, F.B.A.; Dr. C. H. Descu, F.R.S.; Mr. A. S. Firtu;
Miss H. Masters; Mr. R. J. Howrie; Prof. R. Peers; Mr. G. C.
Hickson) (11.45).

DISCUSSION.

AFTERNOON.
Visit to Loughborough College.

Friday, September 8.
EDUCATION FOR THE INDUSTRIES OF THE East MIDLANDS :—
Dr. P. W. Bryan.—Geographical and general introduction (10.0).
Mr. H. Satt.—The boot and shoe industry (10.20).

Five problems have to be considered :

(1) The change in the conduct of the industry from home to factory
work,

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(2) The change from hand operations to almost identical operations
done by machines.

(3) The lack of uniformity in the industry’s raw materials.

(4) The standard of ‘ studentship.’

(5) The lack of suitable books of reference, and the means adopted
up to the present to solve this.

Mr. JOHN CHAMBERLAIN.—The hosiery industry (10.35).

Education for the hosiery industry was originally of a technological
character, and the subject was treated in a very general manner, but, as the
trade developed, it was found necessary to form grouped courses of instruction
for the training of persons occupying functional positions, as follows :
(1) General hosiery course. (2) Course for designers and makers-up.
(3) Dyeing and finishing course. (4) Administration and salesmanship.

Course (1) is intended to give the student a clear idea of trade processes
and machinery, as well as the sciences underlying the industry. Yarn
testing and fabric analysis form part of this course. Both full-time and
part-time courses are available for this course and courses (2) and (3).
Course (2) is based essentially on a knowledge of art, especially dress design,
but includes technical subjects, such as the theory of knitting, stitch effects,
patterning mechanisms and fabric production. Course (3) has a bias
towards chemistry and provides instruction for the dyeing of all fibres used
in knit-wear. Analysis of reagents used and testing of dyed materials is
specially emphasised. Finishing processes for knit-wear are included in the
course. Course (4) is as yet in the experimental stage, but includes a study
of business methods, commercial and industrial administration, economics,
salesmanship and modern languages.

Dr. H. ScuorretD, M.B.E.—An experiment in education—the Lough-
borough scheme of engineering training on production (10.50).

Great controversy has always ranged around the subject of the best
scheme for the training of the engineer, but all seem agreed that practical
instruction is essential.

It is growing increasingly difficult to secure an all-round training. Mass-
production methods in engineering have come to stay, and the all-round
kind of experience that the old apprentice received is no longer available.
On the practical side the best boy tends to have the least chance. ‘There is
little connection between the offices of the firm and the works, and pro-
motion inevitably seems to be more open to a bright youth in the office
than for an equally clever boy in the foundry or the machine shop. On the
academic side there is a great tendency to grow stale. University syllabuses
tend to govern curricula, and these concern themselves with the mathe-
matical and physical sections of the work only, taking little account of
management, with all its problems, and the technique of selling goods.

The so-called engineering workshops of the modern University or
Technical College are laboratories rather than workshops, and gifts to
Technical Institutions are often made from plant no longer required for
modern productive industry. Depreciation is still held to be a governing
factor, rather than regard being paid to considerations of obsolescence.

To overcome these difficulties several schemes have been tried. ‘The
productive college first came into being in America, and in this country it
has been very highly developed at Loughborough. 'The University lecture
rooms and laboratories exist side by side with the productive workshops of
the commercial engineering firm, and in one and the same set of buildings,

566 SECTIONAL TRANSACTIONS.—L.

under the same control, using a week-in and week-out system, the student
in a five-year course experiences all sections of productive output, from the
foundry to the drawing office, and from the machining and fitting shops
to the tool room. He is brought up against estimating, costing, and selling.
The exercise no longer exists, and the student is engaged in interesting
productive work throughout his whole course.

Mr. J. R. Bonn, M.B.E.—Agriculture (11.5).
Mr. W. A. BrockIncToN, C.B.E.—Summation (11.20).

DISCUSSION (11.35).

REPORT OF COMMITTEE on The teaching of science, with special reference
to biology (Dr. Littan J. CLarKE; Dr. E. L. Hirst; Mr. G. W.
O.trve; Sir F. Gowianp Hopkins, Pres.R.S.; Dr. W. W.
VAUGHAN) (12.0).

DISCUSSION.
AFTERNOON.

Visit to Rugby School and Rugby Day Continuation School.

Monday, September 11.

Jomnt Session with Section J (Psychology) on The predictive value of
school examinations and psychological tests :—

Prof. C. W. VALENTINE.—The unreliability of entrance examinations
to secondary schools and the awarding of university scholarships
(10.0).

Dr. D. W. Oates.—Some factors in scholastic ability and their pre-
dictive value for secondary education (10.15).

(1) Why predictive values are low. The implied assumption that the
criterion is non-variable and represents the ideal. The distinction between
ability and capacity.

(2) The need for a sharper definition of what the secondary school
demands. Recent evidence of the importance of specific abilities in the
secondary school. ‘ Success in the various subjects depends more upon
specific abilities than upon general capacity.’

(3) The ‘ snapshot’ impression of a single examination, even with the
best examination technique, may present a distorted and badly weighted
index of a pupil’s normal achievement and power. The discrepancy
between the entrance examination result and subsequent achievement is
not necessarily due to faulty measures of achievement, but may be the
natural result of other factors.

(4) The results of investigations of the factors in scholastic ability. The
importance of some traits which we can crudely describe but for which we
have at present no tests that are even approximately objective. The bearing
of certain personality factors other than intelligence upon academic success.

(5) The predictive value of a written examination, intelligence test,
head-teachers’ estimates, and ratings and tests for temperament qualities
as revealed by correlation with subsequent secondary school achievement.

SECTIONAL TRANSACTIONS.—L. 567

Mr. F. BarracLoucH.—The reliability of entrance examinations to
secondary schools (10.30).

In recent years local education authorities have paid much attention to
the syllabuses for scholarship entrance examinations, but in many cases a
corresponding lack of attention to the machinery of the examination has
vitiated their efforts.

School records and the position of children in non-provided schools are
matters requiring further research.

In making a comparison between the results of scholarship entrance
examinations and school certificate examinations the methods of analysis
of variance enable the investigator to test the significance of his results.

The work of Prof. Valentine regarding the predictive value of scholar-
ship entrance examinations revealed the need for additional research, and the
results of an investigation conducted in ‘ non-Valentine’ areas are given.
The predictive value of intelligence tests is also discussed.

Mr. F. SaNDON.—Difficulties in using entrance examinations, intelligence
tests and school results for comparative purposes (10.45).

Prediction is a question in probabilities, and our estimate of a, the
ability to profit by education at a secondary school, depends on correct
statistical procedure. No test, by reason of various kinds of variability,
will be perfect, and any test will only correlate to some degree with the
criterion. Even if we have a theoretical correlation table with r, between
mark and criterion, as 0-85, in the top one-fifteenth two-fifths of the selec-
tion should not be there and the correlation for selected candidates would
be computed at 0:3. This illustrates a principle of Karl Pearson that
examination statisticians have apparently overlooked. Selection modifies
means, standard deviations and correlation coefficients. In an observed
case a correlation of 0-67 on feebly selected material was by more and more
stringent selection reduced through values of 0:07 and —o-16 to —o-93.
The farther we get away from the measure of the selection the less will be
the effect on the correlation of correlated measures—the other test will
always tend to be the better. A correlation coefficient between two measures
should not be given in vacuo ; the material studied should be revealed and
special study made of possible selection effects.

Other statistical and allied difficulties are referred to and some suggestions
submitted.

Prof. J. Drever—The comparative reliability of examinations and
tests respectively (11.0).

Examination marks are unreliable from two points of view. In the first
place one and the same examination paper, it is well known, may be
differently assessed by different examiners, and even by the same examiner
at different times. This defect might to some extent be removed by objec-
tive methods of assessment. In the second place school examinations at
best have been shown to have an extremely low correlation with University
success even in the same subject. The causes of the unreliability in this
case would appear to be very complex. The first type of unreliability ought
not to be present to any considerable extent in the case of intelligence tests,
and the second is certainly not present in the same degree.

568 SECTIONAL TRANSACTIONS.—L.

Miss A. B. DaLe.—Tests and entrance examinations as predictive of
academic success among university women students (11.15).

During the past seven years a comparison has been made between the
intelligence test scores of students of Newnham College, Cambridge, and
their performances in academic examinations, the total number of students
dealt with being about 530. Students were tested during their first term
at Cambridge and again later in their University career. Records were kept
of their performances in entrance or scholarship examinations and in their
tripos or other academic examinations taken at the end of each year of their
course.

The results appear to show that success in advanced and highly specialised
academic work depends to a considerable extent on factors other than that
measured by intelligence tests, although the influence of this general factor
varies in different academic subjects.

Performance in entrance or scholarship examination differs markedly
' from that in the final examination taken 3} years later in about 14 per cent.
of the cases considered. A special study of these cases shows to what extent
a truer forecast of success would have been obtained by combining an
intelligence test with the academic papers of the entrance examination.

Mr. E. Farmer.— The predictive value of examinations and psychological
tests in skilled occupations (11.30).

DISCUSSION (11.45).

AFTERNOON.
Symposium on The cultural value of science in adult education :—

Sir RrcHarD Grecory, Bart., F.R.S. (5.30).

When the Workers’ Educational Association was founded thirty years
ago, its deliberate intention was to arouse among the workers greater interest
in higher education, particularly in relation to subjects of a non-utilitarian
character. It represented the view that, in the training of citizens, oppor-
tunities for general culture were needed as well as facilities for technical
education. ‘There was to be a broad highway to realms of intellectual
delight in literature, history and art, as well as in natural science, and the
education was to touch the heart and imagination independently of its
industrial or commercial contacts.

The cultural value of science in adult education is thus no new subject,
but it cannot be said that any clear principles of promoting this value have
yet emerged from any educational organisation.

When science is taught, not as an aid to a vocation, but as part of the
training of a modern citizen, it may be said to have a cultural value. Atten-
tion should, therefore, be given to the influence of scientific discovery and
its applications upon social and economic life and thought. Science rightly
conceived is modern humanism in the fullest sense. Even if the humanities
are understood to mean letters, history and art, there should be no conflict
between these studies and natural knowledge. It should be understood
that the object of teaching science to general students in adult classes is not
to produce specialists but to create in the rank and file appreciation for what
is good and needful for intelligent citizenship.

Prof. W. J. PucH.—Geography and geology (5.45).

SECTIONAL TRANSACTIONS.—L. 569

Prof. W. B. BRIERLEY.—Natural Science (zoology, botany) (6.0).

Consideration of this question depends on one’s idea of the meaning of
the word ‘ culture.’ To the author it means an integration of knowledge
and experience which helps an individual to lead a reasonably full and free
intellectual and emotional life and fits him to play a contributing part in the
social community ; in short, an orientation towards life which makes for
personal happiness and social usefulness. Cultural values are traditionally
ascribed to particular subjects but, in fact, cultural values are not inherent
in any subject, but derive from the method of treatment and the personal
- relationship to a subject. There are few, if any, subjects whose study is not
of potential cultural value, but the traditional methods of approach often
lead only to the accumulation of information unrelated to life as a whole.
To possess cultural value a subject must be regarded not as an isolated
department of pure knowledge but as an integral part of human life and
social welfare, and its pedagogy must have this orientation. The study of
biology (zoology and botany) by reason of its methodology of observation,
experiment, deduction and generalisation, together with its techniques of
recording, can be made to yield ample scope for the development of an
individual’s sensory, emotional, and intellectual life. By reason of its sub-
ject material, which is the basis of all human development and social structure,
it can be made to induce appreciation of fundamental principles of life and
civilisation.

Dr. ALLAN FERGUSON.—Chemistry and physical science (6.15).

Prof. J. L. Myres, F.B.A.—The general educational problem (6.30).

Education, as a preparation for life, approaches its task in different ways
and by appropriate methods, according to the life to be lived, and the pre-
supposed experience of the pupil. In adult education, the student’s experi-
ence is wide but ill-co-ordinated ; his faculties though mature, are ill-trained ;
he is less receptive of systematic ins*ruction, more appreciative of theoretical
assistance applied to concrete episodic problems. His approach to all
enquiry,—‘ scientific’ in the popular sense, or other,—is rather that of
explorer and pioneer, than of pupil or disciple. Collaborative apprentice-
ship, however, has been his normal introduction to technical skill; and
usually he understands what team-work means, even when he is not by
disposition suited to it. ‘These considerations affect the teaching, no less
than the learning, of adult students. Historical and economic studies have
had their vogue mainly because they have been presented to adult classes
as remedies for social inconveniences in daily experience. Comparative
indifference to the natural sciences results less from intrinsic abstruseness,
than from the failure of academic exponents, laboratory-trained themselves,
to appreciate the necessity of beginning with what the student practically
knows and can do, with the simple means at his disposal and chiefly with his
own trained eye and skilled hand.

Dr. VAUGHAN CorNIsH.—The esthetic aspect (6.45).

Sir Josran Stamp, G.B.E.— Summation.

Tuesday, September 12.

PRESIDENTIAL ApprEss by Mr. J. L. HoLtanp on The development of the
national system of education (10.0). (See p. 219.)

570 SECTIONAL TRANSACTIONS .—L.

RESEARCH WORK BY TEACHERS AND SCHOOLS :—
Dr. A. H. SmitH.—Field-names (11.10).

Dr. L. DupLtey Stamp.—Some types of local survey (11.30).

This paper describes an attempt to apply a simplified form of the regional
survey method on a nation-wide basis. Starting with the assumption that
a fundamental aim of juvenile education is to provide an adequate prepara-
tion for adult life, an intensive study of the home region and of the local
environment is used as a starting point for a training in citizenship by
awakening an appreciation of the significance and relative importance of the
facts of local geography, history, and economics. Several bodies exist to
encourage regional survey as an educational method and amongst them was
the Regional Survey Committee of the Geographical Association. The
author, on his resignation from the Indian Educational Service in 1926,
became Secretary of this Committee and it was soon apparent that only the
larger or better-equipped schools could, except with specially enthusiastic
leadership, organise a complete local survey. A search was made for a
simplified form which could be undertaken by the smallest rural schools—
even single-teacher schools—but which would carry the advantage of the
method and would, at the same time, yield results of permanent value. By
a magnificent pioneer effort, Mr. J. L. Holland, Director of Education for
Northamptonshire, assisted by Dr. E. E. Field, showed how the rural schools
of a county could effectively undertake a survey of the uses of land, each
school studying its own parish. With this example before them, the Land
Utilisation Survey of Britain was formed in October 1930, with the help
of a grant from the Rockefeller Fund of the London School of Economics.
The Survey was careful to remain an independent body and all work has
been carried out on a voluntary basis, though the approval of the Board of
Education, Scottish Education Department, County Councils Association,
and many other bodies was first obtained. The Survey was organised ona
county basis, England, mainly in 1931 ; Wales and Scotland mainly in 1932. In
seventy of the ninety-three administrative counties the Director of Education
has been the county organiser. It is estimated that 10,000 schools and
200,000 children have taken part in the study of the 22,000 sheets of the 6-in.
ordnance map which are involved. The methods followed are described ;
independent opinions and estimates of the value of the work are given. A
number of the maps on the scale of 1 inch to 1 mile, now being issued by
the Ordnance Survey as a result of the Survey, are mentioned. The results
of the Land Utilisation Survey further illustrate in a remarkable way the
controlling influence on the progress of educational experiments exercised
by the County Education Committees.

Mr. A. S. McWiti1am.—A research in agriculture at Lady Manners
School, Bakewell (11.50).

This paper is an account of some of the field experiments carried out by
the boys and girls in connection with the biology course. The experiments
are arranged in collaboration with the Rothamsted Experimental Station.

The experiments on meadow hay consist of, first, an eight plot manurial
test which gives significant results for the complete manure, all the other
treatments containing nitrogen and for potash in the presence of nitrogen.
The second one demonstrates the importance of the degree of solubility of
phosphatic fertilisers ; and the third is a two years’ trial to compare the
action and manurial residues of dung and complete artificials.

SECTIONAL TRANSACTIONS.—L, M. 571

The experiments on arable crops are (1) the comparison of nitrogenous
fertilisers on potatoes in which nitrogen in all the forms tried gave significant
results, but the differences between the various forms of nitrogen were not
significant, and (2) a rotation experiment on the eight plot system which
brings out some overall effects. The size of the plot varies from 1/120 to
1/200 acre each; the treatments are replicated and randomised. ‘The
standard errors compare favourably with those obtained at research centres
where larger plots are used.

Miss J. K. Jones.—A village survey (12.10).

A short account is given of the work done in two small Oxfordshire
village schools over a period of years under the guidance of Miss C. V.
Butler, M.A., who, with Miss C. A. Simpson, wrote the Board of Education
Pamphlet No. 61 on ‘ Village Survey Making—an Oxfordshire Experiment.’

One of the schools, Lower Heyford, is in a ‘ compact’ village, in the
centre of the county, on the Cherwell, typically a valley village ; and this
survey is compared with that of Idbury and Fifield, on the extreme west of
the county, 600 ft. above sea-level, on one of the Cotswold slopes.

The points of comparison will be :

(1) Geological formation, involving types of water supply, buildings,
boundaries, crops, and fields with their names. b

(2) Economic life of the inhabitants; local industries, existing and
extinct ; markets.

(3) Illustrations of social history Enclosures and commons, tithe
barns, pounds, turnpikes, manorial rights.

(4) Local customs ; Folk lore, weather lore, children’s games.

(5) Nature study ; Trees.

(6) Method. (a) Utilisation of children and the effect on ordinary

school work.
(6) Utilisation of parents—neighbours and old scholars.

(7) Limitations and value. (a) As ‘ finding out’ with some real con-

tribution to knowledge ; (b) as an educational method.

DISCUSSION (12.30).

SECTION M.—AGRICULTURE.

Thursday, September 7.

PRESIDENTIAL ADDRESS by Dr, A. LauDER on Chemistry and Agriculture
(10.0). (See p. 243.)

Discussion on Some sociological aspects of agriculture :—

Mr. R. R. ENFIELD.—What is our objective in agriculture: high
production, high employment or high standard of living ? (11.0).

The objective of a higher standard of living. Its relation to general
economic progress. Economic factors affecting the problem of increasing
agricultural production and employment. The trend towards economic
nationalism. The country’s balance of payments. Sociological factors.
How can these be measured? Their relation to economic factors. Ex-
amples of other countries. Technical questions involved. The effect of

572 SECTIONAL TRANSACTIONS.—M.

modern technique on employment and production. Questions of procedure.
Conclusion.

Prof. A. W. AsHspy.—Technical and economic efficiency and some
social results (11.30).

DISCUSSION (12.0).

AFTERNOON.

Excursion to the Robert Bakewell Memorial and the Midland
Agricultural College.

Friday, September 8.

Discussion on Land drainage :—
(1) Lancer WaTERWAYS.

Mr. A. T. A. Dosson, C.V.O., C.B.E.—The law of land drainage ;
arterial drainage (10. 0).

A brief account is given of the trend and object of land drainage legislation
prior to 1930, when a new and comprehensive Act was passed repealing all
previous enactments, and providing for the constitution of a new class of
land drainage authority.

The more important of the powers conferred by this latter Act are shortly
described, and some account is given of the progress that has already been
made and i is likely to be made in the future by the new authorities which
have been set up under that Act, in dealing with the task before them, and
in organising the drainage system of the districts for which they are
responsible.

The nature of the operations which urgently require to be carried out on
the main rivers of England and Wales is referred to, and an attempt is made
to show that powers now exist for the first time under the Land Drainage
Act, 1930, whereby every watercourse from the farm ditch to the great
arterial or estuarial river, can be maintained in a reasonably effective manner
with the financial resources provided under the Act.

Discussion. (Mr. W. Hare.)
(2) Fietp Drains.

Mr. H. H. NICHOLSON (10.30) -—
(a) A general survey of the position on farms.

The area of land requiring field drainage varies enormously from one
part of the country to another, depending on such factors as physiography,
geological formation, the main drainage channels, the type and maintenance
of previous drainage operations. ‘Tile draining and mole draining are still
practised, the former to a diminished extent. Ditching and the cleaning of
watercourses are still carried out with effect, but these important links between
the field drains and the main water-ways are being increasingly neglected.

(6) Drainage investigations at Cambridge.

The field moisture profile of the soil and its variations throughout the
year have been studied particularly on heavy land, in conjunction with the
incidence of rain and the performance of drain outfalls. ‘The mode of

SECTIONAL TRANSACTIONS.—M. 573

operation of mole drains, their shape and the changes which take place with
age, have been examined. Observations have been made on the permeability
of the soil in the field and its seasonal variations.

Dr. H. Janert.—Drainage investigations on the Continent (11.10).

Many soils in Germany require amelioration to make farming profitable
and to intensify cropping to the level necessary to provide home-grown
foodstuffs for the whole population. ‘To this end the German states have
always paid careful attention to land amelioration work, and a special
organisation was set up to lead and to supervise amelioration generally and
drainage in particular.

Land amelioration boards exist in all the German states and possess a
large staff of trained amelioration experts, called Kulturtechniker. The
duties of these experts are very diversified and include irrigation, cultiva-
tion of moor and marsh land, and particularly drainage.

It is now fully recognised that efficient drainage can only be expected if
the water and soil conditions are carefully investigated and taken into
account. The soil conditions are of particular importance in determining
the appropriate drain depth and separation. Before modern methods of
soil investigation were introduced into drainage practice, the soil conditions
were estimated simply by practical experience. This was found to be
most unreliable, and it has been shown by field and laboratory researches
that close relations exist between the results of certain laboratory tests and
the response of a soil to drainage.

These relations apply only to tile drainage, which, however, becomes
uneconomic in the case of the extremely heavy soils. In some of these
mole draining can be successfully employed, but in others the moles do not
hold, and some internal support must be provided for the mole channels.
A new method for this purpose is proposed and described.

Mr. J. H. BiackaBy.—Drainage machinery (with a note on the
measurement of outflow) (11.35).

Mole draining requires considerable power, a variation from 7 to 23
drawbar horse power being shown in the records of tractor working. The
methods of providing this power are a team of horses, a portable winch
operated by hand, horse or low-powered engine, steam cable engines, direct
tractor haulage and tractor cable haulage. Each has advantages and limita-
tions. Mole ploughs in this country are essentially of simple form ; there
are points in construction which make for good work. Continental machines
have been elaborated for various purposes. Mole draining can be done
very cheaply. Mole drains have lasted fifty years, shallow tractor-drawn
mole drains have worked well for five or six years.

Tile drainage is comparatively expensive by reason of the hand labour
involved. Various forms of excavator have been developed to minimise
this and speed up the work. Ditch cleaning has also been mechanised.
For arterial watercourses, excavators of varying size of the drag-line or grab
type are used.

A meter for measuring drainage outflow has been designed and tried out
in the field by the Institute for Research in Agricultural Engineering.
This meter is automatic and self-recording and can deal with rates of flow
from zero up to 4 gallons per minute.

DISCUSSION (12.0).

574 SECTIONAL TRANSACTIONS.—M.

Saturday, September 9.

Excursion to open fields, Laxton. Paper during excursion :—

Mr. C. S. ORwin.—The open field parish of Laxton.

Laxton has an unique interest for the agriculturist and the economic
historian in that it is the last survivor of the open field parishes, and it
remains the only place where the manorial system can be studied as a living
organism.

The population is still concentrated in the village, with the farm buildings
and crofts behind each dwelling-house. ‘The demesne lands, all of them
ancient inclosures, extend along one side of the parish. The common,
with its cow-gates attached to certain of the holdings, is still in being. ‘The
plough land of the parish is still divided into three great fields, over which
are scattered the holdings of the tenants, and they are farmed strictly on
the old three-course rotation—winter corn, spring corn, fallow. Stubbles
and the fallow field are still grazed in common by the livestock of the tenants.
The Court Leet is still summoned by the Bailiff, and the jury is sworn by
the Steward of the Manor. A Pinder is appointed to control the common
grazing, and to impound straying or unauthorised stock in the parish pinfold.
The jury inspects the state of cultivation and fines delinquents.

Laxton has belonged to the family of Earl Manvers for the last three
hundred years. It is an historical monument of the first importance, for it
demonstrates the manorial system in a way which no written description can.

Monday, September 11.

Discussion on Grazing problems :—

Alderman P. F. Ast1Lt.—Grazing in the Midlands (10.0).

The grazing of the rich pastures of the Midland area consists of feeding
animals for a comparatively short time till they are fit to butcher. The
feeder has to consider what type is most suitable for his pastures, and at
what weight and age the animal commands the best price. He must
estimate the number his farm will carry, and have a proportion of his stock
ready to market as soon as his pastures have reached their maximum growth.

The greatest factor in producing these renowned pastures has been the
management.

Their richness or strength has unfitted them for feeding the younger
animal the public now demands and presents an unsolved difficulty which
merits most careful inquiry. The consumer’s demand for a small and
tender joint is much easier to meet in the production of mutton and lamb
than in beef.

The rearing of the right type of store is increasingly important and there
are good reasons to expect an early improvement.

The increase of the grass acreage has caused an unequal production of
both beef and mutton, with great fluctuations in value which tend, in the
period of short supply, to limit the demand for home-produced meat.

Mr. Martin G. Jones.—The art of grazing and its effect on the
sward (10.30).

Pasture is a perennial crop, and the art of grazing resolves itself into two

aspects, viz. the maximum production from the sward in any particular

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season and the maximum benefit to that sward for production in future
years.

Both aspects are closely bound up with the botanical nature of the sward,
and therefore any treatment that favours the best plants will improve the
sward for future years, whilst any treatment that favours undesirable plants
will cause a deterioration.

Pastures generally contain a number of different species and strains of
plants which are in continual competition with one another, and the experi-
ments to be described have shown how the grazier by adjusting the rate of
stocking at various times of the year does unconsciously determine which of
the botanical constituents in his sward shall predominate. Starting with
an uniform area of pasture it has been possible to convert one portion into
a clover-dominant sward, whilst a corresponding portion has been converted
into a grass-dominant sward. The grassy sward has been further divided,
causing ryegrass to become dominant over cocksfoot in one section, whilst
the adjoining section has cocksfoot as the dominant plant.

Mr. W. Davies.—The biotic factor : lessons from Australian and
New Zealand grasslands (11.0).

Grassland is an unstable vegetation complex, often a direct biotic complex
which depends upon the action of grazing animals for its maintenance as
grassland. ‘The problems of pastures established by man in place of forest
are compared with those of semi-arid (steppe and savannah) regions. ‘The
influence upon the pasture complex of contrasting management and different
types of stock are examined, as for example, the control of grazing by
domestic live stock and uncontrolled grazing by wild animals, as rabbits,
kangaroo and other organisms.

The principles of pasture maintenance and pasture improvement are
briefly considered from the several view points of (1) species and strains ;
(2) soil fertility ; and (3) management.

(1) Desirable attributes in herbage plants ; the value of knowing source

of origin in purchasing pasture seeds ; seed certification in relation
‘to herbage plants—tendencies in New Zealand, Australia and
Britain.

(2) The improvement of soil fertility. The value of pasture legumes as
soil improvers and as payable pre-crops: lessons based on
Australian experience. Pasture plants classified according to the
demands made by them upon soil fertility.

(3) Grazing technique in relationship to botanical composition. The
influence upon the sward of differential grazing: (a) heavy con-
tinuous; (b) heavy intermittent; (c) overstocking and under-
stocking ; (d) haphazard and controlled grazing. The reactions of
individual species and causes of depletion in semi-arid grazings.

Mr. A. BripGes.—Some economic aspects of grassland (11.30).

Since the war the problem of grassland has received considerably more
attention than formerly. . In rather less than twelve years a vast amount of
scientific knowledge has been gained in relation to the management of grass
and placed at the disposal of farmers if they have the wish and the need to
use it. The reason which has prompted this attack on the grassland
question is the large increase in the area under grass since the war. A
peculiar feature of the post-war situation is the large increase in the area
of rough grazings. The increase in the area of grass is the result of two

576 SECTIONAL TRANSACTIONS.—M.

tendencies. First, it is the complement to the increase in livestock farming ;
and, secondly, the result of a desire to curtail expenditure on unprofitable
arable land during the depression. ‘The improvement of this latter class of
land may not be desirable at present.

The improvement of old grassland in poor condition can be financially
successful, as Mr. Bligh’s experiences show, yet it makes little headway on
a national scale. ‘There are certain factors limiting activity in improving
poor grassland : (1) the alternative of an increased output from better class
grassland ; (2) the laying down of arable land to grass; (3) the special
function of poor grassland in systems of farming ; (4) the speculative nature
of the investment.

In the subject of the economics of grass and hay versus purchased foods
as a Management question it appears that grass and hay are much cheaper
to produce than most purchased foods. Yet purchased foods play a special
part on grassland farms. For their reliability and convenience, as compared
with an uncertain and variable supply of food from grass, farmers are
prepared to pay a higher price. Scientists must remove the uncertainties
of grass as a food supply.

DISCUSSION (12.0).
AFTERNOON.

Visit to the Market Harborough grazing area.

Tuesday, September 12.

Discussion on Milk production and distribution in relation to nutrition
and disease :—

Prof. T. J. Macxre.—The milk supplies of the country in relation to
the public health (10.0).

Introductory : milk in human diet ; milk as a vehicle of infection—the
hygienic problem ; consumption of milk in this country ; need for a higher
standard of purity.

Factors that have influenced the condition of the general milk supplies—
the distribution of milk to the urban communities—transportation and
retailing of milk.

Bacterial contamination : sources—milk as a bacterial growth-medium—
hygienic and economic aspects—methods of dairying and distribution.

Milk-borne infection: bovine tuberculosis and human infection by the
bovine type of tubercle bacillus—prevalence of bovine disease and of tubercle
bacilli in market milk—human mortality and morbidity due to bovine-type
infection ; other infections and their sources ; bovine contagious abortion
and undulant fever (‘ abortus-fever ’) of the human subject—prevalence of
Bacillus abortus in market milk.

The control of milk-borne tuberculosis ; ‘ open ’ tuberculosis of cattle—
tuberculosis detected by tuberculin reaction—existing legislation in control
of disease—eradication of the disease from dairy herds, methods, achieve-
ments, and future progress—the position of the individual farmer ; designated
milks.

Disinfection of the ordinary market milk—pasteurisation : question of
its efficacy—methods—need for control—effect on nutritive qualities—
question of compulsory pasteurisation.

Immediate measures to ensure safe milk supplies.

SECTIONAL TRANSACTIONS.—M. 577

Mr. W. Goppen and Dr. J. BLackwoop.—The nutritional aspect
(10.30).

Dr. N. C. Wricut.—Some implications of compulsory pasteurisation
(10.50).

Apart from the relation of pasteurisation to the reduction of milk-borne
disease and to the nutritive value of milk, certain other factors must be
taken into account in deciding whether a policy of compulsory pasteurisa-
tion for city milk supplies is justifiable. Such factors include the effect of
compulsory pasteurisation on the producer-retailer and the small distributor ;
the influence of pasteurisation on the production of clean milk and on the
eradication of bovine disease ; its effect on wholesale and retail milk prices ;
and, finally, the expediency of applying an element of positive compulsion
to the artificial treatment of such a widely consumed foodstuff as milk.
These factors are discussed in the present communication.

Mr. Ben Davies.—The problem from the point of view of the dairy
industry (11.10).

Prof. G. S. Witson.—The necessity for a safe milk supply (11.30).

Milk is a valuable food, and so far as its nutritive properties are concerned
it is not an expensive food. Its importance in infant feeding, its power to
stimulate the growth of under-nourished school children, and its value in
the treatment of disease, amply justify for it a very special place in the
human dietary. Unfortunately, however, owing to the fact that it is par-
ticularly liable to become infected, and that it furnishes an admirable
medium for the multiplication of many types of pathogenic bacteria, its
use in the raw state is bound to be accompanied by a certain amount of
danger to the human population. While the production of clean milk
from healthy animals may diminish this risk to some extent, it can never
entirely eliminate it. To do this, the only satisfactory measure at the
moment is some form of heat treatment that will destroy all pathogenic
aka while interfering to a minimal degree with the nutritive value of
the milk.

Discussion (11.50). (Dr. H. D. Kay, Miss OLGA NETHERSOLE.)

EVENING DISCOURSES.

FIRST EVENING DISCOURSE
FRIDAY, SEPTEMBER 8, 1933.

MUST SCIENCE RUIN ECONOMIG
PROGRESS ??

BY
SIR JOSIAH STAMP, G.B.E.

Economic progress is the orderly assimilation of innovation into the general .

standard of life. It usually connotes a widespread sharing of new benefits,
but is by no means inconsistent with some degree of uneven distribution
of wealth or income, for in a non-socialistic community some disparity
generally raises the standard of life of the mass to a point higher than it
would be under a forced equality of distribution of wealth, the envies
caused by disparity notwithstanding. The purely material standard in
Great Britain was raised fourfold during the nineteenth century, and
probably rather more in the United States. If we take into account also
length of life and proportion of leisure, the increase is much greater. ‘The
improvement arises only to a very small extent in changes in the average
innate capacity of man, not co-operant with, or parasitic upon, his environ-
ment. It is almost all due to innovation in social activity (including social
education and the reactions of economic betterment upon physical and mental
ability). ‘The greater part of the innovation is scientific innovation—in
physics, engineering and public health ; but a not inconsiderable part falls
outside these categories, and belongs to the non-physical section—better
ideas about money, more social confidence in banking and credit, improved
political and social security and legal frameworks for the better production
and diffusion of wealth. The elaboration of these factors depends partly
on intellectual prevision and invention, but mainly upon average moral
standards and calibre of character, since many political schemes, including
international co-operation, are impracticable only because of failings in the
present standards of human nature.

It is being commonly stated that scientific changes are coming so thick
and fast, or are so radical in their nature and implications, that the other
factors of social life, the intangibles of credit, the improvements in political
and international organisations and ideas, are unequal to the task of ab-
sorbing and accommodating them, or else they present new problems
which have no counterpart. If changes in social forms and human nature
or behaviour cannot possibly be made rapidly enough for the task, then in

1 For further reports, see Lecture Recorder, 3, 3, Oct. 1933; Nature, 182, 3333,
Pp- 429, Sept. 16, 1933.

MUST SCIENCE RUIN ECONOMIC PROGRESS? 579

that sense science may ‘ ruin’ economic progress, and the world might be
better served in the end if scientific innovation were retarded to the maxi-
mum rate of social and economic change. Civilisation went through a
long period when the limiting factor to progress was the scientific, but is now
passing through a stage when the limiting factors are non-scientific. The
lack of identity in the tempo of change creates new problems, tending to
offset scientific advantages, of three types. First, for example, the utilisa-
tion for essential or competitive purposes of rare minerals, the need for which
becomes general, but the distribution of which is particular and accidental,
sets up great political strains, and we have invented no means of adjusting
the international effects of accidental monopoly of essential elements.
Second, the problem of scope, where the scale of production upon which,
for example, a chemical innovation can be made to give its real economic
advantages, is a scale inconsistent with the size of markets freely open in
a nationalistic world. Here strains are set up in the international machine,
and the balance of trade, which may gravely jeopardise economic progress,
and dry up the juices of commerce. Third, for example, where the innova-
tion is absorbed most easily for offensive purposes in a military or naval
sense, it may create rivalries and changes of balance of power inimical to
economic security, and compel new economic sacrifices outweighing the
direct economic advantages of peaceful uses. It is open to question whether
the innovation of aircraft has yet become, on net balance, economic
progress.

Inasmuch as all economic production creates real vested interest in a
location or a skill devoted to it, and every scientific innovation alters the
centre of gravity of collective demand, every such scientific change disturbs
an economic equation. That equation for human life may often be richer
ultimately, but the pain or waste of disturbance has to be debited to the
gain, before the net balance is progress. For the time being, the balance
may be net loss, the price paid for to-morrow. If to-morrow is continually
postponed, because it, in its turn, is redisturbed, and the economic to-
morrow never comes, it is literally jam yesterday, jam to-morrow, but never
jam to-day. Wastes of absorption will be at a minimum in certain con-
ditions, which are related to the wearing life of existing assets and places,
and to the rate of flow of new skill into new directions. The orderly ab-
sorption of innovation into economic progress, apart from improvements
in the non-economic factors of such progress, depends upon two kinds of
balance. The first is the balance between two classes of scientific discovery,
that which accelerates or makes easier the production of existing economic
goods, and that which creates new kinds of economic satisfactions—the
derivative and the direct. Let us suppose that in static society a million
people are employed making boots, and the gramophone has not been
invented. Then let a labour-saving device be invented, such that the same
quantity of boots can be made by half the workers, and boots are half the
price. Assuming that the demand for boots is quite inelastic, and no more
are wanted, there is potential unemployment for half a million people, and
the whole population has now reserve unspent purchasing power, saved on
cheaper boots. The gramophone is introduced, employing the potentially
unemployed, and absorbing the reserve or released purchasing power. ‘The
progress of the past hundred years has been essentially of this order, and
innovation has enabled purchasing power to be released for new spending—
first, upon far more of the same article at the reduced price ; second, upon
more of other existing goods; and, third, upon entirely new kinds of satis-
faction, bicycles or radio sets. In this connection it must be remembered
that an old article may be so transformed in degree as to be equivalent to

580 EVENING DISCOURSES

a change in kind—the silk stocking and feminine footwear are cases in point.
Now even if these two classes of innovation, direct and derivative, are in
balance, the process of absorbing them will give rise to economic growing
pains and temporary dislocations of capital and employment, but the gains
will rapidly outweigh the disadvantages. But when they are not in balance
the process is more painful, and the debit to be set against progress very much
greater. The introduction of machinery has been for three hundred years
accompanied by the same hostile arguments, for the immediate effects in
unemployment are much more obvious and human than the countervailing
employment given by the released purchasing power, which may occur in
some other place or country. Illustrations may be found all the way from
Queen Elizabeth’s sentiments on stocking-knitting machinery to the Luddite
riots, and the eight looms per weaver of to-day. But in the literature of the
whole series, nothing can outdo, for detailed economic jeremiad and precise
calculation of woe, a contemporary examination of the effect of the intro-
duction of the stage-coach in the middle of the seventeenth century upon the
post-horse industry and all that depended upon it. (In Grand Concern of
England, 1673.)

The argument so far, no doubt, begs the question of the meaning of pro-
gress, and assumes that silk stockings and fine shoes represent ‘ higher ”
standard of life than black homespun woollens and rough boots—a doctrine
that is not acceptable to Mr. De Valera, for example; but as we are not
entering the field of morals or ethical aims, we are obliged to assume that
those objects which are actually the subject of average human desire must
be given their economic significance accordingly, and not attempt to solve
the larger problem simultaneously. In this sense such a mechanical
invention as the totalisator must take its place in ‘ progress ’ at this stage. ~

The problem of balance, in the direct and the derivative, is not however
so simple in practice, for the sum total of the effect of derivative innovations
(creating technological unemployment) ought to be balanced by the sum
total of direct innovations or increased demand for other products (new
and expanded employment). But many direct innovations are not additive,
they are substitutional, and destroy the need for old commodities. If combs
are made from celluloid, and dishes from papier maché or pyrex, they will
certainly not create a wholly additional demand or employment—there
will be a displacement of the old types in metal or bone combs or china
dishes. This substitution goes into rival classes of utility also, and a radio
set may be a real substitute for a billiard table, and oil may be the enemy
of hops, if cheap bus-riding supplants long sittings in public-houses. These
substitutions may be gradual enough to be absorbed as a normal feature of
progress, but if they are very rapid and coincide with certain other economic
disturbances they may be very distressing. By ‘normal’ I mean such as
can be coped with by the direction of new labour entering industry or new
capital spent on renewals, leaving the contractions to take place by natural
age attrition without unemployment, or by premature obsolescence—for the
moment this is the optimum point of change.

The lack of balance between derivative and direct innovation may be
due, of course, to a terrific drive and rapidity in scientific recovery of the
industrial type, but it is only fair to say that the excess of one may be due
to causes on the economic side. If, for purely monetary reasons, the gold
standard, etc., the purchasing power of money is continually increasing
through falling prices, and, with the current inability to change the money
totals of wages and other costs, real wages are rising, it becomes increasingly
possible to substitute innovations of machinery for hand labour, or complex
for simple. A change that was not worth making on a balance of old wage

MUST SCIENCE RUIN ECONOMIC PROGRESS? 581

costs against new capital costs in 1923, became well worth making by 1932,
and indeed imperative, if any profits were to be preserved. Hence the
almost artificial pressure which a rigid monetary system may bring to
bear towards the over-rapid application of new methods and creation of
unemployment.

The second kind of balance which is vital to economic progress and which
may be ruined by over-rapid innovation is that between obsolescence and
depreciation. Nearly all scientific advance for economic progress has to
be embodied in capital forms to be effective, more and more elaborate,
large and costly. ‘The productivity of such apparatus and plant per man
involved becomes greater, and, even allowing for the men employed in
making the machinery or process, the total satisfaction is continually pro-
duced with less and less human effort. Now it used to be said of British
machinery that it was made good enough to last for ever and long after it
became old-fashioned, whereas American machines were made to be worn
out much earlier, and were thus cheaper, but could be immediately replaced
by capital assets containing the latest devices. If the period of physical life
and fashionable life can be made to correspond, there is greatest economy
and security of capital. But if the expensive embodiment of the latest
science can be outmoded and superseded long before it is worn out, there is
waste of capital, loss of interest, and resultant insecurity of business and in-
vestment. ‘The factor of physical safety alone means that each embodiment
must be really durable, even if roughly finished, and, therefore, it is impos-
sible wholly to reduce physical life to probable ‘ obsolescent ’ life. In this
way an over-rapid series of innovations may mean the scrapping or unprofit-
ability of much excellent capital for very small marginal gains. A responsible
socialist community would see each time that the gain was worth while,
but competitive individuals have no collective responsibility. Suppose the
giant Cunarder attracts a profitable contingent for two years only, when
a lucky invention in a new and rival vessel attracts all her passengers at
a slightly lower fare. Here is progress in one typical sense, but the small
net advantage to be secured by individuals as free-lance consumers may be
dearly purchased by large dislocations or loss of capital, reacting even upon
those same individuals as producers.

Now, if the innovation were very striking, and were reflected in working
costs, the margin of difference between the old working costs and new
working costs may be large enough to pay interest on the new capital
employed, and also to amortise the cost of the unrealised life of the asset
displaced. A locomotive may have many years of useful life left, but a
new type may provide a margin by lower working costs not only sufficient
to make one adopt it on normal renewal, but also to pay for the premature
scrapping of the old type. ‘The majority of modern innovation is, however,
of the type which does not pay the costs of obsolescence and proceed by
orderly and natural physical renewal or substitution. A similar type of
argument applies to the capital expenditure generally on a district, which
can be amortised over the economic activity of that area, such as a colliery
area, but which is wasted if a dislocation occurs by the adoption of some
innovation stimulating rival activity in another place. Similar but more
poignant considerations apply to obsolescence in human skill and training,
more rapid than the ordinary attrition through age retirement can accom-
modate. Physical capital forms, human vocational training, and centring
in geographical areas, are all essential features in the absorption of scientific
innovation into economic progress. Each has its natural time span, and
a narrower span of scientific change is bound to set up large economic debits
to be set against the economic credits of the change. A man running a

582 EVENING DISCOURSES

race might be stopped to be given a new magic cordial which, after allowing
for the two minutes stoppage, would enable him to finish a minute earlier.
But if he is stopped at frequent intervals for other magic cordials, each
advantageous by itself, the total period of stoppages would at some point
exceed the possible gains of speed during the short undisturbed running
periods, and he would finish later at the post, instead of earlier. This is
a parallel to the current effects of too rapid disturbance on progress.

Under an individualistic form of society it is difficult to alter the social
technique of change, and to make its credits really pay for the debits, and
make all the people who gain by the profits on new capital pay also for the
losses on prematurely displaced capital, or the gainers by cheapness and
variety pay the human costs of unemployment and no-longer-wanted skill.
The basic economic reason for social unemployment relief is not the humani-
tarian argument of social obligation against distress, or the argument against
revolution, but the plain argument that the social gainers by innovation
should bear the losses of innovation. At the same time much can be done
to shorten the hitherto natural time span and make society ready to absorb
the quickened tempo of science. No prices ought to be charged except
on the basis of costs fully loaded with short-period obsolescence—this
would prevent over-rapid substitution, economic only to a narrow range of
people. We have no adequate technique of change: we treat life as mainly
static, with occasional and exceptional periods of change, whereas we must
learn to look upon it as continuously changing, with occasional and abnormal
periods of rest, and we have to secure all the changes of social outlook implied
by that reversal of view.

The next field in which scientific advance alters the economic problem
faster than we can solve it, is in the duration of human life. We have to
provide social dividend adequate to maintain a much larger proportion
beyond the age to contribute to it. Combined with the altered birth-rate,
a profound change is taking place in age densities, and the turnover from
an increasing to a stationary and then a declining population, in sight in this
country, Belgium, Germany and even the United States, is bound to affect
the tempo of economic life. A larger and more immediate problem of
adjustment is, of course, the absorption of the results of science not in
increased masses of new kinds of commodities made by the released labour
of labour-saving devices on old kinds, but in generalised leisure. The
transition from a state of affairs in which we have an uneconomically high
commodity wage paid to a part of the population, and the rest with a
mere pittance and enforced idleness, to a state where a part of the reward is
taken all round in larger leisure, and where economic satisfaction from leisure
is deliberately equated to that from commodities in the standard of life,
may need a surgical operation, or a catalyst, such as the United States
experiment can show.

In the past, the absorption of innovation has been achieved, according
to contemporary explanation, by four agencies :

(x) Great elasticity of demand for the old commodities at reduced prices—
food and staple household necessities.

(2) Rapid introduction of new things.

(3) The rise in population created by the increase in produce.

(4) Overseas outlets in more backward industrial countries.

In the first the elasticity completely alters as the standard rises, and generally
there is not now the scope for lower price in food or clothing increasing the
demand pro tanto; for the third, a rising standard no longer stimulates
population but tends the opposite way ; for the fourth, the external outlets

MUST SCIENCE RUIN ECONOMIC PROGRESS ? 583

are now largely self-producers. As regards the rapid introduction of new
things—these mostly now demand increased leisure for their proper ab-
sorption and use, so that the two are co-related and mutually dependent.

It can be conceived that a socialistic organisation of society could obviate
such of the maladjustments as depend upon gains and risks of absorption
not being in the same hands, and a theoretic technique can be worked out
for the most profitable rate of absorption of scientific invention having regard
to invested capital, and skill and local interests. It is sufficient to say that
it needs a tour de force of assumptions to make it function without hopelessly
impairing that central feature of economic progress, viz. individual choice
of the consumer in the direction of his demands, and an equally exalted
view of the perfectibility of social organisation and political wisdom. But
in the field of international relations and foreign trade, which alone can give
full effect to scientific discovery, it demands qualities far beyond anything
yet attainable.

Economic life must pay a heavy price, in this generation, for the ultimate
gains of science, unless all classes become economically and socially minded,
and there are large infusions of social direction and internationalism, care-
fully introduced. ‘This does not mean government by scientific technique,
technocracy, or any other transferred technique, appropriate as these may be
to the physical task of production. For human wills in the aggregate are
behind distribution and consumption, and they can never be regulated by
the principles which are so potent in mathematics, chemistry, physics, or
even biology.

584 EVENING DISCOURSES

SECOND EVENING DISCOURSE

Monpay, SEPTEMBER II, 1933.

THE WORK OF THE SAFETY IN MINES
RESEARCH BOARD

BY
PROF. J. F. THORPE, C.B.E., F.R.S.

Tue Safety in Mines Research Board is appointed by and reports to the
Secretary for Mines and is financed liberally from the Miners’ Welfare
Fund. Its experimental work is carried out at two Research Stations, one
at Harpur Hill, Buxton, and the other in Portobello Street, Sheffield,
where it is in close association with the Department of Applied Science
of the University. Both these Research Stations are under the direction
of Dr. R. V. Wheeler, to whom Dr. H. F. Coward is Assistant Director.
Falls of roof and haulage accidents are investigated by Major Hudspeth,
Chief Mining Engineer to the Board. The Board works also through a
number of sub-committees, of which the Explosives in Mines Research
Committee, the Spontaneous Combustion Committee, and the District
Support of Workings Committees may be regarded as types.

Time does not permit me this evening to deal with the great problems
under investigation by Major Hudspeth and his staff, although it is evident
that such problems are of great importance in relation to mine safety.
Indeed, by far the greater number of casualties and fatal accidents in coal
mines, during the period 1922-31, have been due to falls of ground and
haulage accidents. ‘Thus persons killed through explosions during this
period numbered 521, whereas the deaths due to falls of ground and haulage
accidents were 5,199 and 2,276 respectively. Nevertheless the casualties
due to the two causes last named are mainly adventitious, and it is difficult
to subject them to scientific, as distinct from human, control. On the other
hand the causes of explosions and their elimination can be made the subject
of scientific investigation and the fact that the terrible disasters of the past
no longer occur must be ascribed to the application of the knowledge which
has been gained by scientific research and investigation. It is my object this
evening to describe the way in which this has been done and to show the
many causes which may lead to the ignition of gas, and the methods which
are being taken to remove these causes.

All the experiments have been arranged at the Board’s Sheffield Research
Stations by Dr. H. F. Coward. Three members of the staff, Messrs.
Hartwell, White and Russell, are in attendance as demonstrators.

SAFETY IN CoaAL MINEs.

The conditions of coal-mining create dangers from which other industries

are free.
The fact that work may be carried on underground at depths up to a mile

WORK OF THE SAFETY IN MINES RESEARCH BOARD 588

below the surface of the earth, and perhaps two or three miles from the
pit-bottom, causes the problems of roof-support and underground transport
of men and materials to be particularly difficult. It is not surprising,
therefore, to find that accidents due to falls of roof and accidents incurred
during underground haulage are by far the most numerous.

Yet the accidents which cause most concern, both to the miner and to
the public, are those due to explosions. Partly, perhaps, because of man’s
inherent dread of fire; and partly because an explosion so often claims
many victims.

Explosions may be caused either by gas or by coal dust. During the
process of formation of coal from decaying vegetable matter, a process of
bacterial fermentation, the gas methane, the fire-damp of coal mines, was
evolved. This gas remains to-day pent within the coal substance, or stored
in the associated strata, whence it may be liberated into the mine workings
with disastrous results. Coal dust, if fine enough, forms explosive mixtures
with air as dangerous as or, in some respects, more dangerous than mixtures
of firedamp and air.

Efforts to eliminate explosions and, more importantly, the fear of ex-
plosions from coal-mining, have been fairly successful, more particularly
as regards coal dust explosions. Little by little the various causes of
explosions, of the initial ignition of firedamp or coal dust, have been
recognised and controlled. Our aim is to eliminate them completely.

The greatest danger, initially, of explosion lies with firedamp, because
its presence, unlike that of coal dust, may remain unsuspected; and
because it is so easily ignited. Firedamp is only explosive, however, when
mixed in certain proportions with air, between the ‘ lower limit’ of about
5 per cent. and the ‘ upper limit ’ of about 14 per cent. If, therefore, the
gas, as it issues into the workings, is so diluted with air that it never forms
more than 5 per cent. of the atmosphere anywhere in the mine, it ceases to
be dangerous. Good ventilation of the mine is thus the primary safeguard
against firedamp explosions, and there are, in consequence, stringent
regulations governing the ventilation.

Supposing, though, that the ventilation fails to be effective, there are
many potential means of ignition of firedamp in the pit. Each of these
potential means of ignition—lights, explosives, electricity, frictional sparks—
has to be safeguarded. Much of the experimental work on safety in coal
mines, that is being carried out in this country and abroad, is directed
towards safeguarding all possible means of ignition of firedamp.

Coal dust, which during one period in the history of coal-mining, con-
stituted the more formidable danger, can be rendered harmless as an
explosive agent. Credit, perhaps for the discovery and certainly for the
practical application of the remedy, stone dust, is due to a Yorkshire mining
engineer, the late Sir William Garforth.

The application of the remedy, the spreading of fine stone dust wherever
coal dust can accumulate in the mine workings, so that the mixture is
incapable of propagating flame when raised as a cloud in air, appears at first
sight to be simple, but the problem is complicated by the fact that there is
not a dead level of inflammability of coal dusts. Some coal dusts are much
more inflammable than others, and require to be treated with a proportion-
ately greater quantity of stone dust before they can be regarded as harmless.
Wise mine managers treat the roadways of their mines with an excess of
stone dust considerably above that required by regulations ; and it can be
said with some confidence that, in this country, the widespread disasters
due to coal dust extending small firedamp explosions throughout the

x

586 EVENING DISCOURSES

workings of the mine, such as occurred in 1905-12, need no longer be
feared.

The study of the causes of mine accidents, whether they be due to falls
of roof, to mishaps during haulage or to explosions, and the devising of
remedies, are not in themselves sufficient to secure the increased safety of
the mine worker that we all desire. Often enough, the application of a
remedy against an accident rests with the miner. It is necessary, therefore,
to instruct the miner, who has shown himself most willing to be instructed,
as to the reasons for the measures for safety, sometimes arduous, that he is
called upon to perform, and as to the risks he runs if he neglects them.
For this reason the educational work of the Safety in Mines Research Board
ranks equal in importance with its experimental work.

EXPERIMENTS.

Experiment I.—Experiments on propagation of flame in methane-air mixtures.

Mixtures.—10 per cent. methane-air mixtures. Measurements of the
required amounts of air and methane are made by means of rotameters ;
after passing through a mixing apparatus the mixture is passed into the
explosion tube.

Tube.—Horizontal glass, 19°5 ft. long, 2 in. diameter.

Ignition.—By single break spark between electrodes (4 mm. gap).

Experiment (a). Propagation from open to closed end of tube.—Mixture
ignited by spark at electrodes 6 cm. from the open end of tube.

Propagation showing uniform movement and subsequent vibratory phase.

Experiment (b). Propagation from closed to open end of tube.—Mixture
ignited by spark electrodes 2:5 cm. from the closed end of tube.

Higher mean speed of propagation with vibrations.

Experiment II.—Experiments on the inflammability of coal dust and the effect
of stone dust thereon.

Test I.—Violent inflammation of a typical coal dust.
Test II.—Suppression of inflammation by using an adequate proportion
of stone dust.
Typical coal-dust . ; : . 45 per cent.
Fuller’s earth ; : i UBIGIUT SG Ee
Test III.—Partial suppression of inflammation by using less than the
statutory amount of stone dust.
Typical coal dust . : 4 . 65 per cent.
Fuller’s earth ! . f TOtyED BOL

Experiment III.—Experiments on the ignition of methane in air by a heated
surface and the effect of iodine on the ignition temperature.

Notr.—The late Professor H. B. Dixon showed that traces of iodine
had an inhibiting effect on the ignitions of methane air mixtures.

A jet of methane is passed on to a heated alundum surface, maintained at
a temperature sufficient to ignite the methane in the surrounding air stream.
When the air stream is passed over crystals of iodine at laboratory tempera-
ture (and thus contains 0°03 to 0°04 per cent. of iodine vapour) ignition
does not occur owing to the inhibiting action of the iodine. It is proposed
to erect two similar heated surfaces, cylindrical in shape. One will be
maintained at a temperature just sufficient to ignite the jet of methane in
air. ‘The second apparatus will be used for experiments with air contain-
ing iodine to show that a higher temperature is necessary for ignition
under these conditions.

WORK OF THE SAFETY IN MINES RESEARCH BOARD 587

Experiment IV.—Experiment showing the ignition of firedamp by heat of impact
of handpick on rock.

The apparatus consists of a wooden box 2 ft. by 1} ft. by x ft., fitted with
oiled paper releases and a glass observation window. Attached to the pick is
a rubber diaphragm, covering a circular hole in the cover of the chamber.
The stretching of the rubber is sufficient to allow of a good blow of the pick.

Sufficient pure methane is admitted to the chamber to give an approximate
7 per cent. methane-air mixture. A sampler, fitted with platinum elec-
trodes, is attached to one side of the chamber to check this percentage.

The rock used is that suspected of causing ignition at Canavan’s Mine,
Valleyfield Colliery. A glancing blow of the pick on the rock must be

delivered to cause ignition, there being a bright yellow flash at the point
of contact.

Experiment V.—Experiments on signalling with bare wires.

Pit conditions render it necessary that signalling should be possible at
any point in the roadways over a distance of perhaps four miles, and it is,
therefore, only possible to do this by means of bare wires which are
crossed to make the signal.

The bare wire connections from a signalling bell are brought into contact
in a mixture containing 8-3 per cent. of methane, confined in a glass vessel
of approximately 400 cc. capacity. A vertical exit tube, closed by a loosely
fitting rubber bung, provides a release on ignition.

Bell—A.T.M. (Automatic Telephone Manufacturing Co.) Model,
working on 24 volts.

Experiment (a). Unsafe condition—A 500 ohm shunt, connected in
parallel across the ends of the magnet windings, is disconnected by means
of aswitch. Signalling by bringing wires in contact causes ignition.

Experiment (b). Safe conditions —The 500 ohm shunt is connected across
the coils. No ignition occurs on signalling.

Experiment VI.—Experiment with clay and sand-clay stemmings.

Blown-out shots are a possible cause of ignition and lead to loss of
efficiency in the use of the explosives. It is found that sand-clay remains
but clay is ejected as stemming—a mixture of sand and clay is actually
used.

Experiment. —Lead tubes, 2 ft. long and 2 in. bore by # in. wall are used.
A wooden piston with a brass handle has been made to fit these tubes
closely. When clay is packed into one of these tubes, little force is required
to push the material through the tube. With sand, hammering of the piston
produces a bulge of the lead wall and the sand is not ejected.

Experiment VII.—Lamp testing experiments.

A flame lamp (No. 2a Davis-Haydock pattern) is raised into mixtures
containing from 1 to approximately 6-5 per cent. of methane in the Oldham
chamber. ‘The mixtures are prepared by means of rotameters.

As the percentage of methane in the air is raised from 1 per cent., the
flame of the lamp becomes gradually higher and is finally extinguished in

a mixture containing approximately 6 per cent. of methane. This latter
mixture is ignited with a taper.

Experiment VIII.—Showing that a lighted cigarette does not ignite a 6 per cent.
methane-air mixture.

588 EVENING DISCOURSES

Experiment IX.—Illustration of spontaneous ignition by means of pyrophoric
iron.
Models.—Sheathed explosives.
Films—
Film (1).—Showing a demonstration of a coal dust explosion at the
Research Station, Buxton.
Film (2).—Showing shot firing with
(a) Clay stemming.
(b) Clay and sand stemming.
Slides—
(a) Showing total casualties in coal mines.
(6) Showing total fatal casualties.
(c) Showing effect of stone dusting on casualties due to explosions.

CONFERENCE OF DELEGATES OF
CORRESPONDING SOCIETIES

Tue Conference was held in the Lord Mayor’s Rooms, Hastings Street,
Leicester, on September 7 and 12, under the presidency of Dr. R. E.
Mortimer Wheeler, F.S.A., 43 delegates attending representing 52
societies, in addition to a large audience.

Thursday, September 7.

The President conveyed the congratulations of the delegates to the
Manchester Statistical Society upon the recent attainment of its centenary.
Mr. Frank H. Roby, representing the Society, responded.

The delegates considered the following report communicated by the
Secretary, which was approved and adopted.

“Committee to take cognisance of proposals relating to National
Parks by the Government and other authorities and bodies concerned,
and to advise the Council as to action if desirable.’

The Chairman and Secretary report that no proposals have arisen during
the past year requiring the consideration of the Committee ; and in view
of the improbability of any such proposals arising in the immediate future
under the prevailing financial stringency it is recommended that the
matter might suitably be referred to the Corresponding Societies’ Com-
mittee, with power to co-opt thereto competent members for the special
consideration of the subject should occasion arise.

ADDRESS ON

THE CENTRALISATION AND CO-ORDINATION
OF RESEARCH IN ITS RELATION TO LEARNED
SOCIETIES

By Dr. R. E. M. WHEELER,
President of the Conference.

WE live in a period of feverish co-operation. We co-operate to wage
war, to inflict peace, to abolish old frontiers and to create an infinitude of
new ones. But whatever the difficulties of political or economic co-
operation, an effective co-ordination of effort on an international scale
within the limits of any scientific discipline should be practicable without
a disproportionate expenditure of effort. ‘That difficulties of one kind
or another will indeed arise even in so impersonal a pursuit as that of
knowledge is, of course, inevitable so long as man remains a political
animal. For instance, quite recently, in a branch of science which shall

590 CONFERENCE OF DELEGATES

be nameless, steps were taken for the first time since the war to organise
an international conference. All went well until the question of locale
arose ; and in the controversy which ensued, the detached observer could
not but recall to himself Mr. H. G. Wells’s remark that ‘ Europe is sunk
in pits of stale and unventilated history.’ As a matter of interest, I may
add that, out of the whole of Europe, only in two regions would the delegates
of the various nations consent without exception to meet in conference—
namely, in Scandinavia or in Great Britain. ‘The choice of Scandinavia,
which has, I suppose, always been the least provocative part of Europe,
calls for no comment. But it cannot by the most ardent patriot be averred
that Great Britain has always maintained a similar detachment, and we may
perhaps flatter ourselves that the final choice of this country for the inter-
national conference in question was due to something more than a purely
negative quality in our national character.

This mention of national character brings me to a point which will
probably be implicit in much that will be said to-day. My main subject
is the problem of co-ordination of effort amongst the various scientific
societies of Great Britain; and our discussion will be more than tinged
with unreality unless we realise quite clearly at the outset that neither
co-ordination nor effort is, in the senses which we have in mind, an out-
standing quality of the British character. We make a fetish of individual
freedom to the extent of inhibiting ourselves with all sorts of restrictions
to prevent that freedom from being violated ; and so inclined are we to
laziness that we impose upon ourselves all manner of strenuous enjoyments
as an alternative to work. ‘To these queer complexes we shall have per-
petually to refer any scheme of formal co-operation to which logical argument
may lead us. We may all agree in the abstract that duplication of research
is a waste of time and money, and that some efficient mechanism whereby
results may be freely interchanged and policies co-ordinated would
materially hasten the advance of knowledge. It is, however, one thing to
draw up a logical scheme of the kind and quite another thing to put it
effectively into operation. ‘The personal qualities to which I have alluded
do not induce us in this country, even as scientists, to conform easily to
the dictates of logic and method, that blessed word to which our Teutonic
friends are so devoted. One may perhaps go so far as to say that any
Englishman is perfectly prepared to make a principle of his practice, but
will see you further before he makes a practice of anyone’s principle. In
other words, any effective attempt at further co-ordination amongst the
various bodies which we represent here to-day will proceed rather by the
amplification of present effort than by any attempt to impose a brand new
complete and highly-principled scheme.

By way of introduction, therefore, to the discussion which is our main
function this afternoon, it may be useful to review briefly some of the
efforts which have been or are now being made to collate and to prevent
waste of effort amongst scientific bodies. I shall take my examples mainly
from the province with which I myself happen to have an immediate
contact—that of archeology, though, at the same time, I am fully conscious
that, in certain respects, other branches of research have already reached
a more advanced stage alike of centralisatiori and of judicious delegation.

In his Presidential address to the Society of Antiquaries a few years
ago, Sir Charles Peers dealt in some detail with the desirability of reviewing
the whole field of scientific archeology in this country at the present
time and of drawing up a considered policy of research. Subsequently,
Sir Charles opened a discussion on the same subject at the Annual Congress
of Archeological Societies at Burlington House. He pointed out, on the

CORRESPONDING SOCIETIES 591

one hand, the unprecedented extent of the work, particularly field-work,
now being carried out in Great Britain both by central and by local
archzological societies ; and he appealed, on the other hand, for a greater
co-ordination of this work and for a more fitly proportioned distribution
of energy over the whole field of study. Incidentally, he pointed out
certain specific directions in which current research was overcrowded and
others in which progress had been unduly retarded.

Before we consider the ways and means whereby a reasonable policy of
the kind can be implemented, let us glance at some of the causes of the
present inequality of effort in the province with which I am, for the moment,
concerned. It will, I think, be found that parallel causes are in greater
or less degree the basis of similar difficulties in other branches of science.

In archeology, we are at the present time approaching the end of a
transitional phase. A generation or two ago, the science—then only
partially scientific in method—was still essentially an amateur accomplish-
ment. As such, it was widely cultivated by the country gentry, who formed
the nucleus of most of our learned societies. Some of the research carried
out under these conditions was surprisingly good; much of it, less
surprisingly, bad. But whatever the value of this work in detail, it had—
and, so far as it continues, still has—one outstanding and overwhelming
merit. If it did not necessarily create a scientific understanding of
archzology, it at least established and maintained a widespread sympathy
for that study, and so, more than any other factor, prepared the way for
the next great advance.

That advance is best symbolised by the inauguration of centralised State
effort. The first symptom of the new order, in this country, was the passing
in 1882 of the first Ancient Monuments Act, giving the government slight
and nebulous powers for the preservation of certain classes of antiquities.
I describe this primitive Act as nebulous. It was, indeed, a cloud no bigger
than a man’s hand. It had behind it, however, though not in this country,
a significance out of all relation to its initial size. As long ago as the second
half of the eighteenth century, the great Gustavus III of Sweden had
instituted a State inquiry into the antiquities of that country. We need not
inquire too closely into his motives, which were perhaps as mixed as those
which have induced another autocratic statesman of more recent days to
expose and to advertise the grandeur of Rome. But the Swedish example
has been taken up during the past century in France, Germany, Spain and,
recently, in Ireland, to an extent that enables us to regard a considerable
measure of State control in matters archeological as a normal function of
a civilised country at the present time.

In Great Britain, the protoplasmic Ancient Monuments Act of 1882
has grown successively into the Acts of 1913 and 1931, and has incidentally
brought into being the three Royal Commissions which are now busily
engaged upon recording the ancient and historic structures of England,
Scotland and Wales. The growth of the Ancient Monuments Department
of H.M. Office of Works, which administers the Act, and of the three
Royal Commissions is a factor of primary importance in our problem in so
far as it is concerned with this particular study.

Its importance is this. With the parallel but more reluctant growth
of museum organisation, it has created a nucleus of what may best be
called professional archeology. It might be argued that the emergence
of archeology as a science and its emergence as a profession are really one
and the same thing. One may, indeed, claim archeology as the youngest
of the sciences, and, if only for that reason, you will, I trust, forgive me for
devoting an unconscionable share of my remarks to it.

592 CONFERENCE OF DELEGATES

Now this new professional status of archzology has had, and is having,
a number of rather important reactions. In the first place, the universities
are devoting an increasing amount of attention to it—at least seven new
chairs and lectureships have been created since the war—and so are just
beginning for the first time to impose a sort of academic monopoly upon
the science. In the second place, the position of the older type of local
society is undergoing a change by reason of the widening gulf between the
amateur and the professional. In the third place, so long as the profession
remains a relatively small one, it is on its part peculiarly liable to develop
within itself an excessive narrowness and isolation—in fact, the vices of
most restricted professionalism.

All these are in one way or another disruptive influences. They are
tending to divorce the archzologist from the layman whose sympathy and
help are perhaps more necessary in this branch of knowledge than in any
other. They are tending to divide professed archzologists themselves into
schools which reproduce their own kind, and—of all vices the most subtly
noxious—the new science is inclined to suffer from a kind of snobbism which
the older sciences have largely outgrown. With the minutize of these
dangers and diseases I am not here concerned. Something may be said,
however, on broad lines of the attempts which are being made, or might
profitably be made, to remedy them.

First, let us take the broadening rift between the professional and the
layman. Here, interest and duty agree in fixing the responsibility. The
professional scientist, and he alone, can properly stimulate that great mass
of lay opinion upon which not a little of his own achievement must ulti-
mately depend, whether in the form of individual or of corporate patronage.
On all grounds, a close liaison between professional science and the lay
public is essential to the maintenance and development of research.

This may sound a mere truism, but it is a truth of which three-quarters
of professional science is unappreciative. And in re-affirming it to-day,
I would urge it not merely from the motives of professional self-interest to
which I have referred. I would urge it also as a salutary counter-irritant
to one of the worst afflictions from which a closely-restricted professionalism
can suffer. A few years ago in a presidential address at a meeting of the
British Association, attention was drawn to the plague of pedantic verbiage
which had infested modern science, and a plea was made for simplification
and classification. That plea was a timely one; it might fittingly have
been extended from professional science to such activities as professional
football, professional cinematography and professional journalism. The
dangers of scientific jargon are twofold ; it adds to the obscurity of science
from the lay standpoint, and, sooner or later, it tends to obscure and obstruct
scientific thought itself. I have just been turning over the pages of an
excellent journal which makes it its business to present the results of
scientific archeology to the general public, and my eye has caught three
articles by three of the most distinguished archzologists of the day. On
one page I am caught up in the astonishing hyphenated word ‘ leaf-shaped-
sword-culture-complex ’ ; on another, I see the dark phrase “ the diagnostic
value of negative lynchets’ ; on a third, the remarkable sentence, ‘ These
names were left by the equestrian inhumators who brought in the later
Hallstatt culture... One may perhaps suppose that the ‘ equestrian in-
humators’ had their counterpart in such folk as ‘ pedestrian incinerators,’
and were the forbears of such distinguished sects as the ‘ aerial seventh-day
Adventists ’ and the ‘ submarine Rosicrucians.’ In any case we may best
describe this obscurantist jargon by the one simple word, Hokum. And,
whatever may be the case in other branches of science, it is sufficiently

CORRESPONDING SOCIETIES 593

certain that in professional archzology at the present day, Hokum is on the
increase. Learned and estimable young men in baggy trousers and suede
shoes are spreading contagiously from our universities and are beginning
to cloud their science and their own minds with a whole lot of unnecessary
Hokum, fortifying themselves the while with the disastrous slogan, Odi
profanum vulgus et arceo.

The remedy, could it be enforced, is an easy one. Could these young
men—and, indeed, some of their elders—but be compelled to explain their
ideas periodically to, shall we say, the Netherwallop Antiquarian Society
and Field Club in language intelligible to the local birdscarer, then could
we begin to hope at length for clarity of expression and clarity of thought.
But what in fact happens in all too many cases is this. A young man of
ability goes up to one or other of the older universities and there comes
under the influence of a highly-specialised teacher, who instils his own
special tastes and ideas into his disciple and ultimately secures a fellowship
for him. The youth remains at the university for the rest of his mortal
existence, coming only intermittently and accidentally into contact with the
profanum vulgus beyond its walls. I am speaking now in particular of my
own science of archeology, where the number of professional openings
outside the universities is restricted to an extent perhaps unparalleled in any
other branch of science.

In this problem, therefore, of the co-ordination of research, I would begin
by urging a closer contact and sympathy between the scientist and the
general public. That contact is the return which, whether in its individual
or its collective capacities, the general public has the right to demand for
its constant and, on the whole, liberal support of research. Furthermore,
the maintenance of contact is in itself a fine discipline for the scientist,
compelling, as it does, a constant simplification and valuation of ideas. In
other words, it is an excellent and essential antidote to that insidious pro-
fessional pedantry which I have here called Hokum.

I have spoken so far of the inter-relationship of layman and professional
as it were of the interchange of courtesies between aliens, and I have not
hesitated to put this vital factor into the forefront of my remarks. I now
turn briefly to the more domestic problems of effective co-operation within
the actual limits of organised science. In particular, we are faced at once
with that ever-recurring problem of the proper working-relationship
between the more central scientific bodies and the more local organisations.
In this connection, I cannot refrain from expressing a personal regret that
the central scientific societies in London and Edinburgh do not take a more
active interest in assemblies such as that which I now have the honour to
address. This aloofness is detrimental to the interests alike of the central
societies and of their provincial kindred, and is in some sense another aspect
of that snobbism to which I have already referred as a disruptive force.
I speak with the impartiality of one who is a member both of more central
and of more provincial societies than my banker cares to contemplate ; and
it seems to me that, in future years, something might perhaps be done to
secure a participation of the great metropolitan societies in our proceedings.
It would be impertinent for me to point out here the fundamental value of
the output of many even of the most local of provincial societies. But
I would remind you that we have already had occasion to-day to congratulate
the Manchester Statistical Society on the completion of a century of useful
industry, and would emphasise also the solid scientific work, produced over
a long period of years, in zoology, botany, geology and archzology, by closely-
localised organisations such as—to take a random example—the Cardiff
Naturalists’ Society. I recall as significant the delighted surprise with

X2

594 CONFERENCE OF DELEGATES

which the Transactions of the Cardiff Society (now covering a period of
over half a century) were discovered for the first time two or three years
ago by one of the great scientific societies in London. There is abundant
evidence, indeed, that the gulf between the central and provincial societies
is still an unnecessarily wide one. How can it best be narrowed ?

Here we are up against certain of those traits in the British character
to which I referred at the beginning of my address. It would be easy for
a central society to draw up a clear-cut programme of research and to
allocate to local bodies appropriate shares in its execution—shares, that is
to say, appropriate to the environment and attainment of these various
local organisations. Could this ideal scheme be carried out with reasonable
precision over a period of years, there is no doubt that, in theory, the ratio
of achievement would increase with leaps and bounds. Such, however,
is the unreasonable nature of our British temperament that any attempt
to conscript science in this sort of way is liable to immediate disaster. We
are all anxious to learn but hate to be taught, and any semblance of dictation
is calculated to arouse all the most unthinking. obstinacy in our nature.
Nevertheless, the difficulty is one of method rather than of principle, and
I would again refer to the carefully-considered statement of the present
position of archzological research recently promulgated by the President
of the Society of Antiquaries. On this a further word may be said.

This statement, drawing attention to the major desiderata in British
archeological research at the present time, owes its importance to two
factors. In the first place, under the leadership of Sir Charles Peers, it
received a very thorough preliminary consideration from a committee
representing all the principal interests and localities throughout the country.
In the second place—and I would draw special attention to this factor—
it was discussed by and disseminated through a thoroughly representative
Congress of provincial societies. ‘These societies had thus a direct voice
in the final formulation of the statement, and ultimately received it in a
shape which all or the great majority of their representatives regarded as
acceptable and workable. How far the positive recommendations of the
scheme will be carried into effect by these societies, it is at present too
early to say, but, without going into details in the present context, I may
observe that certain preliminary steps have already been taken in the right
direction.

Here, then, we have a scheme of co-ordination, drafted first by a central
society and then shaped and approved by the provincial societies in conclave.
The whole procedure was, we may say, parliamentary and British, and is,
I think, a fair sample of the kind of method which, at any rate in certain
branches of science, is likely to yield the most satisfactory results. The
essential medium was, as I have indicated, the congress of appropriate
societies; and although the principle of procedure by conference is perhaps
sometimes overdone, it seems to be that method which most nearly accords
with the needs of the age in which we live. I have in mind not merely
the Congress of Archeological Societies but other co-ordinating bodies
such as the South-Eastern Union of Scientific Societies, which, incidentally,
owes so much to the enterprise of our Secretary, Dr. Tierney. Here, in
the South-Eastern Union, we have an organisation through which, in
particular, the smaller local societies find a useful and stimulating medium
of exchange. I would emphasise the word ‘ useful’ and would give one
example to illustrate my point.

The illustration is indeed one of several which will occur readily to the
minds of many of you. You will recall that, as the Great War proceeded,
our Local Government Board realised the potential source of dangerous

CORRESPONDING SOCIETIES 595

infection to the population of this country through the introduction of the
malarial parasite by infected troops returning in large numbers from
Macedonia, Gallipoli, Mesopotamia and elsewhere. The Board accordingly
instituted inquiries amongst local scientific societies to ascertain the pre-
valence and distribution of anopheline mosquitoes in England and Wales.
In the course of this investigation, the suspicion arose that an elusive tree-
hole breeding species of anopheline mosquito (Anopheles plumbeus) was
capable of becoming an infected intermediary host of the malarial parasite,
and of transmitting it. This suspicion was confirmed, and special steps
were promptly taken to ascertain the distribution of the noxious species.
The task was not an easy one, and its accomplishment was due in no small
degree to the officially-invited co-operation of the South-Eastern Union of
Scientific Societies, by which inquiries were instituted among the affiliated
societies throughout the Union’s area.1_ As the result of these and parallel
researches, the danger was successfully countered; and the ravages of
malaria, which have been ingeniously credited with the decline and fall of
the ancient Greek and Roman civilisations, cannot now be saddled with
the responsibility of any declension in our own.

The example which I have just given emphasises the utility of regional
congresses or unions of scientific bodies as a machinery for stimulating
and co-ordinating effort. At the present moment, I believe, steps are
being taken to form some such union for the great midland area in which
we are meeting this week. The movement deserves all success, and should
be followed in other parts of the country. The more numerous local
scientific societies become—and they have increased rather than diminished
in numbers since the war—the more urgent becomes the need for
systematic co-ordination. A general meeting held once a year under the
auspices of the British Association is no sort of substitute for regional
organisation. Let me refer in this context to the co-operative movement
which has, during the past decade, been growing in strength amongst the
museums of England and Wales. The wasteful rivalries and petty jealousies
which had tended to obstruct the proper functioning of local and, indeed,
of national museums seemed to some of us not to be the inevitable
alternative to apathy and ineffectiveness ; and schemes whereby smaller
museums could work in affiliation with larger museums on a regional
basis were brought into operation. The method was first evolved, I think,
in Wales, which happens to be an obvious and convincing territorial unit
and where, incidentally, co-ordination in a country so sharply subdivided
by geography and tradition was specially desirable. The result of the
experiment there has been completely successful; the local museums
and the National Museum to which they are affiliated have alike benefited
in various important directions which I need not here particularise. The
Welsh example has been followed in Lancashire and Cheshire and elsewhere,
and the movement as a whole received strong approval and encouragement
from the recent Royal Commission on National Museums and Galleries.
No central national organisation—however useful as an ultimate co-
ordinating authority—can replace regional organisation of this kind, whether
amongst museums or amongst other scientific institutions, as a practical
solution of the problem with which I am here concerned.

Lastly, as a mere spectator in the fields of natural science, I freely confess
to a feeling of envy for the comparative simplicity of the problem of co-
operation in those researches which do not directly relate to the handiwork
of man. The distribution of a species, the ecology of a plant, can be

1 The history of the investigation is summarised by Dr. Tierney in the
Transactions of the South-Eastern Union of Scientific Societies, 1923.

596 CONFERENCE OF DELEGATES

studied up to a point through the instrumentality of relatively unskilled
labour. A specimen can be sent up for verification ; it is rarely unique
in the locality where it is found, and its locale can therefore be verified, if
any particular report or record is open to doubt. But in the scientific
study of man—in archeology, anthropology, tertiary or quaternary geology—
this is, as arule, not the case. The value of a bone or an artifact is generally
the value of its finder’s skill and acumen. Its intrinsic interest is very
often negligible. Its precise relationship, before disturbance, to the
strata in which it lay is probably of cardinal importance. But that
relationship is intelligible only to the highly trained eye, and, once disturbed,
can rarely be reconstructed or satisfactorily checked. Under such circum-
stances, what I have called ‘ unskilled labour ’ is nearly useless, and semi-
skilled labour, through misinterpreting the subtleties of a discovery, may
be a positive danger. It is, I suppose, the destiny of the human sciences—
the sciences relating directly to man—to be inexact. I turn therefore more
hopefully to those sciences which are of a more reputable kind, which deal,
it may be, with the inferior orders of creation but can at least deal with them
in a very superior way. And I conclude by inviting what I may call a
‘descriptive discussion’ of the efforts and needs of the various branches
of organised science for more effective organisation.

Dr. G. C. Rosson.—Zoological Surveys.

Dr. Robson, inviting the co-operation of societies in the compilation of
zoological surveys in their own areas, drew attention to the value of such
surveys, especially where the results are published in the transactions of
some central organised body embracing the area, such as a union of
scientific societies, where such records as may prove of value are more
readily accessible for scientific reference than when published in the
proceedings of societies having a purely local circulation amongst their
own members.

In the discussion which followed, Captain T. Dannreuther reported
upon the development and progress of the Insect Immigration Survey
undertaken by the South-Eastern Union of Scientific Societies. Mr. R.
Adkin, Prof. F. Balfour Browne, Dr. F. A. Bather, F.R.S., Mr. T.
Sheppard, Dr. G. F. H. Smith, and Mr. E. W. Wignall also contributed.

Tuesday, September 12.

Mr. T. SHepparD, M.Sc., Chairman of the River Hull Pollution Com-
mittee —The Effects of Pollution on the Flora and Fauna of Rivers.
The Pollution of the River Hull.

(Ordered by the General Committee to be printed in full.)

I HAVE been asked to address the Conference of Delegates from the Corre-
sponding Societies of the British Association on the subject of the cause
and effect of the pollution of the river Hull, for two reasons: (1) that the
work was largely carried out by amateurs, members of local scientific
societies ; and (2) that our experience of what to do, and more particularly,
what not to do, may be of service to members of the Corresponding Societies
in whose areas similar investigation might profitably be carried out. ‘
The river Hull has its source at Emswell, near Driffield, in East York-

CORRESPONDING SOCIETIES 597

shire, and its upper reaches, where it emerges from the chalk, form one of
our best trout streams. It flows in a southerly direction along the west
of the ‘ Isle of Holderness’ until it reaches the estuary of the Humber at
the city usually called Hull, though its correct name is Kingston-upon-Hull.
In its lower reaches the river is tidal and very brackish. When it is remem-
bered that the Humber is fed by the Trent and Ouse, and their tributaries,
which carry the sewage from a large proportion of the towns of the north
of England, in addition to which a fair share of the material denuded from
thirty miles of the Holderness Drift cliffs is carried into the estuary, it will
be understood that this area is not of much interest to anglers.

The area reviewed in these notes therefore is a matter of sixteen miles
between the Top Lock at Beverley, where the tidal influence ceases, and Drif-
field, about which place the trout streams are pure and well stocked with fish.

The growing population at Driffield and Beverley, with the increase in
factories; sewage disposal works; the more modern methods of agricultural
drainage, with its contamination caused by the increase of artificial and other
manures on the land, as well as the effect of tar sprays and petrol washed
from the roads, all have helped to change the nature of the fauna and flora of
the river.

Many years ago Hull’s water supply was extracted from the river Hull,
and was passed through filter beds at Stoneferry to the north of the
city. A serious epidemic at Beverley was followed by a much more
serious outbreak at Hull, for, while the filter beds clarified the water, they
were unable to extract the bacteria. Since then Hull has bored into the
chalk for its water supply.

In that section of the river which has had our supervision for some years,
the anglers first drew attention to the fact that sections of the stream, which
once were prolific, are now almost useless for angling purposes. While
making investigations in a part of the river Hull known as Whinhill, we
record that a man ‘ who gave his age as 76 years, stated that the most
interesting day of the week on which to view the canal at Whinhill is Tuesday,
as on that day “‘ blood and suds ”’ come down the stream ; blood from the
slaughterhouses at Driffield, Tuesday being killing day ; and “‘ suds ”’ from
the washing of clothes which takes place on the same day of the week.’ He
also stated that years ago the stream was full of fish, and now there is not
one.

The members of the various angling societies in the district, realising that
the changes in the river were resulting in the fish gradually disappearing,
appealed to the Yorkshire Fishery Board, which in turn appealed to the
Ministry of Agriculture and Fisheries. That Board sent its scientific
representative, Dr. E. C. Jee, to make inquiry, and eventually a local com-
mittee was formed, thoroughly to investigate the fauna and flora, the effect
of sewage contamination, and the chemical and biological changes which
were taking place.

This committee consisted of representatives of the Hull and Driffield
angling societies, amateurs interested in the vertebrate fauna, mollusca, and
other lower forms of animal life; the flora and lower forms of vegetable
life ; and chemistry, meteorology, etc., likely to affect the problem. These
were drawn from the Hull Scientific and Field Naturalists’ Club, the Uni-
versity College of Hull, etc., and the Hull Waterworks Department ; the
Secretary was Commander A. L. Woods of the Ministry of Agriculture and
Fisheries in Hull, the Chairman being T. Sheppard.

To begin with, periodic examination was made of the state of the micro-
scopic fauna and flora of the river, as upon these the freshwater snails,
worms, etc., are fed, which in turn supplied food for the fish. In this way,

598 CONFERENCE OF DELEGATES

for some years, samples have periodically been taken at various points in
the stream. The effects of sewage, gas-works effluents, and other sources
of contamination were apparent, and having obtained sufficient scientific
evidence to show that these sources of pollution had a detrimental effect
upon the health of the river fauna, and were therefore likely to be detrimental
to the health of human beings, interviews were arranged with the various
parties concerned.

The nature of the filthy and evil-smelling slime which stifled the vegetation
and made animal life impossible in the vicinity of sewage outfalls, told an
obvious story. As a result, improvements have been made in the method
of treating the sewage, and in preventing poisonous gas liquor from finding
its way into the river, all of which is to the good.

The reports of the various observers of the macroscopic and microscopic
fauna and flora, as well as the marvellous series of observations on the
chemical and other properties of the water carried out month by month by
Mr. N. C. Akers, have indicated certain directions in which experiments
might definitely be made to ascertain the effect of the polluted water upon
the fish in different parts of the river. For this purpose, with the aid of the
Yorkshire Fishery Board and the local angling societies, large numbers of
different species of fish were secured, and placed in specially designed cages
at selected points of the river, and periodically examined. So far, however,
the experiments have been largely of negative value, though we have been
able to ascertain what to avoid in dealing with captive fish.

In the first place, most freshwater fish suffer by being handled, and still
more during transport—so much so that the damaged scales, etc., readily lend
themselves to the growth of a fungus which quickly causes a large mortality.
Similarly, if the cages, though kept under water and with facilities for
the fresh water to pass through, are too small, or unsuitable in their con-
struction, and the fish damage themselves and thus soon die. Further, also,
marking the fish in different ways before allowing them their freedom in
the stream has given negative results, as none of the hundreds of marked
fish has been recovered. At the present time trout, and ‘ goldfish "—which
seem to be immune from many of the troubles referred to—are being subject
to experiment. In any case the work has proved to be exceedingly interesting
from a scientific point of view, and before our labours are completed we hope
that results of a practical nature will accrue.

At the same time, however, as years go on, increasing population on the
banks of the river and on its tributary streams, together with the necessity
for disposing of the waste liquors from the factories which increase in size
and numbers, all militate against a return to the ‘ good old times.’ But
the Ministry of Agriculture and Fisheries considers that the work done in
East Yorkshire by amateur zoologists, botanists, chemists, and others might
easily be undertaken in other areas ; and the object of these notes is to suggest
to the delegates that they consider whether they can help; and I am assured
that the Ministry will give every facility and place its accumulated records
at the disposal of any society inclined to take up this fascinating work.

As one who has missed but very few of the scores of meetings which have
been held dealing with nearly all aspects of the question, I can assure you
that the investigations are full of interest.

There are other aspects of the matter which I have not dealt with, but which
are bound to arise, namely, the legal questions, which are keenly watched
and contested by the legal representatives of the different parties. ‘These
difficulties and the wonderful arguments which have been brought forward
are, I fear, beyond me; though they have been quite entertaining! This
particular subject was dealt with by Mr. H. F. Atter in Section G yesterday.

CORRESPONDING SOCIETIES 599

Mr. J. W. Walton (Folkestone) contributed a note on the apparent
deleterious effect upon the fish in the Royal Military Canal at Hythe,
Kent, by the reduction of the water level and the dredging and cutting of
plant growth in the canal. A discussion followed in which Mr. F. T. K.
Pentelow, representing the Ministry of Agriculture and Fisheries, warmly
welcomed the observation of local societies upon the variation and changes
of the fauna and flora of the rivers within their respective areas. Mr. J.
Adams, Mr. T. S. Dymond, Mr. H. E, Salmon, and Dr, J. F. Tocher also
took part.

Mr. J. Fairgrieve read a paper on The Amateur Meteorologist, in which
he directed attention to the importance and value of the meteorological
organisation of this country, which was in large measure due to, and
founded upon, the work of the amateur observer. He indicated ways
and means whereby an extension of those observations and records would
be of value, especially by observers in remote districts. Dr. G. C.
Simpson, C.B., F.R.S., supporting Mr. Fairgrieve, stressed the desirability
of societies undertaking regular local observation in their own areas and
supplying such records to their municipal authorities, thereby affording
material assistance in the compilation of the meteorological records of
their own localities. Prof. F. G. Baily, Captain T. Dannreuther, the Rev.
Pryce Jones, and Mr. T.. Sheppard also contributed to the discussion.

ON PLANT GROWTH HORMONES
(AUXIN A AND AUXIN 8B)

BY
PROF. DR. FRITZ KOGL, Urrecut.

(Ordered by the General Committee to be printed in extenso.)

THE experiments which I am about to bring before you were mainly carried
out in conjunction with Dr. Haagen-Smit and Dr. Hanni Erxleben; they
are based on modern researches on the physiology of vegetable growth—
researches which we owe chiefly to the school of Prof. Went of Utrecht.
As a preliminary I would summarise the chief results of these researches as
follows : Whilst animal growth takes place almost exclusively by multi-
plication of cells, we must distinguish in plants between cell division and
cell extension. ‘The obvious increase in volume which is seen in higher
plants depends principally on cell extension. Fig. 1 shows two stages in the

<— Growth
substance
ts formed
tn the top

of the

Avena-
coleontite.
(Avena sativa
= oats ).

ek

removed a

‘deficiency con-
dition"is induced

resulting in an

interruption of

substance
wanders

extension
of cefts.

During this
interval new
wth can be
Grought about
6y See a
btock of agar

containing Guxins

of the Clock of
agar is placed
on the cofeontife
stump asymmetri-
cally, a curvature
results from the

unequat growth

of the two sides,

, Under certain
4 Conditions this

curvature

ts according to
FWWent

Lrgnortional

to the concentration
auxin.

Of the angle (o:) is 10°

the tis

Avena-unit.

sds
=<

+ Shototronism:
vege
side ts s found
to have a

higher
auxin content

38, 3
-Seotronism:

the under side is
Jound tohave a higher
auxin content

extensional growth
during ajew hours.

of various sources. than the opposite side.

BGs 2s Fic. 3.

cell extension of oats seedlings. This extension takes place under the
influence of definite growth substances, which may be termed auxins. 'The
mode of their physiological action and recognition is represented diagram-
matically in Figs. 2 and 3. ‘The active substances are formed in the top of
the seedling and wander from there into the base ; if the top is removed a
* deficiency condition ’ is induced, resulting in an interruption of extensional
growth during afew hours. During this interval new growth can be brought
about by auxins from various sources. If the block of agar containing
growth substance is placed on the coleoptile stump asymmetrically, a curva-
ture results from the unequal growth of the two sides. Under certain
conditions this curvature is, according to F. W. Went, proportional to the
concentration of the growth substance ; if the angle of curvature is 10° the

British ASSOCIATION REPORT, 1933

Fic. 1.—Two stages in the cell extension of oats seedlings.
A = 2 days old; B = 4 days old.

Fic. 14

Illustrating Prof. Kégl’s paper on Plant Growth Hormones

[To face p. 600

Lar. My Jp
17 JAN 34.

lig je LIS oes

ON PLANT GROWTH HORMONES 6or

growth effect is called one Avena?! unit (A.U.). We may further mention
that phototropic and geotropic curvatures are also caused by auxins ; thus
the shaded side of the shoot (in the former case) or the under side (in the
latter case) are found to have a higher auxin content than the opposite side.
The growth test of Went, by the help of which we were able to isolate the
auxins, is best shown ina film. (Demonstration.)

When some two and a half years ago we were searching for a suitable
source from which to isolate auxins, our attention was directed to the high
auxin content of human urine. We know now that the isolation of the
auxin from urine implies a concentration of 21,000 times ; its isolation from
the vegetable sources which were known at this time would have meant
a concentration of at least 500,000 times. Under these circumstances
it will be readily understood that we followed the line of least resistance and
first attempted the isolation from urine, although this is an animal source,
a circumstance which many botanists no doubt felt to be an esthetic defect
in our work.

We have earlier described the isolation of auxin from urine. The quan-
tity of crystallised auxins which we have obtained so far from urine—about
400 mg.—would have just been sufficient for three or four com-
bustions before Pregl introduced micro-analysis seventeen years ago. If,
now, we had devoted all our energy to the preparation of pure auxin, it
might have been possible to convert the trail or the footpath which led us
to the crystalline substance into a high road. For the problem as a whole
it seemed to us, however, more important to devote a part of our time to
the study of new physiological problems which presented themselves ; this
also helped the chemical investigation in many ways ; we were, moreover,
able to compensate to some extent for the shortage of material by improve-
ments in the preparative micro technique.

Micro-analyses, determinations of the molecular weight, and titrations,
led us to the formula C,,H;,0; for auxin; this composition also agrees
with that of the derivatives obtained so far. In addition to a carboxyl
group the molecule contains three alcoholic hydroxyl groups ; the course
of the hydrogenation shows that auxin contains one double bond and one
carbon ring ; it is therefore a monocyclic trihydroxy carboxylic acid with
one ethenoid link. If we call the basic hydrocarbon C,,H3, auxane, then
the growth substance is auxene-triol-acid.

A second crystalline substance of equal physiological potency was recog-
nised in auxin lactone C;,H3,O,. Like auxin the lactone exhibits mutarota-
tion, which is evidently due to the attainment of an equilibrium between
the acid and its lactone. A constant rotation is reached after two or three
hours, and if we may utilise the results of Haworth and his collaborators by
way of comparison, we can deduce the size of the lactone ring. According
to these authors 8-lactones usually attain equilibrium in a few hours, whilst
y-lactones require days. We consider it therefore probable that in our
case the substance is a 8-lactone. If there were hydroxyl groups in both
the y- and 5-positions, the formation of a y-lactone would very probably be
favoured, whence we conclude that there is in auxin no hydroxyl group in
the y-position (with respect to the carboxyl group).

So far we have only been able to sacrifice 126 mg. of the substance for
degradation experiments. Miss Erxleben has succeeded in isolating two
important oxidation products. The first oxidative attack was directed
against the double bond. On treatment of 25 mg. with permanganate in
sodium carbonate solution a crystalline optically active acid was obtained.

1 Avena sativa = oats.

602 ON PLANT GROWTH HORMONES

The experiment was repeated twice with the acid, and once with the lactone ;
we were thus able to characterise the degradation product by means of
analyses, titration, and preparation of the p-Phenyl phenacyl ester as a
dicarboxylic acid of the formula C,;H5,0,4.

Of course one is inclined to assume that the auxin molecule was split
at the double bond, and that one of the carboxyl groups of the dicarboxylic
acid was identical with that one already present as such in the auxin molecule.
This assumption, however, at once creates a difficulty: since our C,3-acid
does not contain the hydroxyl group which in auxin occurs in the $-position
relative to the carboxyl, this group must have been present in the C; residue
removed by oxidation. If we do not wish to assume a lactone ring with
more than six members, we arrive at the partial formula of Fig. 4, according
to which the C,;-acid should be a substituted malonic acid. The acid,
however, could be heated 100° above its melting point, without losing carbon
dioxide. We assume therefore that both carboxyls of the C,;-acid have been

Cra th 0, + CsthO,
(auxin) (arcarfoxylic acta)
— C7

AH
R- Git: v NC

COOH-

This formula would ead
tod malonic acid:

v2 CA COOH
Double Bond betwe COOtt
Cand Cy ssainael wou Gsad toan

austin hes no
enolic hiydrosgt ?

Fic. 4.

newly formed by the oxidation of auxin, whilst the ‘ auxin carboxyl’
originally present was removed with the C;-residue.

In order to test this hypothesis further, we oxidised dihydro auxin in
glacial acetic acid solution with chromium trioxide. So far we could only
do one experiment, with 22 mg. of substance. Fortunately we obtained
besides oxalic acid a neutral product which could be converted into a crys-
talline p-nitrophenyl hydrazone, the micro-analyses of which indicate the
formula C,;H;,O for the oxidation product. Since it gives no aldehyde
reactions it must be a ketone. In this oxidation also the oxygen atoms
originally present in the auxin molecule have disappeared with the C;
residue ; evidently the cyclic ketone corresponding to the C,3-acid has been
formed.

The simplest explanation of the results of the degradation leads to the
following working hypothesis (Fig. 5) :

(1) The three hydroxyl groups are not distributed over the whole mole-
cule, but are localised in the region of five carbon atoms ; one of these five
carbon atoms belongs to the carboxyl group.

(2) In the C;-residue there is probably a hydroxyl group in the 8-position
with respect to the carboxyl, whilst the y-position is free of hydroxyl. The
two other hydroxyls would then have to be in positions « and 8. :

(3) The ring of auxin is not terminal ; it probably contains the double

ON PLANT GROWTH HORMONES 603

bond, and it is at acarbon atom bearing this double bond that the C;-residue
is attached.

I will not present here probable formule for auxin which may seem rather
premature ; but I will limit myself to a few formule which by now have

6uplanation of degradation.
results :

"Cotes
4 Coonpea ase? Seni,
Cy -mesidue :
—CL CH-Ch- CH Coow-
. "lactone w

3, C,-restdue : ane

—G

4, OxCdation ofauxin:
: Ee oir Meany Cog COOH
A ND (Fe)
3; Quidation of difydro anvin :

CF rb Gz C008

Me ro, C0 (tind)

Fic. 5.

already been disproved but nevertheless afford an illustration of the con-
stitutional problem. Attention may first be called to the formula of chaul-
moogric acid (Fig. 6). Like auxin this vegetable acid contains 18 carbon
atoms, a double bond, and a ring ; there is, however, no relationship, for
chaulmoogric acid has a terminal ring. Of the formule in Fig. 7, the first
may be excluded with certainty since 4-m-heptyl cyclo hexanone, synthesised
by Mr. Picard, is not identical with our ketone. The exact comparison of
B-n-heptyl adipic acid, which was also synthesised, has not yet been made,

=CH
(TS cHe- (Ct COOH:

Cte —Ch

chaulmoogric acid
(Cratt20)

Fic. 6.

since the synthetic acid has not yet been resolved into its enantiomorphs ;
the same applies to «-n-heptyl adipic acid synthesised by Mr. Koningsberger.
The following experiments showed us, however, with certainty that our
C,;-acid has a different structure, for we submitted the two adipic acids,
in quantities of 20 mg., to Blanc’s reaction and could obtain definitive
evidence of the formation of pyrolytic ketones. The degradation product
however furnished in a similar experiment no such ketone, but an acid
anhydride. The formation of an anhydride in Blanc’s reaction is quite
general with glutaric acids, exceptional with adipic acids. Hence we con-
sider it to be more probable that our degradation product is a glutaric acid
and that auxin contains a five ring. Numerous substituted glutaric acids

604. ON PLANT GROWTH HORMONES

are being synthesised in my laboratory. If our working hypothesis is in
the main correct, the problem consists further chiefly in determining the
way in which the ultimate residue of Cy is attached to the glutaric acid and
to the corresponding cyclopentene ring. Perhaps we can obtain further
insight into the constitution of auxin by the syntheses of octyl glutaric acids
and dibutyl glutaric acids which are in progress ; in this connection we are
especially concerned with isoprene as a possible unit. We shall of course
also utilise X-ray analyses, and we sincerely hope that it will not be necessary
to synthesise and resolve all the 1,200 substituted glutaric acids containing
13 carbon atoms !

Although it was of course self-evident that we should first try to isolate
the vegetable growth substance from the most favourable source, we were
conscious from the very beginning that its isolation from vegetable sources
should next be attempted. Our whole experience indicated that the reac-

Ci,
Cth, Cth Oh CCC - CHG Ne=ctt cy ct ctt.
“4 & On * On OF by

| ee.

Oh Ch,
Ch-Ch-CH-CH-C hCG ZD,
pn hepyl.odenio Ce

Ch CH
CH Cthy Ch; Cir Oh” Yc=0
#-n-heptyl cyclohexanone C-Ch

Cy Oh Ct Cie Cth Ch Ch HCE
-2-R Cadi 20 £
ih hol A a

Fic. 7.

tion of Went is a strictly specific test, and it seemed likely that the active
substances from various sources were identical or very closely related.
But recently such predictions require, more than ever, experimental proof,
for in the case of the follicular hormone (cestrine) it has been found that the
“lock * can be opened not only by the classical ‘ key,’ but also, more or less
easily, by rough copies, or even by skeleton keys.

My collaborator, Kostermans, has undertaken the difficult task of isolating
the vegetable growth substance from yeast, which requires a concentration
of about 500,000-fold. Miss Erxleben has already succeeded within the last
few months in obtaining active crystalline material from other vegetable
sources, first from maize germ oil and then from malt. Both these materials
are very closely related to the coleoptiles of oats, in which the growth
substance was first discovered. Although specially favourable samples were
used, the maize oil required a 300,000-fold concentration, malt one of
100,000-fold ; the procedure employed was essentially that worked out
for urine. Both from maize oil and from malt two active crystalline sub-
stances were obtained. The first was found, by means of its melting point,
mixed melting point, analyses, and physiological action, to be identical with
auxin isolated from urine. The second crystalline substance melted 13°

ON PLANT GROWTH HORMONES 605

lower than auxin ; according to its very probable formula C,,H )O, it is
isomeric with auxin-lactone, from which it differs however completely,
already by its acid nature. A close relationship to auxin must, however, be
assumed on account of various chemical properties; the physiological
activity is of the same order of magnitude as that of auxin and its lactone
round about 50,000 millions A.U. per gram. Within the last few months
we have prepared 120 mg. of the new crystalline substance which we will
designate as aquxin-b ; the substance first isolated from urine will hence-
forth be called auxin-a. Of the four oxygen atoms of auxin-b, two belong
to a carboxyl and one to a hydroxyl group. The course of the mutarotation
once more indicates that this hydroxy] is in a §-position with reference to the
carboxyl. The fourth oxygen is present as a ketogroup: auxin-b yields
a crystalline semicarbozone and on treatment with methyl alcoholic hydrogen
chloride forms a crystalline lactone of the dimethyl acetal. Finally, we can
also give some indication of the position of the carbonyl group relative to
the carboxyl. At its melting point auxin-b rapidly evolves carbon dioxide
and passes into a neutral substance. As far as we can see this is only com-
patible with the assumption that auxin-b is a B-ketonic acid (Fig. 8) ; we are
surprised that the substance can nevertheless be isolated. We have not

Auxin-a G20;
C rprkt tri-of- a)
R-Ci 1 Ct -C TCE, OHO OK

AAuxin-6 Ce tbo
(auxene-ofon-acid)

R-CH-CH-CO- Co,
Fic. 8.

yet succeeded in transforming one of the auxins into the other, but we have
been able to oxidise auxin-b with permanganate to the same dicarboxylic
acid with 13 carbon atoms which we had already obtained from auxin-a ;
the double bond must therefore be in the same position in both molecules.
Finally, it should be mentioned that the crystals of both auxin-a and of
auxin-b completely lose their physiological action on keeping for some
months. All these facts make it certain that our two auxins are very
closely related.

The occurrence of auxin-a in urine brought this vegetable hormone
(‘phytohormone ’) also into the realm of animal physiology. We have
given considerable attention to the problems arising in this connection, but
I can only mention the results here very briefly. Adults excrete about
2 mg. of auxin-a per day, independently of age or sex.. Urine excreted a
few hours after a meal has the highest auxin content (Fig. 9). During a day
of fasting less auxin is eliminated and the characteristic ‘ auxin peak’ does
not appear. We have tested various diets and found that after ingestion of
glucose, starch, or egg white no auxin peak appears, but that such a peak
does appear after ingestion of salad oil (arachis oil; Fig. 10), and butter
(Fig. 11). Fats and oils contain the auxins in a free or in an esterified form.
A hydrogenated coco-fat, in which the auxins had been modified by reduc-
tion and inactivated as regards plants, produces no auxin peak (Fig. rr).
The auxin peaks do not therefore arise indirectly after ingestion of fats.
A large part of the eliminated auxin is derived from the fats of the food.

606 ON PLANT GROWTH HORMONES

Presumably there are also in food unknown precursors or derivatives of the
auxins. So far we have been unable to isolate auxin-b from urine ; we
must therefore conclude that the auxin-b ingested with the food is trans-

: frourty elimination of auxin in urine. ;
chiief,18% | chief meat 18: oftef meal 10 | chicef meat 10% ‘cfiefmect73%
Se is coun: Cok ea

“GE. : i

|
-% :

-~

Fic. 9.

formed in the organism into auxin-a. In this connection we may recall the
relationship between methyl glyoxal and glycerol, and that between the
follicular hormone and its hydrate.

The isolation of auxin-b has of course raised many new physiological
questions. At present I would merely mention that according to experi-
ments dueto Dr. Albert Fischer of Copenhagen, the growth of fibro-blasts of

trourty elimination of cuir on urgestion of various, Food stuzs.

no food i gfzcose | starch | saladoil: egguhite |
y

{ ; 7 3

100ce + (So, 125: : @oocc) : 7110,

foe ge 9) (1259) sal (7709)

16 milfvons of ALL aaa na 72h H 2h
peer hoar

Syne oof

”

7

|
|

the heart is not accelerated when auxin-a or auxin-b is added to the nutritive
medium of tissue cultures. So far we have obtained no indication that our
vegetable growth hormones have also the function of animal hormones.
Rather is it a question whether the auxins, which are so important to the
plant, have for the animal organism the character of vitamins, or whether
they are merely substances indifferent to the animal body.

Finally, I would like to refer to certain experiments which are really a

ON PLANT GROWTH HORMONES 607

‘ by-product’ for us chemists, but are of great biological interest. The
potency of 50,000 million A.U. per gram of our phytohormones is only an
average value ; the actual potency varies from day to day, and in the course
of time we have observed with standard solutions all degrees of potency
between about 10,000 million and 100,000 million A.U. per gram. Our
suspicion has been more and more strengthened that these large variations
are not due to experimental error but to unknown external causes, which
can even exert their influence in our dark laboratory kept at constant tempera-
ture and humidity. We paid special attention to the various atmospheric
conditions, but no certain relationship could be deduced even from observa-
tion extending over several months. My colleague, Prof. Went, informs
me that the possibility of such unknown influences of the weather has often
been canvassed in vegetable physiology, but that all experiments aiming at

Denendence of auxin elimination
upon the nature Sf wegested pe a

age oe Gutter Aueragenated
OTE i 703° H ak (7009);

the discovery of definite relationships, e.g. to ‘ atmospheric electricity,’ have
failed.

We did not make any progress until we undertook the examination of the
potency of the auxins at hourly intervals during periods of 24 hours. This
examination was more easily planned than carried out, but the skill and
perseverance of my collaborator, Dr. Haagen-Smit, overcame all technical
difficulties. Whilst we normally carry out tests on 300 to 400 seedlings per
day, up to 1,500 seedlings had to be examined on the following important
experimental days. Since the age of the seedlings in the test reaction is not
a matter of indifference, we use them exactly 88 hours after sowing. ‘The
determinations of potency during the 24 hours of an experimental day were
therefore only valid, when the sowing had likewise taken place at hourly
intervals, four days previously. The results of the experiments are repre-
sented in Figs. 12 and 13, in chronological sequence. I would here sum-
marise them by a few empirical rules :

We found that in the morning hours—not always but mostly—there occurs
a pronounced maximum of potency. Thus, for instance, one and the same

608 ON PLANT GROWTH HORMONES

auxin solution was, on December 17th, at 4 A.M., six times as active as in
the forenoon of the preceding day. A potency which we had previously

Standard variations
‘ Sent.30% Oct.1" 1932.

o 70° per G

Nov. 4% Nor:S*1932.

regarded as characteristic of an individual day, in reality therefore applies
to the actual hour of the experiment.
After consultation with Prof. Ornstein of the Physical Institute and his

6 & 0 2 W 16 8 20 2 2% 2

ae wall perg Jan.20% Fan21°1933.

FO —e-

e o- Tae,
60° ZUR

Toten

assistant, Mr. Jan Went, we carried out further series of experiments in
order to elucidate the changes in the potency of our standard. We tested
the potency of auxin solutions on seedlings grown in a Faraday cage, in

ON PLANT GROWTH HORMONES 609

metal boxes, and in bakelite boxes, and also kept in these containers during
the twenty-four hours of the actual experimental day. We, of course, took
care to have the same temperature and humidity inside the boxes as in our
laboratory.

Now whilst the action of the auxin on the ‘ cage seedlings ’ and ‘ bakelite
seedlings ’ was pretty much the same as that on the control seedlings out-
side, the seedlings in the metal boxes gave us quite a different curye of
potency ; this curve is on the average higher and the percentage variations
aremuchsmaller. The difference is all the more striking if we bear in mind
that the seedlings have to be removed from the boxes during a short interval
each time they are manipulated in carrying out the test.

What conclusions can be drawn from these experiments ? The essential
difference between metal and bakelite boxes is doubtless that in the former,
that is inside a conductor, an electrical field is abolished and atmospheric ions
are eliminated. ‘The electrical field is also abolished inside the cage, but
the latter does not completely eliminate atmospheric ions. No difference
could be observed between zinc walls of 0-8 mm. and leaden ones of 5 cm.
in thickness. The leaden box was suggested by our physical advisers with
a view to the detection of a possible influence of cosmic rays.

It was of course our aim to influence the susceptibility of the seedlings to
auxin solutions at will, by physical means. We were as yet unable to do
this by definite electrical fields and a supply of atmospheric ions, but we
succeeded by means of an experimental arrangement suggested by a con-
versation with Prof. Pohl of G6ttingen. On the supposition that the
observed variations were caused by very weak electrical currents in the
seedlings, we have artificially produced a potential difference in them:
For this purpose (Fig. 14) a moist silk thread was fastened to the agar block
and then, for instance, connected to the positive pole of the source of current,
while the plant trough was joined to the negative pole, or conversely. We
had for example a potential difference of 80 millivolts per cm. and a current
of 0-0008 milliamperes. What was the effect ?

The auxins are acids. When the silk thread was connected with the
negative pole, the transport in a basal direction of the physiologically active
auxin anion is accelerated. In this case we could increase the potency of
the standard solutions—that is to say the susceptibility of the plants—to
120,000 million A.U. per gram. On commutation the transport in a basal
direction is inhibited and the susceptibility can be lowered to 10,000 million
A.U. per gram. Finally, we may point out that atmospheric conductibility
in a closed space is also known to be subject to diurnal variations. We may
therefore safely conclude that the normal variations of susceptibility are
also due to changes in the electrical conditions of the air.

It will be the task of the botanists to deduce from these experiments
conclusions concerning the finer mechanism of vegetable tropisms. But
we think that our experiments may also be of interest to medical investi-
gators, especially since the effect of unknown climatic influences on disease
and the unequal distribution of births and deaths during a period of 24 hours
has of late been the subject of renewed discussion. The physician, however,
will have a more difficult task than ourselves, for man is a less suitable ‘ ex-
perimental object ’ than are our seedlings.

Finally, I should like to express my gratitude for the kind invitation to
address the British Association at Leicester on the subject of the auxins.
It has given me great pleasure to accept this invitation, since it offered to
me a welcome opportunity of making the acquaintance of British colleagues.

REFERENCES TO PUBLICATION OF
COMMUNICATIONS TO THE SECTIONS

AND OTHER REFERENCES SUPPLIED BY AUTHORS.

The titles of discussions, or the names of readers of papers in the Sections
(pp. 427-577), as to which publication notes have been supplied, are given
below in alphabetical order under each Section.

References indicated by ‘ cf.’ are to appropriate works quoted by the
authors of papers, not to the papers themselves.

General reference may be made to the issues of Nature (weekly) during
and subsequent to the meeting.

SECTION A.

Astbury, W. T.—WNature, 182, 3337, p. 593, Oct. 14 (1933); to appear
in Phil. Trans. Roy. Soc.; cf. ibid., A, 280, 75 (1931) ; Nature, 126, 913
(1930) ; Fourn. Text. Inst., 218, T17 (1932); Trans. Far. Soc., 29, 193 (1933);
Fourn. Soc. Dyers & Colourists, 49, 168 (1933) ; ‘ Fundamentals of Fibre
Structure ’ (Astbury), O.U.P. (1933).

Bloch, O. F.—Cf. Fourn. Roy. Soc. Arts, 81,'Feb. 3 (1933).

Church, Maj. A. G.—Nature, 182, 3335, p. 502, Sept. 30 (1933).
Cockcroft, Dr. J. D.—Proc. Roy. Soc., 187, p. 229.

Dee, P. I.—Proc. Roy. Soc., A, 141, p. 733 (1933).

Eddington, Sir A.—Times, Sept. 13 (1933).

Franklin, C.H.H.—To appear in Nature; may appear in Journ. Phys. Soc.
Lee, H. W.—Engineering, 186, 3539, p. 533, Nov. 10 (1933).

McCrea, Dr. W. H.—Monthly Notices, R.A.S., 92, pp. 7-12, Nov. (1931).
McVittie, D. G. C_—WMonthly Notices, R.A.S., 92, pp. 7-12, Nov. (1931).

Miller, Prof. Dayton C.—Reviews of Modern Physics, Aug. (1933); short
account to appear in Nature.

Milne, Prof. E. AA—Cf. Nature, July 2 (1932) ; Zeitschr. fiir Astrophys.,
6, p. 1 (1933) ; Monthly Notices, R.A.S., Supp. Notice, 98 (1933).

Oliphant, Dr. M. L.—Proc. Roy. Soc., Sept. (1933) ; Nature, Sept. 16
(1933) ; cf. Proc. Roy. Soc., A, 141, pp. 259 and 722 (1933).

Preston, Dr. R. D.— Nature, 132, 3337, P- 594, Oct. 14 (1933).

Regener, Prof. Dr. E— Nature, 182, 3340, p. 696, Nov. 4 (1933) ; Times,
Sept. 12 (1933); to appear in Zeitschr. fiir Physik.

Rutherford of Nelson, Lord.—Proc. Roy. Soc., Sept. (1933) ; Nature, 182,
3333, P- 432, Sept. 16 (1933) ; Times, Sept. 12 (1933).

Simons, Dr. L.—Proc. Phys. Soc., 45, pt. 2, 247, p. 266, March 1 (1933).

REFERENCES TO PUBLICATIONS, ETC. 611

Smart, E. H.—Proc. Phys. Soc., 45, pt. 2, 247, p. 266, March 1 (1933).
Speakman, Dr. J. B— Nature, 182, 3337, p. 594, Oct. 14 (1933).
Taylor, W.—Engineering, 136, 3539, p. 533, Nov. 10 (1933).

Thewlis, J.—Expected to appear in Brit. Dental Fourn., and Phil. Mag.;
cf. Brit. Journ. Radiol., 5, p. 353 (1932) ; Brit. Dental Fourn., 58, p. 655
(1932) ; Nature, 182, 3337, p. 594, Oct. 14 (1933).

Vegard, Prof. L.—Nature, 182, 3339, p. 682, Oct. 28 (1933) ; Engineering,
186, 3537, p. 470, Oct. 27 (1933); cf. Geophys. Publ. Oslo, 9, 11 (1932) ;
Rae Sept. (1932) ; Geophys. Publ. Oslo, 10, 4 (1933); zbid., 10, 5

1933).
Walton, Dr. E. T. S.—Proc. Roy. Soc., 187, p. 229.

PaPERS IN TECHNICAL Puysics, Af.

Beetlestone, A.— Engineering, 186, 3537, p. 471, Oct. 27 (1933).

Bradley, H.—On ‘ Testing of flexible sheet materials,’ to appear in Journ.
Internat. Soc. Leather Trades’ Chemists, Feb. (1934).

Burch, C. R.—Engineering, 186, 3537, p. 470, Oct. 27 (1933).

Cockcroft, Dr. J. D.—Proc. Roy. Soc., 186, p. 619.

Cramp, Prof. W.—Electrician, 111, 2890, p. 471, Oct. 20 (1933) ; Engineer-
ing, 186, 3537, Pp. 471, Oct. 27 (1933).

Goodlet, B. L..—Engineering, 186, 3537, p. 471, Oct. 27 (1933).

Randall, J. T.— Nature, 182, 3336, p. 574, Oct. 7 (1933); Times, Sept. 12.

Spiers, Dr. C. H.—Leather Trades’ Rev., Oct. 4 (1933) ; may appear in
Journ. Internat. Soc. Leather Trades’ Chemists.

DEPARTMENT A*.
Du Val, Dr. P.—Cf. Journ. Lond. Math. Soc., 8, pp. 11 and 199 ; further
papers to appear in later issues.
Green, H. G.—Cf. Journ. Ecole pu oN 31, Serie II.

Hodge, W. V. D.—Math. Gaz., Jan. (1934) ; Journ. Lond. Math. Soc.,
8, 4; to appear in Proc. Lond. Math. Soc.

Offord, Dr. A. C.—On ‘ Fourier transforms,’ to appear in Proc. Lond,
Math. Soc. On ‘ Hankel transforms,’ may appear in Ann. of Maths.

DEPARTMENT Af.

Best, A. C—May appear as Geophys. Memoir.

Lockyer, Dr. W. J. S—Monthly Notices, R.A.S., 85, p. 580 (1925) ;
ibid., 86, p. 474 (1926) ; ibid., 93, p. 362 (1933) ; ibid., 93, p. 619 (1933).

McVittie, Dr. G. C.—Monthly Notices, R.A.S., 98, pp. 325-339, March
(1933).
SECTION B.
Tanning, discussion ——To appear in Journ. Internat. Soc. Leather Trades’
Chemists, Feb. (1934) ; Engineering, 186, 3539, p. 526, Nov. 10 (1933).
Bergmann, Prof. Dr. M.—¥ourn. Internat. Soc. Leather Trades’ Chemists,

612 REFERENCES TO PUBLICATIONS, ETC.

Oct. (1933); ibid., Feb. (1934); cf. ibid., 244 (1931) and 239 (1931) ;
Naturwissenschaften, 18, 114 (1930) ; Biochem. Zeitschr., 250, 568 (1932).

Butenandt, Prof. A.— Nature, 180, 3276, p. 238, Aug. 13 (1932); Ber. d.
Deutschen chem. Gesellschaft, 66, 601 (1933); Zettschr. fiir physiol. Chem.
(1933); Naturwiss., 49 (1933).

Dodds, Prof. E. C.—Cf, Lancet, 1107 (1928); Biochem. Journ., 22, 6,
1526 (1928) ; Journ. Obstet. & Gynecol. of Brit. Empire, 36, 1 (1929) ;
Journ. Physiol., 68, 4, Jan. 27 (1930); Lancet, p. 683, March 29 (1930) ;
ibid., 1, p. 1390, June 28 (1930) ; Biochem. Fourn., 24, 4, p. 1031 ; Journ.
Obstet. & Gynecol. of Brit. Empire, 37, 3, p. 447; Fourn. Physiol., 88, 2,
Oct. 22 (1931) ; Amer. Fourn. Obstet. & Gynecol., 22, 4, p. 520, Oct. (1931);
Proc. Roy. Soc. Medicine, Jan. 16 (1932) ; Nature, 181, p. 56, Jan. 14 (1933) ;
Naturwissenschaften, Feb. (1933); Journ. Soc. Chem. Industry, 52, 12,
March 24 (1933) ; Chem. & Industry, no. 13, pp. 287-291, March 31 (1933).

Freudenberg, Prof. K.—To appear in Journ. Internat. Soc, Leather Trades’
Chemists, Feb. (1934); cf. ‘Tannin, Cellulose, Lignin’ (Freudenberg),
Springer, Berlin (1933):

Haslewood, G. A. D.—Chem. and Industry, 51, 2777.

Humphreys, Dr. F. E.—To appear in Journ. Internat. Soc. Leather
Trades’ Chemists, Feb. (1934).

Linstead, Dr. R. P.—Expected to appear in extended form in Journ.
Chem. Soc.

Lloyd, Dr. D. Jordan.—To appear in Journ. Internat. Soc. Leather
Trades’ Chemists, Feb. (1934).

Maitland, Dr. P—To appear in Journ. Internat. Soc. Leather Trades’
Chemists, Feb. (1934).

Phillips, Dr. H—To appear in Journ. Internat. Soc. Leather Trades’
Chemists, Feb. (1934) ; cf. ibid., 15, 465 (1931) ; ibid., 16, 345 (1932).

Robertson, Dr. J. M.—Proc. Roy. Soc., A, 140, p. 79 (1933); «bid.,
141, p. 594 (1933) ; and subsequently.

Thompson, F. C.—To appear in Journ. Internat. Soc. Leather Trades’
Chemists, Feb. (1934).

SECTION C.

Dollar, A. T. J.—Geol. Mag., '70, pp. 479-480, Oct. (1933) ; cf. zbid., 69,
pp. 265-268 (1932) ; Report Brit. Assn. (1932).

Eastwood, T.—Colliery Guardian, p. 531, Sept. 22 (1933); cf. Mem.
Geol. Survey (1923, 1925 and 1927).

Jones, Dr. W. R.—Yourn. Hygiene, 38, 3, pp. 307-329, Aug. (1933);
Engineering, 186, 3539, p. 527, Nov. 10 (1933).

®
Section D.

Beadle, L. C.—May appear in a form in Journ. Exp. Biol.; cf.

ibid., 8, 3, p. 211, July (1931).

Bond, Col. C. J.—To appear in Brit. Med. Journ. ; cf. ‘ Genetic Sig-
nificance of Hemilateral Asymmetry in the Vertebrate Organism,’ William
Withering Lecture, Univ. Birmingham (Bond), Lewis & Co. (1932).

Cunningham, J. T.—Proc. Roy. Soc., B, 110 (1932) ; Proc. Zool. Soc.,
Jan. (1933) ; Nature, June 24 and Aug. 12 (1933).

REFERENCES TO PUBLICATIONS, ETC. 613

Deacon, G. E. R.—Work on South Atlantic Ocean in Discovery Reports,
? (1933). Work on whole of Southern Ocean to appear in later volume.

Gates, Prof. R. Ruggles.—Summary to appear in Nature.

Graham, M.—To appear in Fishery Investigations, Series II, either 18,
5, or 14, 2; cf. ibid., 18, 5, or 14, 1.

Heron-Allen, E.—Times, Sept. 8 (1933).

Hurst, Dr. C. C.—Gard. Chron., p. 291, Oct. 14 (1933); cf. ‘ Mechanism
of Creative Evolution’ (Hurst), C.U. Press (1932).

MacLagan, Dr. S.— Scotsman, Sept. 12 (1933); expected to appear in
Proc. Roy. Soc. Edin.

Manton, Dr. Irene.—To appear in Zeitschrift fiir induktiv Abstammungs
und Vererbringslehre.

Roebuck, A.—To appear in British Birds or as bulletin of Midland
Agricultural College ; Lincolnshire section in Trans. Lincs. Naturalists’
Union (1933); cf. British Birds, 27, no. 1, pp. 4-23, June (1933).

Russell, F. S.—Cf. Journ. Marine Biol. Assn., 18-18. One further
paper expected to appear.

Watson, Prof. D. M. S.—Times, Sept. 9 (1933).

Wigglesworth, Dr. V. B.—Cf. Journ. Exp. Biol., 8, pp. 411-451 (1931) ;
Proc. Roy. Soc. B, 109, pp. 354-359 (1931); Quart. Journ. Micr. Scei.,
75, pp. 131-150 (1932) ; fourn. Exp. Biol., 10, pp. 16-26 (1933).

SECTION E.

Clough, Lt.-Col. A. B—May appear in Scot. Geog. Journ.

Dickinson, R. E— Amer. Geog. Rev. (1934) ; cf. ‘ Commercial Functions
of Nuclei of English Conurbations,’ Sociol. Rev. (1929).

Edwards, K. C.—Colliery Guardian, Sept. 29 (1933) ;_ cf. ‘ Luxembourg
Studies,’ Leplay Soc. (1933).

Forde, Prof. C. Daryll—To appear in Scot. Geog. Mag.
Gait, Sir Edward A.—7ourn. Roy. Soc. Aris, Oct. 20 (1933).
Gilbert, E. W.—Expected to appear in Scot. Geog. Mag.
Gimson, M.—Leics. Mercury, Sept. 7 (1933).

Peach, H. H.—Leics. Mercury, Sept. 7 (1933); Leics. Evening Mail,
Sept. 7 (1933); cf. Journ. Roy. Soc. Arts, 78, 4022, Dec. 20 (1929).

Steers, J. A.—Cf. Geophys. Fourn., Jan. (1927); Trans. Norfolk &
Norwich Nat. Hist. Soc., 12 (1925-6); ibid., 18 (1931-2); ‘ Scientific
handbook on Scolt Head Island’ (editor, J. A. Steers), in preparation.

SECTION F.
Florence, Prof. P. S.—Industry Illustrated, Oct. (1933) ; Chap. VII of
‘ Logic of Industrial Organisation ’ (Florence).
Plant, Prof. A.—Financial News, Sept. 9 (1933).
Walker, G.—May appear in Economica ; cf. Econ. Fourn., June (1933):
( ee Sir Arnold T.—Cf. ‘The Suez. Canal’ (Wilson), O.U. Press
1933).

614 REFERENCES TO PUBLICATIONS, ETC.

DEPARTMENT F*,

Annan, Prof. W.—Accountants’ Mag. (Edinburgh), Nov. (1933); cf.
Accountant, Aug. 19 (1933); Proc. Internat. Congress on Accounting
(Knickerbocker Press, New York, 1929) ; Accountants’ Mag., Nov. (1927) ;
tbid., Jan. (1927).

Armstrong, Dr. E. F.—Engineer, p. 254, Sept. 15 (1933).

Crowden, G. P.—Lancet, pp. 665-666, Sept. 16 (1933) ; Industry Illus-
trated, pp. xv-xviii, Sept. (1933); Industrial Welfare & Personnel Manage-
ment, Sept. (1933) ; Electrician, Sept. 22 (1933); Nature, p. 684, Oct. 28
(1933) ; to appear in full in Human Factor.

Neal, L.—Lecture Recorder, 3, 3, Oct. (1933); to appear in Industry
Illustrated ; cf. ‘ Retailing and the public’ (Neal), Allen & Unwin.

de Paula, F. R. M.—Industry IIlus., Sept. (1933); Accountant, Oct. 7
(1933).

Urwick, Maj. L.—Published by Management Library; to appear im

extended form as ‘ Organisation as a technical problem’ (Urwick),
McGraw Hill.

SECTION G.

Adeney, Prof. W. E.—Engineering, 186, 3532, p- 339, Sept. 22 (1933) ;
ibid., 136, 3535, Pp. 423, Oct. 13 (1933).

Arnold, R. N.—Engineering, 186, 3535, p. 417, Oct. 13 (1933) ; Engineer,
p. 314, Sept. 29 (1933).
Atter, H. F.—Engineering, 186, 3532, p. 339, Sept. 22 (1933).

Capon, R. S.—Engineering, 186, 3537, p. 475, Oct. 27 (1933) ; Engineer,
Pp. 255, Sept. 15 (1933).

Chamberlain, J.—Engineering, 186, 3530, Sept. 8 (1933); Engineer,
Pp. 254, Sept. 15 (1933).

Du-Plat-Taylor, M.—Engineering, 186, 3533, p. 372, Sept. 22 (1933) ;
ibid., 186, 3533, p- 369, Sept. 29 (1933) ;_ cf. ‘ Reclamation of land from sea’
(Du-Plat-Taylor), Constable (1930).

Gouldbourn, J.—Privately printed; Engineering, 186, 3533, p. 368,
Sept. 29 (1933).

Haworth, J.—Engineering, 186, 3531, p. 284, Sept. 15 (1933); zbid.,
186, 3532, p. 340, Sept. 22 (1933).

Leonard, Dr. A. G. G.—Engineering, 186, 3532, p. 339, Sept. 22 (1933) ;
ibid., 186, 3535, p. 423, Oct. 13 (1933).

_ Lupton, H, R.—Engineering, 186, 3532, p. 340, Sept. 22 (1933), and later
issue.

_ McKay, A. M.—Engineering, 186, 3535, p. 417, Oct. 13 (1933) ; and later
issue ; Engineer, p. 314, Sept. 29 (1933).

Maughan, W.—Engineering, 186, 3533; p. 368, Sept. 29 (1933) ; Daily
Express, Sept. 13 (1933).

Taylor, W.—Engineer, p. 254, Sept. 15 (1933).

Vokes, F. C.—Engineering, 186, 3531, p. 317, Sept. 15 (1933); zbid.,
136, 3532, p. 340, Sept. 20 (1933) ; Surveyor, Sept. 22 (1933); cf. Proc.
Inst. C.E., 226, pt. 2, paper no. 4660 (1927-8) ; World Power, April (1933).

REFERENCES TO PUBLICATIONS, ETC. 615

Walker, Prof. Miles.—Engineering, 186, 3532, p. 326, Sept. 22 (1933);
Modern Transport, 80, 757, p. 5, Sept. 16 (1933) ; Engineer, p. 292, Sept. 22
(1933).

Watson, J. D.— Engineering, 186, 3531, p. 283, Sept. 15 (1933); ibid.,
136, 3532, p. 339, Sept. 22 (1933).

Wilson, W.—To appear in Engineering ; Engineer, p. 255, Sept. 15 (1933).

SECTION H.

Cardinall, A. W.—Cf. ‘ Nations of Northern Territories of Gold Coast ’
(Cardinall, 1920); ‘In Ashanti and Beyond’ (Cardinall, 1927); ‘ Tales
Told in Togoland ’ (Cardinall, 1931) ; ‘ The Gold Coast, 1931 ’ (Cardinal,
1932).

Childe, Prof. V. Gordon.—To appear in extenso in Ancient Egypt and the
East ; summary to appear in Nature.

Davies, O.—To be extended in book form; cf. ‘ Roman and Medieval
Mining,’ Trans. Inst. Mining and Metall. (1933-4).

Dollar, A. T. J—Man, 38, p. 166, Oct. (1933); Ilfracombe Chron.,
Sept. 15 (1933).

Evans-Pritchard, Prof. E. E—To appear in Man.

Forde, Prof. C. Daryll—Summary to appear in Man; cf. ‘Ethnography
of the Yuma Indians ’ (Forde), Univ. California Press (1931).

Fox, Dr. C.—Cf. ‘ Personality of Britain: Its Influence on Inhabitant
and Invader in Prehistoric and Early Historic Times ’ (Fox), Nat. Museum
of Wales.

Gates, Prof. R. Ruggles.—Yourn. Roy. Anthrop. Inst., Jan. (1934).

Hornell, J—To appear in Journ. Roy. Anthrop. Inst. ; cf. Man, §5 (1919) ;
tbid., 67 (1920) ; Mariner’s Mirror, 19, pp. 439-445 (1933):

Hutton, Dr. J. H—Summary to appear in Nature; may appear in
Current Science (Bangalore).

Jackson, K. H.—In part in Bull. Board of Celtic Studies, Nov. (1933) 3
remainder expected to appear in Man.

Nadel, Dr. S. F.—Cf. Musical Quarterly (New York), 16 (1930);
Erdball (Berlin) (1931) ; Zettschr. Wien Akad. Wissensch. (1931); ‘ Georg-
ische Gesinge’ (Nadel), Lautabteilung, Berlin (1933); ‘ Messungen an
Raukasischen Grifflochpfeifen ’ (Nadel), Anthropos (1934).

Palmer, Sir Richmond.—May appear in Journ. Roy. Anthrop. Inst.

Pokorny, Prof. J.—Zeitschr. fiir celtische Philologie, 20 (1933) ; to appear
in Journ. Roy. Anthrop. Inst.

Rattray, Dr. R. S.—Times, Sept. 12 (1933).

Roth, G. K.—Man, 170, Oct. (1933) ; expected to appear in detail in
Journ. Roy. Anthrop. Inst.; cf. Man (1933), articles no. 49, 67 and 167.

SEcTION I.
Bedford, Dr. T.—To appear in Journ. of Hygiene.

_ Burn, Prof. J. H.—Cf. Quart. Journ. Pharm. Pharmacol., 2, 187 (1930) ;
Journ. Pharmacol. Exp. Ther., 46, 75 (1932); Journ. Physiol., '75, 144

(1932).

616 REFERENCES TO PUBLICATIONS, ETC.

Dufton, A. F.—To appear in Journ. of Hygiene.

Edridge-Green, Dr. F. W.—CE. ‘ Physiology of Vision ’ (Edridge-Green,
1920) ; ‘ Science and Pseudo-Science ’ (Edridge-Green, 1933).

Feldberg, Dr. W.—¥ourn. Physiol., Nov. 18 (1933) ; in part in Pfliigers
Archiv, 23, remainder to appear in Journ. Physiol.

Harris, Dr. L. J.—Cf. Science Progress, 18, 68 (1928) ; Lancet, 1, 1031
(1932) ; Biochem. Fourn., 28, 206 (1929) ; ibid., 25, 367 (1931).

Hunter, Dr. D.—Cf. Lancet, 1, 897, 947, 999 (1930) ; Brit. Journ. Surg.,
19, 203 (1931-2).

Kay, Dr, H. D.—Cf. Physiol. Rev., 12, pp. 384-422 (1932); Fourn.
Nutrition, 6, pp. 313-324 (1933).

Robison, Prof. R.—Cf. work to appear in Biochem. fourn.; ‘ Herter
Lectures ’ (Robison), New York Univ. Press (1932).

SECTION J.

Correlation, discussion on methods.—Nature, Oct. 21 (1933).

Balchin, N. M.—Journ. Nat. Inst. Indust. Psych. ; Industry Illus.

Brown, Dr. W.—On ‘ Personal Influence,’ Brit. Med. Fourn., Sept. 16
(1933).

Cattell, Dr, R. B.— Brit. Journ. Psych., Jan. and July (1933).

Creed, Dr. R. S.—Expected to appear in Nature.

Hurst, Dr. C. C.—Eugenics Rev., Jan. or April (1934) ; cf. Proc. Roy.
Soc., B, 112 (1932).

Piaggio, Prof. H. T. H.—To appear in extended form in Brit. Journ.
Psych. ; Nature, Oct. 21 (1933); cf. Brit. Journ. Psych., 24, 88, July (1933).

Rodger, A.—-fourn. Nat. Inst. Indust. Psych., Feb. (1934); cf. Brit.
Journ. Educ. Psych., 8, 2, June (1933).

Shaw, Miss A. G.—Labour Management, Oct. (1933) ; Engineer, p. 254,
Sept. 15 (1933).

Tolman, Prof. E. C.—Cf. Psych. Rev., 40, pp. 60-70, Jan. (1933) ; ibid.,
40, pp. 246-255, May (1933); Univ. Calif. Publ. Psych., 4, 5, pp. 71-89,
Sept. (1929).

Thouless, Dr. R. H.—Expected to appear in Brit. Journ. Psych.; cf.
ibid., 21, pp. 339-359 ; 22, pp. 1-30; 22, pp. 216-241.

Valentine, Prof. C. W.—To be embodied in book yet to be published.

Vernon, Miss M.D.—Expected to appear in Brit. Journ. Psych. (1934).

Vernon, Dr. P. E.—Psych. Rev., 40 (1933); cf. Eugenics Rev., 28,
PP. 325-331 (1932).

Wishart, Dr. J —Cf. Brit. fourn. Psych., 19, pp. 180-187 (1928).

Wright, Dr. G. G. Neill —To appear as_part of ‘Society and the Human
Mind’ (Wright).

SECTION K.

Ball, Prof. N. G.—Expected to appear in New Phytologist ; cf. bid., be
p. 13 (1932).
Barnes, Dr. B.—Cf. Trans. Brit. Mycological Soc., 17, p. 82 (1932).

REFERENCES TO PUBLICATIONS, ETC. 617

Chattaway, Miss M. M.—To appear in Forestry ; cf. New Phytologist,
$1, 119 (1932).

Cromwell, Dr. B. T.—Biochem. Fourn., 27, 3, pp. 860-872 (1933).

Fisher, Prof. R. A.—To appear in Ann. Bot.

Gwynne-Vaughan, Prof. Dame Helen.—-Amn. Bot., 48, Jan. (1934).

Hyde, F. F—May appear in New Phytologist or Ann. Bot. ; cf. Analyst,
P- 523, Sept. (1933).

Matthews, Prof. J. R.—Cf. Ann. Bot. (1923, 1924, 1926).

Seward, Prof. A. C-——Expected to appear in Ann. Bot.

Thomas, Dr. H. Hamshaw.—To appear in New Phytologist (1934).

Thompson, Prof. J. McLean.—Publications of Hartley Bot. Labs., 11,
Univ. Press, Liverpool, Oct. (1933).

Went, Prof. F. A. F. C.—Nature, 182, 3333, p. 454, Sept. 16 (1933).
Williamson, Mrs. H. S.—Ann. Bot., 48, Jan. (1934).

DEPARTMENT K*,
Coke, Maj. the Hon. R.—Expected to appear in Journ. Roy. Scot. For.
Soc.; Journ. Roy. Engl. For. Soc., Jan. (1934).
Long, A. P.—Expected to appear in Quart. Journ. Forestry, Jan. (1934).

Mundt, H.—Expected to appear in Scot. Forestry Journ. ; cf. Communica-
tions from Congress of Nancy, pp. 326-347 (Internat. Union Inst. For. Res. ;
1932).

Orde-Powlett, Hon. N. A.—To appear in Journ. Roy. Scot. Geog. Soc.

Pratt, Lt.-Col. E—Quart. Journ. Forestry, Jan. (1934) ; cf. back numbers
of Fourn. Roy. Agric. Soc., and Estate Mag.

Rayner, Dr. M. C.—To appear in Journ. of Ecology; cf. Forestry, 3,
p. 26 (1929) ; ibid., 4, p. 65 (1930) ; Empire For. Fourn., 9, p. 182 (1930) ;
Reports of B.A. Cttee. on Mycorrhiza (1930, 1931, 1932).

Robertson, W. A.—Timber Trades Fourn., Sept. 23 (1933) ; to appear in
Journ. Scot. For. Soc.

SEcTION L.

Examinations and psychological tests, discussion.—Yourn. Educ., p. 666,
Oct. (1933).

Barraclough, F.—Fourn. Educ., Oct. and Noy. (1933); Schoolmaster,
Sept. 21 (1933).

Brierley, Prof. W. B.—Yourn. Educ., Nov. (1933) ; may appear in Nature.

Chamberlain, J —Hosiery Trade Fourn., Oct. (1933).

Cornish, Dr. V.—Fourn. Educ., Nov. (1933) ; may appear in Nature.

Dale, Miss A. B—May appear in Journ. Educ. Psych.

Farmer, E.—To appear in Brit. Journ. Educ. Psych.

Ferguson, Dr. A.—Yourn. Educ., Nov. (1933) ; may appear in Nature.

Gregory, Sir R.—¥ourn. Educ., Nov. (1933) ; may appear in Nature.

Lawe, F. W.—Expected to appear in Journ. Nat. Inst. Indust. Psych.,
Industry Illus., Journ. of Careers.
Y

618 REFERENCES TO PUBLICATIONS, ETC.

Lewis, E. 1.—Financial News, Sept. 11 (1933); cf.‘ Making of a Chemical’
(Lewis), Benn (1927).

McWilliam, A. S.—High Peak News, Sept. 23 (1933); cf. Derbyshire
Farmer (1932) ; Annual Reports, Rothamsted Experimental Station.

Myres, Prof. J. L.—Fourn. Educ., Nov. (1933) ; may appear in Nature.

Oates, Dr. D. W.—To appear in Journ. Educ. Psych.; cf. Brit. Journ.
Psych., 19, 1, pp. 1-30; Forum of Educ.,'7, pp. 171-185 ; Journ. Educ.,
Aug. (1029).

Pugh, Prof. W. J.—Yourn. Educ., Nov. (1933) ; may appear in Nature.

Salt, H.—Shoe and Leather Record, Sept. 15 (1933); Shoe and Leather

News, Sept. 14 (1933) ; expected to appear in Fourn. Shoe Manufrs. Fedn.
or Journ. Nat. Inst. Boot and Shoe Industry.

Sandon, F.—Yourn. Educ., 65, 771, p. 666, Oct. (1933); cf. Forum of
Educ., 2, p. 29 (1924) ; ibid., 4, p. 223 (1926) ; ibid., 8, p. 24 (1925) ; Math.
Gazette, May (1926); Forum of Educ., 6, p. 270, Nov. (1928) ; ibid., 7,
p. 23, Feb. (1929); Brit. Journ. Educ. Psych., 1, 3, p. 296, Nov. (1931) ;
ibid., 3, 3, p. 269, Nov. (1933).

Valentine, Prof. C. W.—Cf. ‘ The Reliability of Examinations’ (Valentine),
Univ. Lond. Press (1932).

Wickens, G. C——Supplement to Counter Clerk (Assoc. Counter Clerks
and Telegraphists) ; Yourn. Inst. Public Admin. ; supplement to Post Year
Book (Union Post Office Workers).

SecTIoN M.
Ashby, Prof. A. W.—Expected to appear in Welsh Journ. Agric., 10
1934); cf. Scot. fourn. Agric., 8, 2 (1925).

Astill, Ald. P. F—Bull. 10, Imp. Bureau of Plant Genetics : Herbage
Plants, Sept. (1933).

Blackaby, J. H.—To appear in Engineering ; cf. ‘ Technical Notes on
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Research Agric. Eng. (1932).

Blackwood, Dr. Janet H.—Cf. Bulletin 5, Hannah Dairy Res. Inst., Feb.
1933):

Bridges, A.—Bull. 10, Imp. Bureau of Plant Genetics : Herbage Plants,
Sept. (1933).

Davies, B.—Times, Sept. 13 (1933) ; N. Wales Observer, Oct. 5 gah}

Davies, W.—Bull. 10, Imp. Bureau of Plant Genetics : Herbage Plants,
Sept. (1933).

Dobson, A. 'T. A.—Times, Sept. 9 (1933).

Godden, W.—Cf. Bulletin 5, Hannah Dairy Res. Inst., Feb. (1933).

Jones, M. G.—Bull. 10, Imp. Bureau of Plant Genetics : Herbage Plants,
Sept. (1933).

Kay, Dr. H. D.—In part in Journ. Dairy ‘Riese siDsnne(@g38)-

Orwin, C. S.—To be incorporated in book (1934).

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Organisation, League of Nations, 1, no. 4, p. 664 (1932).

Wright, Dr. N. C. Scot. Ph on Agric., Jan. (1934).
wt te &

ee

APPENDIX

A
SCIENTIFIC SURVEY
OF

LEICESTER

AND DISTRICT

PREPARED FOR
THE LEICESTER MEETING

#955

BY VARIOUS AUTHORS

EDITED BY

P. W. BRYAN, Ph.D., B.Sc.+(Econ.)

Vice-Principal, University College, Leicester

CONTENTS.

PAGE

I.—Leicester in its Regional Setting. By P. W. BRYAN ........ ‘

Ii—Geology:, By Tiwi. GREGORY 3... ga4)« «fas Rsyoeusoe quate teas 17

III.—The Flora of Leicestershire. By A. R. HoRwoop.......... 25
IV.—The Zoology of Leicestershire. By E. E. Lowe, W.E. Mayes,

RSWAcsrarrEyand S:.O., FAYLOR: | ..c's ocesutemeeies 33

V.—tThe Climate of Leicestershire. By E.G. BILHAM ........ 40

VI—Farming in Leicestershire. By 'THomaS HACKING ........ 48
ViI.—The Industries of Leicester. By L. W. KersHaw, F. R.
ANTCLIFF, J. CHAMBERLAIN, J. P. IvEeNs, and F. W.

ROBERTS) ole. eae PRIOR Aceh ts aie. os Sains area eee on ERRNO 60

VIII.—Municipal Activities of Leicester. By H. A. PRITCHARD .... 72
TX.—Education in Leicester. By F. P. ARMITAGE .............. 80

X.—Men of Science in Leicester and Leicestershire. By F. B.
OTT it fy: Werte. tre. eeMetees talons tes sek, « 0 eh cae ee reaae 84.

A SCIENTIFIC SURVEY OF
LEICESTER AND DISTRICT

Ih
LEICESTER IN ITS REGIONAL SETTING

BY
P. W. BRYAN, Ph.D., B.Sc. (Econ.),
VICE-PRINCIPAL, UNIVERSITY COLLEGE, LEICESTER.

Definition of ‘ District ’—Cultural and Natural Landscape—Satisfaction of Man’s
Desires in the Leicester Region—General Topography and Geology—The
Grasslands—Cultural Forms of—Water Supply of—Market Harborough
Area—Hunting—Upland Grasslands—Cultural Forms of—Physical Setting
of—Vale of Belvoir—Cheese-making—Wold Country—Melton Mowbray
Area—Keuper Marl Grassland—Arable Land in the North-east—Iron Ore
Workings—Ironworks at Asfordby—Leicestershire | Coalfield— Cultural
Forms of—Physical Setting of—Charnwood Forest Area—Relief and
Structure of—Formation of—Quarries of—Leicester—Site of—Roman
Roads—Expansion of City—Different Areas in the City—Manufacturing
Activities—Communications of the Region—Conclusion.

THE region of which Leicester is the focal point exhibits, to a greater
degree perhaps than any other area of the East Midlands, diversity in
unity. The keynote of this diversity is found in the differing ways in
which man has here adapted to serve his needs differing physical settings.
The city of Leicester, functioning as the chief focal point—the principal
collecting, distributing and organisation centre—for a series of districts
located in the vicinity, is the chief unifying force operating in the area.
Before examining these districts with a view to discovering their chief
characteristics and their relationships to the city it may be well to define
what we have in mind by the term ‘ district.’ It is here used to denote
an area in which there is a combination or grouping of a series of more or
less related phenomena which tend to repeat themselves throughout the
area. It may beasked, What phenomena? It is assumed that the pheno-
mena referred to are those connected with man’s utilisation of the physical
setting in which he lives to satisfy his desires. ‘The phenomena therefore
are of two main kinds—those which make up the physical setting or

4 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

natural landscape, and those which constitute the cultural landscape or
natural landscape as modified by man. The motivating force effecting
this modification is taken to be the effort of man to satisfy his desires.

Man desires beef and milk. He uses the extensive grasslands of the
Leicester area to raise cattle and sheep. He desires cereals and potatoes.
The lighter and better-drained limestone and sandstone soils of the north-
eastern part of the county provide him with a suitable area for tillage.
He needs to transport his products. In the quarries of the Charnwood
Forest and elsewhere he finds excellent road metal to surface his roads.
He desires buildings to house and shelter his activities and their resulting
products. In the marlstone at Scalford, the limestone at Croxton, and
the clays of the lower grounds he finds material for his houses and villages.
He needs factories in towns and cities in which to shape his products into
articles suitable for consumption. In Leicester he takes leather and wool
and fashions them into boots and hosiery with the aid of organisation,
capital, labour, and coal from the nearby coalfield. The cities and towns
require municipal government and the performance of social services for
their inhabitants. Man erects suitable buildings to house these activities,
constructs waterworks and power stations, and organises government.
He needs recreation. He takes waste areas and converts them into the
numerous playing fields, golf courses, parks and open spaces to be found
in the city and countryside. He desires to gratify his esthetic senses and
preserve some of the beauties and amenities of the countryside for present
and future use. He sets aside, as at Bradgate Park and Swithland Wood,
beautiful scenic areas in which town and country dwellers may enjoy
nature unspoilt. ‘Through scientific methods of cultivation and produc-
tion applied to his natural surroundings he obtains surpluses which he
exchanges for commodities from other areas. In this fashion Leicester-
shire beef, milk and cheese, hosiery, boots and engineering products pro-
cure for the country and town dweller the surpluses of other regions.

These are only some of the chief relationships which exist between
man and nature in the Leicester region. In all these activities man in the
Leicester region makes use of his environment. His activities change
from place to place throughout the region with changes in the natural
environment. In each district man moulds the face of nature, and his
activities are in turn moulded and modified by it. In this general geo-
graphical survey we can only touch briefly on the chief districts, with
some of the cultural and natural phenomena related to man’s activities,
which fall within the Leicester region.

Although from the writer’s point of view the most satisfactory approach
to the study of a region is through an examination of the human activities
in the area, it may be more helpful for the general reader to have before
him a brief description of the region from the topographical and geological
standpoints. :

The city of Leicester is situated near the centre of the county, on the
river Soar. This valley is the central topographical feature of the region.
It runs roughly south-north, bending eastward in a flat bow to avoid the
ancient rocky masses of the Charnwood Forest. Some miles north of the
city the river Wreake enters the Soar at a right angle from the north-east.

LEICESTER IN ITS REGIONAL SETTING

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[- -] Txwtw YFSIM N UINYE HD y

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DISAII/F7 TAIVHOSINA OW
WEHINISSA AITOVYM PNQUSTHY VW Uszy0y NOIDxsv’ag
FIV7WL = SONU ISSUYD DNYTIN a ld Bg Le JOOMNY YHD G7F/A THO)
‘3° MN =) M

6 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

These two valleys with their adjacent lowlands divide the region into
three regions of upland—the Charnian mass to the west, the Melton Ridge
to the north-east, and the Jurassic uplands to the east. Along the river
valleys, between the river valleys and the uplands, and, in some cases,
surrounding, penetrating, and overriding the uplands, are the great grass-
lands for which Leicestershire has become justly famed. 'To west of the
Charnwood Forest the low ground is occupied by the Leicestershire
coalfield stretching north-westward towards Burton. 'To the extreme
south-east around the headwaters of the river Welland lie the rich
grasslands of Market Harborough.

Broadly speaking, the underlying structure of the region is a fairly simple
arrangement of clays, marlstones, sandstones, and limestones running in
bands from south-west to north-east and dipping eastward. ‘They are
mostly of Triassic, Jurassic, and more recent origin. ‘To west of the Soar
valley, projecting through these younger rocks, are the coal measures form-
ing the Leicestershire coalfield, and the ancient volcanic materials of
which the rocky peaks and ridges of the Charnwood area are formed.
These older materials have been partly buried in the marls of Triassic age.
To east of the river Soar a low escarpment of limestone (Rhetic) forms
the high ground overlooking the city. ‘To east of it a long sweep of clay
country (the Lower Lias) rises to the foot of the marlstone escarpment,
beyond which lie the grassland uplands capped with clays. This marl-
stone country also forms the Melton Ridge whose escarpment looks down
steeply on to the clay-covered grasslands of the Vale of Belvoir. The
eastern part of the Jurassic uplands round Uppingham is capped with
Northampton sandstone, while the eastern part of the Melton Ridge is
capped partly with the Northampton sandstone and partly with the Lincoln-
shire limestone. From the standpoint of soils the position is complicated
by widespread deposits of chalky boulder clay. This occupies the surface
of much of the Melton Ridge, the Jurassic uplands, and the lowlands
between the river flood plains and the upland edges.

In our brief survey of the districts which make up the Leicester region
we may usefully begin with the grasslands. Our justification may be that
out of the land available for crops and grazing in the county approximately
five-sixths is under grass, some of which is claimed to be the best grassland
in England. As nearly two-thirds of the value of English agricultural
produce is derived from grassland farming, the importance of Leicester-
shire in this connection will be realised. ‘The Leicestershire farmer
contributes largely to the milk, cheese, beef and mutton supply of England.
The Leicestershire grassland is a perennial resource which does not
become exhausted as does land under crops, nor worked out as do areas
from which minerals are obtained. Its fertility is maintained through
the droppings of the live stock coupled with a winter rest period. Efforts
are, however, being made to increase its yield. Experiments show that
under favourable conditions grassland yield can be increased up to
50 per cent. with modern methods. The development of better types of
grass, the application of fertiliser, and even simple harrowing, all help to
increase the yield.

As we have already seen, the Vale of Belvoir to north of the Melton

LEICESTER IN ITS REGIONAL SETTING if

Ridge, the Wreake valley to the south of it, the Soar valley in the centre
of the county, the country to south of the Charnwood, and the district
around Market Harborough on the headwaters of the Welland are all
lowland grasslands. ‘They possess certain features in common, and certain
other features which differentiate them. ‘These features are in part due
to the physical circumstances, chiefly the soils, and in part to man. ‘The
soils are chiefly alluviums, heavy clays, or clayey loams. The clays and
loams are mainly derived to west of the river Soar from the Keuper marl
and boulder clay ; to east of the river from the lower and middle Lias and
the chalky boulder clay. ‘The upland grassland to east of the marlstone
escarpment is capped with boulder clay and the upper Lias clay. Under
the influence of the differing soils resulting from these different formations
and of variations in the topography, the human activities of these grass-
lands and the minor cultural forms tend to vary.

The main cultural forms of the grassland are the grass fields with their
herds of cattle and sheep, the farmsteads and the scattered houses of the
herdsmen, the well-cared-for whitethorn hedges, the broad road spaces
with their wide grass margins, the scattered villages usually smaller than
those of the tilled country, and the prevalence of brick as a building
material. Minor forms are the small red boards warning huntsmen of
the presence of wire in the fences, and in the milk country the milk-cans
are to be seen at the roadside either on the ground or on small platforms
waiting collection by the milk lorries. Where tillage has given place to
grassland, as in much of the chalky boulder clay country, the ridges and
furrows of the old drainage system are characteristic. Along the river
valleys the alluvial lands are subject to periodical flooding. This flooding
keeps the land well watered and helps to renew its fertility while rendering
it useless for crops. Raised footpaths on wood or iron posts are common
in the flood plains of these valleys.

On the slightly higher grasslands above flood-plain level the numerous
brooks and rivulets are evidence of a high water table. They ensure the
land being well watered. There are some 600 of these in the county.
In the areas of ridge and furrow which give alternate belts of drier and
wetter land there is always, even in the driest summer, some moist herbage
in the furrows. ‘This is of considerable importance to the Leicestershire
grasslands, as the county lies in that part of Great Britain which has the
most Continental type of climate.

Of the subdivisions of the grasslands those around Market Harborough
near the headstreams of the Welland and those along the flood plain of
the river Soar are probably the richest. In the Market Harborough dis-
trict the soils are mostly heavy clays or medium loams. In many parts of
the district neither cake nor fertiliser is used ; the droppings of the live
stock evenly spread and well trampled are adequate to maintain these
lands in high condition for finishing full-grown cattle without making
undue demands on the plant food in the soil. ‘They can feed one bullock
or twenty sheep to the acre, and it is said that a bullock gains in weight
about 2 lb. per day on these untreated lands. As is pointed out by
Mr. Hacking in his chapter on ‘ Agriculture’ in this survey, grassland
management is here carried to a fine pitch. From this district beef and

8 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

mutton of the very best quality are sent to market. ‘The numerous dairy
herds to be seen in the fields also indicate that milk, while a secondary
product in this district, is none the less produced on a fairly large scale.

Market Harborough is one of the chief hunting centres of the Midland
clay vales, and therefore one of the chief hunting centres of England. In
the grassland, except for dairy work, there is little to be done during the
winter. Where finishing beef cattle is the main activity the cattle are
usually bought in the spring, fattened on the grassland during the summer,
and sold in the autumn. During the winter the grassland rests, and the
beef farmer is largely free for hunting. ‘The undulating grassland, with
its stiff fences, lying between the river flood plains and the uplands, and
the sharply dissected plateau country of the upland grassland, both form
ideal hunting country which makes stern demands on men and horses.
Its value for hunting is enhanced by the absence of tillage and the relative
absence of live stock in the fields during the winter. In addition to the
Market Harborough country, that around Melton Mowbray, and the Vale
of Catmose in the eastern part of the area, are famous hunting centres, and
it is here that we find the Quorn, the Cottesmore hunt, the Belvoir, and
the Pytchley—all names famous in the annals of the chase.

North of Market Harborough and east of Leicester the country rises
in a series of long grass-covered slopes to the clay-topped marlstone
plateaux forming the upland grassland. In this grassland we have clearly
marked that grouping and repetition of phenomena which we have assumed
above to be the hallmark of a district. Its eastward boundary is Wardley
Hill, near Uppingham. Within the district, with the exception of a few
small and poor-looking villages, the distribution of buildings is of the
dispersed type. Numerous hedges divide the area into grass fields with
small farms and their associated buildings dotted about in the grassland.
A few arable fields are to be seen, but they merely serve to emphasise the
widespread dominance of grass. With the exception of one or two main
roads, the roads up to a few years ago were poor and narrow. ‘To-day
many of these side-roads are surfaced with tarmac. By the roadside on
small platforms we see milk-cans. Cattle and some sheep are in the fields.
Should we pass in the winter we may see fox-hunting in full swing. We
are in the country of the Quorn and the Fernie. Over a distance of
eight or ten miles from Houghton-on-the-Hill to Wardley Hill we observe
a repetition of the same elements of human occupancy—small farms, small
houses for the herdsmen, grassfields, well-cut hedges, poor narrow side-
roads—mostly gated,—one great main road, the milk-cans and their plat-
forms, the milk lorries on the road, the small villages, the live stock in the
fields, and the scattered population. It is clear that the people are mainly
concerned with the tending of live stock, chiefly cattle, partly for beef,
but mainly for milk, with sheep herding as a lesser activity.

The above forms of the cultural landscape concretely express man’s
relationship to the physical setting of these uplands. ‘This physical
setting is clear-cut and definite. It consists in the main of a repetition of
simple topographical and structural elements. A series of gently undulat-
ing clay-covered marlstone plateau tops are deeply dissected by sharply
cut little stream valleys with clay floors and marlstone slopes. Of these

LEICESTER IN ITS REGIONAL SETTING 9

stream valleys that of the Eye Brook is the largest. The rock layers are
nearly horizontal. The weathering is typical of conditions in a relatively
wet area on rocks of varying resistances. Although capable of growing
corn, as is evidenced by the ridge and furrow in many of the fields, the
elevation of the district, from 500 to 750 ft. above sea-level, together
with the clay covering, make it unsuitable for cultivation with agricultural
prices at their present levels. The district is thus for practical purposes
an upland extension of the great grass vales of the Midlands. The
poorer soils and the more severe climatic conditions make it less rich
than the vales. As we have seen, it specialises in milk rather than beef,
its holdings are smaller, its villages are poorer, and it contrasts sharply
with the richer and more varied land, with its larger farms and more
prosperous-looking villages, on the mixed soils and rock outcrops of
Rutlandshire beyond Wardley Hill.

At the other subdivisions of the grassland we can only briefly glance.
In the Vale of Belvoir to north of the Melton Ridge the clay soil is derived
from the lower Lias. Here again we have the grazing of cattle and sheep,
but there is a distinct tendency to specialise in the production of milk and
the Stilton cheese for which the district has become famous. As far back
as 1790, William Marshall, who was probably the first ecologist in this
country, studied soils and the cultivation of grasses in this county from the
standpoint of cheese-making. At Long Clawson, north of the Melton
Ridge, there is a co-operative factory engaged in cheese-making. The
boulder clay-covered Wold country to north-west and to west of the Melton
Ridge, around Six Hills on the Foss Way, is a western extension of the Vale
of Belvoir grass country. The grassland here is only of moderate quality,
particularly where the boulder clay tends to be of a sandy or gravelly type.
It makes cheese, produces milk and raises young sheep and stock. In
the Melton Mowbray district to south of the ridge there is excellent grazing
land, partly in the river flood plain and partly on the clay-covered land
sloping up on the one side to the Melton Ridge and on the other to the
upland grasslands of eastern Leicestershire. In the area south of the
Charnwood and west of the river Soar, although the majority of the farms
are devoted to milk production, the farming, owing to the presence of the
Keuper marl with patches of sands and gravels of glacial and Triassic age,
tends to be of a more mixed type. Stock is raised, and the lighter soils
are devoted to such crops as wheat, oats, barley, beans, sugar-beet and
mangolds.

The chief area of cultivation in the Leicester region lies north-east of
Melton Mowbray. It is found in the district extending from Scalford to
Knipton and Croxton on the soils derived from the marlstone, the
Northampton sands and the Lincolnshire limestone. The relationship
between human activities and soils is very clearly marked here. Running
northward from Melton to Scalford we are on a sheet of chalky boulder
clay, the heavier parts of which are under grass, while the lighter soils are
tilled. Beyond Scalford we enter the marlstone rock bed. Here most
of the surface is under the plough for wheat, beet, or oats. The marlstone
soil is fertile, light and easily tilled. Between Knipton and Croxton a belt
of the upper Lias clay crops out, forming a zone of pasture land lying

10 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

between the arable land below on the marlstone and the cultivation above
on the limestone and sand.

Throughout much of this district the fields lie definitely below the level
of the road. ‘This is an indication of the working of the area to recover the
iron ore present in the marlstone and in the Northampton sandstone.
The ore bed, which may be up to 14 ft. in thickness, lies from a few feet
down to 18 ft. below the surface. It is readily worked, in long narrow
strips, by removing the surface cover, transferring the cover to the other
side of the strip, calcining the ore on the spot, and shipping after about
eight weeks, the time needed for calcining. In this fashion the agricul-
tural land is preserved. It is claimed that its fertility is actually increased.
The general level of the land is reduced by the approximate thickness of
the ore bed, though the amount of settling varies with the nature of the
material forming the cover. Within our region the chief workings in
operation are at Holwell, Buckminster, Branston, Knipton, Croxton,
Eastwell, and Stainby to north and north-east of Melton, and at Tilton
in the grassland uplands to east of Leicester. Many other workings, as at
Corby, to east of our area exist. Much of the ore worked in the Leicester
area goes to the furnaces at Asfordby near Melton. Here pig iron is pro-
duced and is made into castings and piping, Although some of the ores
are markedly calcareous, additional limestone for fluxing purposes is
obtained from the Lincolnshire limestone. Coke comes from Yorkshire,
and sand for moulds from the Bunter deposits near Nottingham. Since
approximately nine-tenths of the British output of iron ore comes from
the Northampton Sand and the Middle Lias, these workings are of great
interest. ‘This interest is enhanced by the fact that the ironworks and
also the iron workings are set in the midst of a fertile agricultural area and
do a minimum of damage to the agricultural resources of that area.

Although there is little commercial connection between the iron work-
ings and the Leicestershire coalfield, we may next glance at its main
features. Standing on Bardon Hill, the highest summit of the Charn-
wood Forest, we look out westward over a landscape which contrasts
sharply with that of the rest of our region. At our feet a steep slope runs
down to the lowland. This lowland is studded with the pithead gears of
the collieries and the long lines of the miners’ dwellings. These are
clearly visible round Coalville and vanish into the distance towards
Ashby, Donisthorpe, Swadlincote, and Burton. ‘To southward the pit-
head gears become fewer and give place to pasture land. The towns are
small, being little better than small market towns or overgrown villages,
for there is no large scale manufacturing industry here. The towns and
villages are mainly marketing centres and dwelling places for the miners,
together with those engaging in a few subsidiary and minor activities.
The coal raised is of a quality mainly suited for household purposes,
and moves out of the district for consumption elsewhere. The few
industries, other than coal mining, are largely connected with the suitability

of the coal-measure clays for the manufacture of drain-pipes, saggars, and
firebricks.

1 The sandstone ore is calcined on the spot to save the cost of carriage and
fuelin the furnaces. The marlstone ore is not calcined at the quarries.

LEICESTER IN ITS REGIONAL SETTING II

Below the surface the coal lies in a geological basin, the upturned edge
of which is faulted against the Charnian mass on which we are standing.
It was probably formed at a period when the Charnian mass was an island
or series of islands in the Carboniferous swamps. ‘The coal basin is
divided into two parts or zones running from north-west to south-east
parallel to the axis of the Charnwood, by an anticline running approxi-
mately through Ashby-de-la-Zouch. This central area is largely
unproductive. The chief mining areas therefore lie in a western zone
round Swadlincote, Moira and Donisthorpe, and in an eastern zone
around Coalville and Coleorton. This latter zone is mostly concealed
under a thick sheet of Triassic marls and boulder clay. Much of the
western zone is heavily faulted. This adds to the difficulty and expense
of working. ‘The pithead gears, the miners’ rows, the numerous small
towns and overgrown villages, the absence of large scale manufacturing
industry, the numerous mineral spur lines of railway, and the relatively
dense population, are all forms of the cultural landscape which here reflect
a definite relationship or series of relationships to the underlying geological
structure and surface topography. ‘They are the concrete expressions of
man’s relationship to nature in the Leicestershire coalfield.

A wholly different district is that of Charnwood Forest. Here we find
some of the very few parts of the Leicester Region in which some of the
natural landscape remains, though even here much of the natural forest
cover has been removed and that which remains has been largely replanted.
Elsewhere in the Leicester region the landscape which we see is either
man-made or is nature modified by man. In the Charnwood Forest
district, bare, rocky peaks, steep slopes, narrow gorges, wooded hills,
patches of woodland, bracken, heather, gorse and moorland, and small
streams are the chief natural features of the landscape. Of the cultural
forms, grass fields and cultivation in the valley bottoms and middle slopes,
scattered farmsteads with a few small villages, quarries in the hillsides,
five reservoirs on the edges of the district, a few bungalows and small
houses for vacationists and weekenders, one good main road and numerous
improved side roads, are the more obvious.

The district consists of a mass of ancient rocks partly buried in the
younger Triassic marls. The general trend of the relief is from north-
west to south-east. ‘There are four main belts of upland which break out
here and there into ragged, rocky eminences—the projecting ribs of the
underlying structure. These belts of upland are separated by three
longitudinal depressions. ‘They contrast sharply in their smooth outlines,
their arable and pasture land, with the barren, rocky, and often tree- or
bracken-covered ridges on either hand. In this contrast lies one of the
great charms of the Forest area, and in it is to be found one of the reasons
why the district performs the useful function of being a playground for
the people of Leicestershire. The fine air available on the ridges and
slopes and in some of the more elevated villages such as Woodhouse
Eaves is a further reason.

Near the centre of each longitudinal depression there is a water parting.
From it streams flow north-west and south-east, sometimes turning
sharply ata right angle to cut their way through a bar of ancient rock—thus

12 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

forming a steep-sided gorge. One of the best-known examples of this
occurs at the Brand in Colonel Martin’s estate. These rock bars have
helped to retain in the Charnwood valleys the red marl which gives them
their fertility.

We have symmetry and great contrast as two of the marked character-
istics of the Charnwood district. Both are related to the geological struc-
ture and development of the area. The geological outcrops take the form
of a series of crude horseshoes placed one within the other—the open ends
of the shoes being towards the north-west. ‘The present ridges correspond
roughly to the more resistant arms of the shoes, while the depressions
were formed in the less resistant arms. ‘The whole arrangement has been
very much modified by severe faulting and displacement along the inside
curves of the shoes. A brief picture may be given of the probable develop-
ment of the present relief. A series of volcanic islands probably occupied
in Archean times what is now the site of the Forest. Much volcanic ash
and lava were ejected from the volcanoes. The material cooled and
solidified, becoming partially stratified in the surrounding sea. Sub-
sequently this material, once horizontal, was ridged up into the form of a
crude ellipsoidal dome. Weathering processes then broke open the dome
and produced a steeply marked ridge and valley topography. This was
later depressed and buried during the Triassic period in the Keuper marl.
Still later erosional processes began to reveal once more the hidden land-
scape—a process which is still going on. ‘The valley floors, with one
exception, are still buried in the marl, to what depth it is not possible
to say.

Within the Charnwood, and at places to the east and south in the lower
grounds, there are numerous quarries. These are in part connected with
the rock of which the Charnian mass has been built up, and in part with
granites and syenites which represent upwellings of the molten magma
penetrating the Charnian rocks and, in places, as a result of erosion, reach-
ing the surface through the Keuper marl in the low grounds to the south
of the Forest. Thus at Bardon Hill in the west, Groby in the south, and
Mountsorrel in the east of the Charnwood, granites and related rocks are
quarried for road metal and paving sets. At Enderby, Croft, Stoney
Stanton, and Huncote, outcrops of syenite probably connected with the
main upwellings in the Charnwood, are quarried in the midst of an
otherwise purely farming country.

The Charnian reservoirs on the edge of the district, conveniently
placed for gathering the heavier rainfall of the ridges, are to-day inadequate
to supply the rapidly growing needs of the neighbouring population
centres, such as Leicester and Loughborough, and adequate supplies are
now obtained from a reservoir near the headstreams of the Derwent in the
Pennine uplands. This supply Leicester shares with the cities of Sheffield,
Nottingham, and Derby.

We cannot leave the Charnwood area without recording the public-
spirited action of the late Mr. Charles Bennion in securing for the com-
munity Bradgate Park, the home of Lady Jane Grey, and of the Leicester
Rotary Club in preserving the beautiful Swithland Woods, threatened with
destruction for building purposes. Mr. Bennion’s son and Messrs.

LEICESTER IN ITS REGIONAL SETTING 13

Bastard and Viccars have added to his gift. Nor can we refrain from
regretting that an open area adjacent to the beautiful Swithland Woods
should be spoiled by the unsightly erection of hutments for week-end
visitors.

To conclude our brief account of the Leicester Region we have yet to
describe Leicester itself in the Soar Valley. The river has cut out a wide
flat flood plain which varies in width up to a mile. For a distance of
about 12 miles the right bank of this flood plain is formed by a minor
escarpment caused by the river cutting into the Rhatic limestones of the
lower Lias.2 At Barrow-on-Soar, about 6 miles north of the city, the
presence of a lime works indicates the utilisation of the stone to make an
excellent hydraulic cement from which drainpipes and artificial paving
stones are made. This cement hardens readily under water and is
therefore of great value for coastal and harbour work. The beds are of
especial interest to the geologist, since in them have been found many
fossil reptiles of the Jurassic period.

The original site of Leicester was a gravel terrace on the east side of
the river Soar. This dry terrace was the chief town or camp of a Celtic
tribe. It was occupied by the Romans who carried through it the Foss
Way on its way from High Cross to Lincoln. Above and below this
point the river valley was marshy. ‘The gravel terrace coming close to
the water’s edge doubtless formed a convenient crossing point for the
Foss Way, and an equally convenient terminal point for the Via Devana,
which, starting from Colchester, ran by way of Godmanchester and
Medbourne to Ratz Coritanorum, as the Romans called Leicester. The
many Roman remains found in and about Leicester indicate something of
the importance of Leicester at the end of this line of route to the Romans.
With the departure of the Romans in the fifth century, the land approach
from the south-east was replaced by the water approach from the north,
along which came first the Angles and later the Danes. Both Angles and
Danes have left traces of their occupation of the region in the numerous
place-names terminating in ‘ ton,’ ‘ ham,’ and ‘ by.’ This latter termina-
tion, of Danish origin, is very common along the rivers Soar and Wreake,
then navigable streams, as at Sileby, Rearsby, Frisby, Asfordby, and
Kirby.

The modern city has spread far beyond the limits of its original site on
the gravel terrace by the river. Its chief expansion has been eastward
up the face of the Rhetic escarpment and on to the plateau top beyond.
On the plateau top is a fine open space, the Victoria Park, at the south-west
edge of which, overlooking the city, are the buildings of the University
College. One of the best residential areas in the city now extends along
this high ground for a distance of about 24 miles south-eastward to Oadby.
This high ground carries the main road to London and forms a clearly
marked plateau-like ridge running north-west and south-east. It is
bounded to the north-east by the sharply cut valley of the Willow brook,

2 This escarpment is greatly obscured in places by boulder clay.

3 Although this lime works is still in operation, the local quarries supplying the
raw material have been abandoned, owing to the increasing thickness of the clay
overburden.

14 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

running to the Soar and to the south-west by the Knighton brook, another
tributary of the Soar. To northward and southward along the east bank,
and to a lesser extent along the west bank of the river, working-class and
manufacturing areas have sprung up. Many of the older manufacturing
establishments are along the river and near the centre of the city on the
low ground. Newer industrial areas have developed in the tributary
valley to the east and in the Belgrave area to the north. On the higher
ground of the Dane Hills to west of the city a better type of residential
area has recently grown up at Western Park. Near the centre of the city
are grouped the chief retail shopping areas, the offices of wholesalers and
of the chief professional firms, such as lawyers, accountants, architects,
auctioneers, insurance agents, and the head offices of banks. Here also
are the retail and wholesale markets, the municipal offices, the headquarters
of the omnibus services, the Colleges of Art and Technology, and, just
outside the centre, the main stations of the railways serving the city.

The retail market-place and the motor-bus headquarters are of par-
ticular interest, because they typify an increasing link between the city and
the surrounding countryside. Leicester, in addition to her manufacturing
activities, is a great market and distributing centre for the whole of the
region we have discussed above. Markets are held three times a week in
the market-place. ‘To that held on Wednesday the country people flock
both to buy in the market and in the adjacent shopping centres. The
added transport facilities offered by the motor bus have tended in the last
few years to increase this side of Leicester’s activities. ‘The importance
of the pastoral activities of the surrounding countryside is emphasised
by the size of her periodical cattle and sheep fairs.

In the foregoing paragraphs we have only been able to glance briefly
at the city. No account, however brief, would be adequate without some
reference to its manufacturing activities. As these are fully discussed in
a later section of the survey, we will here only touch briefly on them. The
two staple industries of the city are the manufacture of hosiery and boots
and shoes. Coupled to these major industries are a series of others, some
of which are independent and others are subsidiary. Two of these are
wool-spinning and engineering. ‘The former is the oldest of the Leicester
industries. As far back as the thirteenth century, Leicester wool had
established a reputation among English wools. This reputation was
enhanced in the eighteenth century by Robert Bakewell, who, on his farm
near Loughborough, developed the new Leicester breed of sheep, and
artificially irrigated his land to improve the herbage. Wool was spun and
woven in the district by hand, and from these small beginnings sprang the
wool-spinning industry of the city.

Three hundred years later the hosiery industry developed out of this
wool-spinning industry in a series of villages to west of the river, and
especially in Leicester, Loughborough, Hinckley and Castle Donnington.
With the coming of the Industrial Revolution concentration took place
in the larger centres, though the industry is still carried on under factory
conditions in a number of villages, chiefly to south of the Charnwood, no
doubt helped by the lower county rates and the labour supply available.
‘To-day Leicester is by far the biggest centre in the country for the manu-

LEICESTER IN ITS REGIONAL SETTING 15

facture of woollen hosiery. The headquarters of firms with a world
reputation in the hosiery industry are to be found in the city.

It is difficult to say how far, if at all, the boot and shoe industry of
Leicester can be related in its origin to geographical circumstances. No
doubt there have always been shoemakers in the city. No doubt their
work was facilitated by the skins obtained from the adjacent pasturelands
and the oak bark for tanning. Oaks were numerous on the clay-covered
lowlands of the Midlands. But the modern industry, which is a highly
organised example of machine production involving both steam power and
inventive genius, was only developed in the city during the last century.
Its raw materials to-day are drawn from all over the world ; its demands
on bulk coal production are small ; the value of its finished products in
relation to its raw materials is high. We can say, perhaps, that Leicester,
situated almost as far from the sea as any city in England can be, is not
unfavourably located for the carrying on of an industry of this type, since
transportation charges on its finished products and raw materials do not
affect it to the extent that they do affect the heavier industries. Once
established, the supply of skilled labour, the development of subsidiary
industries, and the centralisation of the organisation and finance of the
industry in the city would naturally tend to attract new-comers and develop
established firms. ‘These considerations apply also to the earlier estab-
lished hosiery industry. To-day Leicester is the headquarters of many
of the biggest firms engaged both in the manufacturing and in the distribut-
ing end of the boot and shoe industry. Many of the latter firms control
numerous retail shops scattered all over the country. Like hosiery, boots
and shoes are also made in many of the smaller towns and villages in the
southern part of the region.

The engineering industry is in part a subsidiary of the two staple trades,
and in part independent. Its chief activity is perhaps in connection with
machinery for the two staple industries. In addition, it produces a great
variety of other machines and appliances, particulars of which will be found
in the section of this survey which deals with engineering.

Loughborough to north of Leicester is situated on the west bank of the
Soar. It is primarily a local market centre. In addition to this function
it has developed hosiery, engineering and bell foundry industries, and
contains Loughborough College, which has attained a widespread reputa-
tion as a centre for engineering training on production.

We have already briefly touched on the roads of the region and the pro-
duction of road metal. From the broader standpoint of road communica-
tion in relation to outside areas Leicester is very favourably situated. A
straight line on the map from the London Docks to the Manchester region
passes close to Leicester. It roughly corresponds to the main route from
London to the north-west. Using either the route through the gap in
the chalk near Luton or that at Dunstable, road traffic enters the Leicester
region at Market Harborough. ‘Thence, by way of the Soar valley and
Leicester, it passes north-west to Derby, and from there has a choice of
three routes to Manchester. Other main roads radiate north, east, south,
and west to Newark, Grantham, Stamford, Peterborough, Rugby,
Coventry, Birmingham, and Burton. With two exceptions these roads

16 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

keep to the valleys or the low ground. The exceptions are the Roman
Foss Way, which crosses the Wold country to Newark, and the road to
Peterborough, which rises over the Jurassic uplands. The Grantham
road, which uses the Wreake valley to Melton, is forced to rise over the
Melton Ridge. The railways mostly keep to the river valleys or the low
ground, avoiding the three areas of upland, but the railway from Melton
to Nottingham is forced to tunnel under the Melton Ridge, and that which
runs directly eastward from Leicester towards the marlstone escarpment
tunnels under a spur before turning south-east through a gap in the
escarpment. Water communication is not much used, though the Soar
is canalised to its junction with the Trent.

In the above rapid survey of the Leicester region we have necessarily
been forced to sketch in the broad outlines and omit detail. We have
seen, however, something of the more obvious relationships between man
and nature in the region, and something of the way in which the cultural
forms express that relationship. ‘The position of the city, the areas of
grassland and tillage and their subdivisions, are related to slope, elevation,
soils, drainage and climatic conditions. The iron workings, the coal
mines and the quarries are related chiefly to the geological structure ;
the roads and railways to the relief; the reservoirs to elevation, slope,
stream and rainfall; the hikers, week-enders, and other visitors in the
Charnwood to the scenic beauty of the physical setting. The focusing
of much of the economic and other activities of the region on the city is
mainly a matter of distance, but partly also a matter of its position in
relation to a series of highly diversified neighbouring areas, and of its size
as a large manufacturing entity with the many subsidiary industries and
activities which that fact involves. ‘The city is perhaps fortunate in that
her two staple trades, hosiery and boots, help to supply one of the three
great primary needs of mankind, the need for clothing, and that, while
she carries on a large foreign trade, the main market for these goods is at
home. She is also perhaps fortunate in being located in one of the
richest grassland areas in England, for it is on the grassland with its pro-
duction of beef and mutton, milk and cheese, under steadily improving
methods of handling, that much of the future prosperity, and therefore
the purchasing power, of the English countryside would seem to depend.

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GEOLOGY 17

II.
GEOLOGY

BY
H. H. GREGORY, M.A.,
ASSISTANT CURATOR, LEICESTER MUSEUM AND ART GALLERY.

Position of the Area—Chief Rock Formations—Charnwood Forest Rocks—
Granitic Rocks—Mountsorrel Granite—Carboniferous Limestone—Millstone
Grit—The Coal Measures—The Triassic Rocks—Rhetic Beds—The Lower
Lias—The Middle Lias—The Marlstone Escarpment—Ironstone at Tilton—
The Upper Lias—Inferior Oolite—Glacial Drift and River Deposits—The
Quarrying Industry.

LEICESTERSHIRE can claim much of interest in the diversity of its general
geology. Situated as it is in the Midlands of England, it forms part of
the wide central plateau which is composed of Triassic and Jurassic
rocks, It lies to the south of the southern termination of the Pennine
axis, around which sweeps the plain of Triassic rocks on both the east
and the west. ‘Two narrower arms of this central plain bifurcate from
the area and continue northwards. On the eastern margin of the Trias
the Jurassic rocks form prominent scarp features. The line separating
the Triassic and Jurassic rocks runs across the irregularly pentagonal-
shaped county of Leicestershire from a point about two miles west of
Lutterworth in a N.N.E. direction, through Dunton Bassett and Wigston,
passing east of the city of Leicester to Brooksby in the Wreake Valley,
thence westwards to Sileby and north-north-westerly to Stanford-on-
Soar, when it continues northwards and north-eastwards into Notting-
hamshire.

To the west of this line the Triassic rocks form the major portion of
the solid floor of the surface of the county through which appear the
older rocks, for which Leicestershire is so justly famed, while to the
east of the line the lower and middle Jurassic rocks (Lias and Oolite)
rise. in escarpments, whose scarps, where prominent, face westwards.
A variety of resulting physical features and land forms within this area
is therefore not surprising.

Were the superficial deposits (glacial boulder clay, sand and gravel)
to be removed, the city of Leicester would be seen to be almost centrally
Situated in the county, nestling as it were in the lea of the Jurassic rocks
and itself built on the Keuper Marls, but within easy access of each of
the outcrops of the other geological formations and in a position at the
navigable head of the river Soar. The river Soar, for much of its
course, actually skirts the line separating the Triassic and Jurassic rocks.

The north-eastern lobe of the area culminates in the Belvoir ridge,
an escarpment composed of Lower and Middle Lias rocks, of which

B

18 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

the latter are largely quarried for ironstone to supply the local furnaces
at Holwell, near Melton Mowbray.

The eastern margin is formed of typical ‘ wold’ country comprising
hills of circumdenudation with cappings of soft Upper Lias clay and
inferior Oolite outliers culminating in Whatborough Hill, near Tilton,
which reaches a height of 755 ft. above sea-level. The eastern boundary
of the county descends in a general southerly direction to Great Easton
in the Welland Valley and then by a south-westerly course along the river
through Market Harborough to Catthorpe, near Rugby.

The county boundary then runs along Watling Street, over Triassic
rocks, to the neighbourhood of Atherstone, and then north-eastwards
across Coal Measures of the Ashby and South Derbyshire Coalfield,
Millstone Grit and Triassic rocks to the river Trent at Long Eaton.

The oldest rocks in this area appear at the surface through the covering
of Keuper Marls, about six miles north-west of Leicester and about
three miles west of Loughborough on the west side of the Soar valley.
These are the pre-Cambrian rocks of Charnwood Forest.

The highest point is Bardon Hill, 912 ft. high, though several com-
manding view-points rise to a height of over 800 ft. These include
Timberwood Hill, Beacon Hill, and Birch Hill.

The Charnwood Forest sequence consists of a varied suite of pyro-
clastic volcanic ashes, agglomerates, grits, hornstones, conglomerates and
slates, which have been divided into three conformable series. The
oldest, the Blackbrook series, has not been subdivided and consists of
greyish massive grits interbedded with greyish and greenish hornstones,
often beautifully banded and heavily stained along the joint faces from
the overlying Trias. On Ives Head occurs a porphyritic Felsite dyke
unrelated to any other known rocks of the Forest.

The Maplewell series consists of tuffs, agglomerates and hornstones
and comprises several subdivisions, the most striking of which the
Slate Agglomerate—an andesitic tuff containing fragments of purple
and green slate—is traceable on both sides of the anticline.

The Brand series, consisting of conglomerates, grits, quartzite and
slates, forms the outermost beds, several of which have been formerly
worked for roofing slates. This industry has now become extinct.

The Charnwood rocks are stated by Prof. W. W. Watts to be ‘ not
like the Uriconian or Torridonian rocks unless we except the grits and
conglomerate of the Brand series, which have some resemblance to
the Torridonian rocks. On the other hand, they have nothing in common
with the gneisses and schists of the north-west or central Highlands of
Scotland. Many of the individual bands are like those of the Longmynd
in Shropshire, and indeed if we could imagine the pyroclastic materials
from the Charnwood volcano dropped far from the vent and sorted and
stratified in water, they would be likely to produce a group of rocks
much like those of the Longmynd. It is impossible at present to push
the comparison further, and meanwhile it may be better to be content
with naming the whole group the Charnian System, and to refer i it to some
unascertained position in the great pre-Cambrian sequence.’

The beds forming the Charnian System were folded by earth move-

GEOLOGY 19

ments into an ellipsoidal dome or pericline. This dome was traversed
along a north-east to south-west axis by a major fault, which displaced
the relative levels of the two halves so that the denuded south-eastern
portion only raises its jagged crags above the mantle of Keuper Marls,
while much of the remaining portion still lies buried to the north-west.

Faults and thrusts, however, have greatly dislocated large blocks of
rocks, thus disturbing the general continuity of the beds around this
semi-ellipse or periclinal dome. Many of the subdivisions, however,
can be located so as to reconstruct the once perfect continuity of the
pericline.

The movements which produced these structural features directed the
intrusion of igneous rocks.

Into the pyroclastic volcanic rocks, grits and slates of the Forest several
types of igneous rocks were intruded, the chief of which are quartz-
diorite-porphyries, or so-called ‘ porphyroids,’ and augite-syenites.

The quartz-diorite-porphyries, or so-called ‘ porphyroids,’ which
occur at Peldar Tor, High Sharpley, High Cademan, Grimley, High Tor
Farm, Birch Hill and elsewhere were first intruded. These bear strong
evidence of shearing and crushing, probably by the main north-west and
south-east movements of pre-Cambrian date. These rocks only occur
in the north-west portion. Lenticular-shaped masses and bosses of
augite-syenite, granophyric in texture, which bear no marked evidence
of shearing, and which, therefore, were of later intrusion than the
* porphyroids,’ occur in Bradgate Park, at Groby, Markfield, Hammercliffe,
Bawdon Castle, Newhurst and elsewhere in the Forest. Further afield,
at Enderby, Narborough and Croft, Earl Shilton and Stoney Stanton,
finer-grained igneous rocks occur, giving rise to noticeable tumulus-like
hills. ‘These latter, however, may possibly be of later age.

The main folding, faulting and cleaving of the Charnwood Forest
deposits, and the intrusion into them of the igneous rocks, appear to
have taken place in pre-Cambrian times. But from that date onwards
until Middle Triassic times, if not somewhat later, the region was sub-
jected to denudation. At the present time the majority of the rocks
are only just being uncovered, and so, as Prof. Watts has picturesquely
stated, ‘ they still present a scarcely altered Triassic landscape ; to this
day many of the summits are as rugged and precipitous as when they
were mountain tops overlooking a Triassic desert, or just submerged
beneath the waters of a Triassic lake.’

In the Nuneaton district, lying to the south of Atherstone, Cambrian
rocks—Stockingford Shales—traversed by numerous dykes of diorite
occur. The igneous rock lies in sheets and varies greatly in thickness
from 200 ft. to small veins, often following the line of strike. The
Warwickshire coalfield succeeds the Cambrian shales on a synclinal
trough to the south.

The only intrusion of granitic rocks exposed in the area and for a
considerable distance beyond its boundaries is the Granite of Mountsorrel.
Covered by a mantle of Keuper Marls, its extent beneath the cover is
unknown.

Investigations of the extent of the Mountsorrel area eastwards have

20 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

afforded no positive knowledge, but the magnetic anomaly which has
been known to exist in the neighbourhood of Thrussington has been
again investigated, and it is probable that the granitic intrusion of Mount-
sorrel extends eastwards into that area under the cover of the Secondary
rocks of the east side of the county. Geophysical methods have been
used with some success in this research by members of H.M. Geological
Survey. These methods will be demonstrated on the site during the
visit of the British Association.

The area of this igneous mass lies to the east of Charnwood Forest,
approximately six miles north of Leicester and to the west of the main
Loughborough-Leicester road. It is prominently exposed at Castle Hill,
Mountsorrel, and large quarries are located to the west and north-west
in the near neighbourhood. A boss forms the fine wooded feature of
Buddon Wood which overlooks the Swithland Reservoir around the
margins of which are found some of the finest modifications, including
hornblende-gabbro, of this interesting granitic area.

The Mountsorrel granite mass is essentially and integrally separate
and distinct in age from the neighbouring Charnwood Forest area. No
indisputable contact with the Charnian rocks is exposed, though, on its
western margin, a hornfelsed rock with garnets is found. The Mount-
sorrel area shows no evidence of having been affected by the earth move-
ments which have produced the structural complexities of the Forest.
It is therefore newer than pre-Cambrian in age and may be as late as
Carboniferous, though petrologically it resembles the post-Silurian granites
of Britain.

Mineralogically and petrologically the rock of the main mass is a
granodiorite which increases in basicity westwards. It occurs in two
forms—red and grey—in the main quarry.

It is traversed by several veins and dykes of varied composition, which
include aplite, dolerite, diorite-porphyrite, augite-andesite and orthophyre,
though these are not of great numerical significance.

On the western edge of Swithland Reservoir is a boss of quartz-mica-
diorite, of which Brazil Wood is composed, while on the opposite margin
at Kinchley the contact of this rock with the Mountsorrel granite occurs.
In this small exposure masses of diorite of varying coarseness occur as
xenoliths in the acid granite together with veins of aplite or micro-
granite. This intimate intermingling of two igneous masses is indeed
striking and shows almost every gradation of mixing.

Dr. E. E. Lowe, in his monograph on the Igneous Rocks of the Mount-
sorrel District, aptly states: ‘ It would seem that at Kinchley we have a
manifestation of invasion phenomena similar to those developed on a
grand scale in Jersey, Skye, and other classic localities. Our manifestation
is a very modest one, it is true, but in spite of restricted area, Kinchley
possesses interesting and instructive features which make it well worth
the attention of geological students.’

Recently Mr. J. H. Taylor has been working on the petrology of the
Mountsorrel igneous rocks. He considers that the quartz-mica-diorite
is of hybrid origin, the result of assimilation of the hornblende-gabbro
by acid magma. ‘There is evidence to show that the earliest acid magma

GEOLOGY 21

to be injected in the Mountsorrel area was of alkali granite type, and it is
suggested that the granodiorite itself is the result of basification of this
magma. Mr. Taylor has also studied the accessory minerals of the
rocks in detail and records some twenty different species.

Inliers of Carboniferous Limestone occur to the north-west of Charn-
wood Forest at Grace Dieu, Osgathorpe, Barrow Hill, Breedon Cloud
and Breedon-on-the-Hill on a fault line which is a continuation of the
main Charnian axis. On a parallel line similar outcrops are brought up
at Dimminsdale, Calke, and Ticknall, just beyond the border of the county.
The rock is a magnesian limestone or dolomite and is now extensively
worked at Breedon and Breedon Cloud. A rich fauna, which is somewhat
decomposed, is found both at the Breedon quarries and at Ticknall.
Limestone shales also occur in association with the Carboniferous Lime-
stone at several of these localities.

Millstone grit occurs near Thringstone and again south-west of Ticknall,
but these outcrops may belong more to Coal Measures with which they
are in close proximity, and are of little significance.

By far the most important beds in the Leicester district are the Coal
Measures, which are exposed at the surface over an extensive area of
upwards of 70 square miles to the west and north-west of Charnwood
Forest. The Coal Measures are divided into three parts, acentral district
of unproductive measures containing no important coal seams, and the
lowest measures with an axis north-west—south-east, forming an anti-
clinal arch through Ashby-de-la-Zouch. On the south-west side lies the
productive South Derbyshire and Moira Coalfield, separated by the
Boothorpe Fault, while on the eastern flank is the Coleorton Coalfield,
bounded on its eastern side by the Thringstone Fault. The Coal Measures
further to the south-east are overlain by Triassic rocks, but are extensively
worked as far south as Desford.

The Triassic rocks cover a greater area than any other solid formation
in the Leicester district. By far the major portion consists of the Keuper
Marls, often beautifully inter-banded with thin bands of sandstones
and green marls as at Sileby and Enderby, while on the north-western
side of the county the Keuper sandstone and also some associated beds
of the next older member, the Bunter Pebble beds with sandstone beds,
occur in close association with the Coal Measures and Charnian rocks.

Near Leicester beds of Gypsum occur in the Keuper Marls.

The transitional Rhzetic beds occur as dark shales in the area, but the
only exposure, at Glen Parva, which has yielded very rare fossil remains,
is now inaccessible.

The outcrop of the Lower Lias extends from the Vale of Belvoir in a
wide strip of over 4 miles to form the basal feature of a projecting
spur of Liassic rocks, which reaches as far west as East Leake Hills.
Its outcrop, however, is almost wholly obscured by drift deposits, At
Barrow-on-Soar, the Lower Lias was until recently quarried extensively
for its hydraulic limestone, which was used for the making of cement.

The Lower Lias in this area consists of a lower and an upper series of
beds. ‘The lower series comprises thin bands of argillaceous limestones,
varying in thickness from about a foot to a few inches, interbedded with

22 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

blue shales. These beds of the lower series have been quarried at
Barrow-on-Soar, yielding many large fossil reptilian remains of
Plesiosaurus macrocephalus Owen, Ichthyosaurus communis Conybeare,
I. tenuorostris Conybeare, as well as numerous fossil fish. Many of these
specimens can be seen in the Leicester Museum and Art Gallery.

At Kilby Bridge, south of Leicester, similar beds have been worked
until recently, but at both quarries work has now ceased on account of
the great thickness of useless overburden of glacial drift which first had
to be removed.

In the upper part of the Lower Lias, blue clays and shales of considerable
thickness occur. These upper beds are only exposed along a narrow
tract of country below the Middle Lias escarpment, and along the numerous
small streams which flow westwards into the Soar.

In the clay pit at Glen Parva brickyard, the base of the Lias is seen
resting on the Rheetic Shales.

The Middle Lias outcrop traverses the county from near Harstone
on the north-east border, south-westerly through Eastwell and Holwell
to Old Dalby, thence eastwards to Sproxton, southwards to Wymondham
and then in an irregular outcrop through Burrough Hill, Tilton, Billesdon,
Goadby and Hallaton, to the near neighbourhood of Market Harborough
in the south-east. Following a series of sinuous curves, its outcrop,
where free from drift, forms a marked topographical feature or escarpment,
with outliers which have been denuded from the main outcrop, as at
Gumley, Foxton, Stonton Wyville, and Great Bowden in the southern
part of the county.

The Middle Lias comprises two important divisions,—the rock-bed
consisting of Marlstone and the shales below the rock-bed.

In the north-eastern area the Middle Lias forms a prominent and
unbroken escarpment, stretching from Belvoir Castle to the neighbourhood
of Old Dalby. ‘The Marlstone forms the protective capping to this
escarpment whose highest point (569 ft.) is reached at Broughton Hill,
near Wartnaby. Around Belvoir Castle the country is well wooded
and very picturesque, the escarpment offering a number of very fine
view-points in the area. The ridge itself is divided into three large
outcrops by a great sheet of boulder-clay which overlaps its southern
edge and extends down the scarp slope for some distance on to the Lower
Lias below, forming gaps at the head of which are the villages of Eastwell
and Scalford.

In the neighbourhood of Tilton, the Middle Lias attains its greatest
thickness and forms a series of bold escarpment features. ‘These bold
features can be seen wherever the rock-bed is free of drift, as at Life
Hill (727 ft.). Billesdon Coplow marks the most westerly outcrop of
the rock-bed, and is underlain over a rather more extensive outcrop by
the underlying sandy shales, and rises to an elevation of 7oo ft. On
account of the thinning of the rock-bed southwards the Marlstone iron-
stone has not been extensively worked for iron ore south of Tilton, though
recently much increased activity has been apparent at Tilton on account of
economic conditions enabling local iron ore to be again profitably worked.

The rock-bed of Marlstone ironstone quarried at Tilton by the

GEOLOGY 23

opencast system is about 12 ft., though in the railway cutting near the
railway station about 18 ft. of ironstone is exposed, and is underlain by
sandy shales.

Further north, around Somerby and Pickwell, the Middle Lias escarp-
ment becomes free of drift deposits, and the rockbed or ‘ Transition
bed,’ as it has been called, is well exposed as a flat-topped hill dipping
gently eastwards and presenting a bold escarpment to the west around
Burrow-on-the-Hill or Burrough Hill, where it attains a height of 690 ft.
It is on this flat tableland that an early Romano-British encampment was
located.

Over considerable portions of this area the Marlstone has been removed
for supplying the Holwell Ironworks at Asfordby, near Melton Mowbray,
with raw material.

There has recently been much increased activity in quarrying the
ironstone, and the average annual output in this area is over half a million
tons. The content of iron varies from about 23 per cent. to 2g per cent.

Above the Middle Lias in this area and separated from the Marlstone
‘ Transition bed,’ the upper surface of which shows some pene-
contemporaneous erosion, are beds of clay with nodular limestone in
bands and septaria. These are succeeded by the ‘ paper shales’ and
fish and insect limestones. These beds comprise the Upper Lias in
this area. They form steep banks, and in quarrying the underlying
Marlstone by the open-cast system for ironstone these measures form the
overburden which is removed.

The Upper Lias outcrop in the north-east is only about a mile wide,
but on the borders of Rutland, into which county it passes, the width is
greatly increased, and east of Tilton and Tugby it attains its greatest
width of outcrop of about six miles. South of the river Welland, near
Market Harborough, the outcrop again narrows to pass beyond the county
boundary.

On the east side of the county, in the neighbourhood of Tilton, outliers
of Inferior Oolite form the cappings of the highest hills, as at Whatborough
Hill (755 ft.), Robin-a-Tiptoe (726 ft.), and Barrow Hill, near Lod-
dington, and at Launde Wood. A larger outlier in the neighbourhood
of Medbourne and Neville Holt on the north side of the river Welland
is capped by Lincolnshire Limestone, the upper member of the Inferior
Oolite. Further north in the neighbourhood of Waltham-on-the-Wolds,
Stonesby and Croxton Park, is a faulted block of Lincolnshire Limestone,
a cream-coloured oolitic limestone, detached from the main mass at
Sproxton, Saltby and Croxton Kerrial. Unlike the bold features usually
presented in the main mass further east, this outcrop has little effect on
the relief, only forming a plateau which reaches about 570 ft. at Waltham
and near Lings Hill, north-west of Croxton Park.

The Lincolnshire Limestone, which varies from a ragstone or oolite
to a freestone in different localities, overlies the Northampton Sand.
In east Leicestershire the Inferior Oolite series comprises the
Northampton Sand, usually rich in ironstone, passing up into brown
sands, succeeded by sands and clays of a lighter colour. These beds
represent the Lower Estuarine series.

24 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

In the working of the ironstones, the Lincolnshire Limestone, where
suitable, is worked for its lime content in smelting. Much new activity,
however, is anticipated in the neighbouring district around Corby, where
these beds are to be worked more extensively.

GLactIAL DrirT AND RIVER DEPOSITS.

Later Secondary and Tertiary rocks are not represented in the district.
The major topographical features had been determined by the end of
Tertiary time. All the minor features, however, owe their origin to
the presence of the glacial deposits which obscure the pre-glacial
topography of large areas of the whole district. The glacial deposits
are essentially diverse in character, and consist of beds of older sand and
gravel and older boulder-clay with quartzose sand interbedded and
succeeded by chalky boulder-clay and valley drift.

These drift deposits appear to be of two distinct ages, one containing
quartzite pebbles being derived from the west and north, and the other
containing chalk, lias limestone and oolite from the east. Possibly a
third series, found only at lower levels in the valleys and consisting of
clays and gravels, were deposited at a later date, after the existing valleys
had taken their primeval form.

By far the major portion of Leicestershire is drained by the river
Soar and its tributary, the Wreake. The Soar is a strike stream, having
cut its valley in a sigmoid curve in Triassic marls at the foot of the
Jurassic scarps. It is probable that its present course approximates to
its pre-glacial course. The retreat of the ice-sheet left the country
strewn with thick masses of glacial detritus which, as one vast sheet,
rose gradually to the watershed and fell away gradually on either side.
At Six Hills it is over 120 ft. thick, while in a recent boring for water,
on the outskirts of Leicester 70 ft. of boulder-clay was proved. Through
this sheet the rivers and streams have re-excavated their channels,
often exposing the solid strata below. The numerous brooks draining
to the Soar on its right bank, north of Leicester, flow down the scarps
of the Jurassic rocks into which they have eaten their head-waters, while
the Wreake has collected numerous obsequent or scarp streams and
joined the Soar as a stream, running along the strike of a projecting spur
of these Jurassic rocks. Other interesting examples of stream abnor-
malities can be seen at the Brand and at Ulverscroft Mill, on Charn-
wood Forest, and also at Croft in the upper reaches of the river Soar.

After the final retreat of the ice-sheet, the rivers flowed at a higher
level with greatly increased volume, depositing along their courses much
sorted sand and gravel, which at the present day remain as river-terraces
along their banks. Teeth, tusks, and skeletal bones of extinct animals,
such as the mammoth, woolly rhinoceros, reindeer, bison, and others, are
found in these terraces.

These deposits yield valuable supplies af sand and gravel, and a
thriving industry has grown up with the ever-increasing demand.
Recently at Quorn and Barkby Holt extensive works have been opened
for the working of these gravels.

The Leicestershire quarrying industry has long held a premier position

GEOLOGY 25

in this country. The rocks at almost every geological horizon are quarried
in great quantities for some industrial purpose and used in many parts
of the country ; the Charnian rocks and their associated igneous rocks,
as well as Mountsorrel granite for road metal, setts, building stone and
slates, the coal measures for coal and fireclay, the Carboniferous lime-
stone for lime-burning and road-dressing, the marls and clays for gypsum
and brick-making, the Lower Lias Limestone for cement, the Middle
Lias and Inferior Oolite ironstone and limestone for smelting, and the
Quaternary sand and gravels for road-dressing and concrete.

Ill.
THE FLORA OF LEICESTERSHIRE

CONSIDERED BOTANICALLY, AND IN RELATION TO
HUMAN ACTIVITIES

BY
A. R. HORWOOD, F.L.S.

Flora in Relation to the Geological Formations—Flora of the pre-Cambrian
Rocks of Charnwood Forest—Flora of the older Limestones—Flora of the
Coal Measures—Flora of the Oolites—Flora in Relation to Human Activities
—Scenery and Vegetation—Local Plants of Economic Interest—Great
Chalky Boulder Clay—Forestry and the Flora of the District.

SoME OF THE LocaL Types OF NATURAL VEGETATION.

Tue flora of Leicestershire may be considered like that of any other area,
characterised by the nature of the soils derived from the geological
formations of the area, each soil type supporting a different type of wood-
land and other correlated plant community. Broadly speaking, the rocks
of the whole district consist of four or five main types.

(1) The pre-Cambrian Rocks of Charnwood Forest, largely of volcanic
origin, of higher elevation than the rest of the county, mountainous on
a small scale, and affording generally sandy or siliceous soils, bear woods
of oak, pedunculate and sessile, oak-birch heath, or birch wood, grass
heath, siliceous grassland, calluna heath, and heather moor. Such soils
being largely confined to the area of Charnwood, the plant associations
named and the component species are likewise more or less confined to
Charnwood Forest.

Deforested several times, Charnwood Forest was probably once part of
a former more extensive forest, part of the Forest of Arden, stretching from
the Avon to the Trent, and beyond to Sherwood, and eastward to Lyfield,

26 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

or Leighfield, in Rutland, and Rockingham in the north of Northampton-
shire. ‘Thus, only remnants or vestiges of original forest survive, and
no very old oaks are left, the communities named being derivations from
woodland. A large area has been enclosed, cultivated, drained, and
materially altered artificially. ‘The tendency, moreover, all over the open
areas which have become drier, causing the moor peat to lose its character,
is for bracken to overrun the district, and to oust less aggressive members
of the communities named. A few illustrations with examples of a moiety
of the more characteristic plants of each locality selected are all that can
be attempted in so brief an analysis. ‘Thus, at High Sharpley, on Sharpley
porphyroid and Beacon beds, at 600-700 ft. O.D., there is evidence of
this spoliation of more natural vegetation, heather moor, calluna heath,
siliceous grassland and grass heath, which of small extent individually,
are intercalated, by the dominance of bracken, which has overrun them,
and eliminated other species. Here grows one of the rarest plants in the
county, the cowberry, Vaccinium Vitis-idea, which only extends to
a few square yards. It is a northern montane plant, which here reaches
its most southern limit in the Midlands. Bracken is dominant as a whole.
Mat grass and purple moor grass form a belt around the lower part of
the slopes, the former sometimes dominant, in drier places, the latter in
wetter spots, as elsewhere on the Forest, where the peat layer has become
exposed to drainage on the one side or waterlogged on the other. Old
rills are filled with various rush species, bog moss (sphagnum), or
Harpidia, etc. In between, hummocks are formed by Calluna, or ling,
and Vaccinium Myrtillus, whortleberry. Cross-leaved heath or bell heather
is scattered amongst the heather in more peaty, moister situations. Occa-
sionally bog moss or sphagnum (where sundew also, no doubt, grew for-
merly) fills the surface rivulets, formed to drain the enclosure, and occupies
the lower, wetter slopes. Dwarf furze, characteristic of the Forest area
generally, is more frequent on the more rocky slopes or dry knolls.
Wood sage, sheep’s sorrel, heath hair grass, early hair grass, a montane
glaucous form of annual meadow grass, buckler fern, circle round the
higher ground near the rocks, with occasional patches of ling and whortle-
berry in crevices. Bracken is generally dominant on the drier slopes,
gradually eliminating other species and obscuring the traces of the various
successions following the original oak wood. ‘There are a few small bog
pools with a water buttercup (Lenormand’s crowfoot), water blinks,
lesser spearwort, montane hepatics, lichens, desmids, diatoms, etc.
On the rocks on the north side overlooking the old Blackbrook Reservoir
(now Loughborough Waterworks), where sundews, etc., once grew,
rupestral montane mosses and lichens are more abundant, and in wetter
spots sphagna, whilst Empetrum probably grew in moist ground to the
north-east. Bog violet, marsh pennywort, green-ribbed sedge, heath
rush, heath wood rush, pill-headed sedge are other characteristic
species that form small societies here and there. Generally speaking this
then is upland moorland, very different to the great grassland tracts on
the clay plains of the rest of the county.

Spring Hill, Peldar Tor (7oo ft. O.D.), is another area, on Peldar
porphyroid, which forms a similar modified type of heather moor and

THE FLORA OF LEICESTERSHIRE 27

calluna heath, with whortleberry and ling forming hummocks on high
ground, with heath hair grass, mat grass, and purple moor grass,
etc., as at High Sharpley, gradually being dominated by bracken, and in
process of elimination. Here is the only station now for the crowberry,
Empetrum nigrum, much endangered by quarrying operations, and petty
whin, Genista anglica, a plant which has become very rare in the county,
elsewhere recently seen only at Six Hills. For the rest the characteristic
species resemble those of High Sharpley, occurring in different degrees of
frequency, with birch and pine here and there, becoming locally abundant,
and the same applies to contiguous tracts at Charnwood Heath, just above
the Hanging Stone, where formerly grew the hare’s tail cotton grass,
which was, no doubt, once dominant there, and probably helped along
with sphagnum, to contribute to the moor peat cover of these ancient
rocks. This peat layer has become so thin and desiccated that it can no
longer support its characteristic vegetation—heather moor or calluna
heath—and is now being further altered by the growth of bracken,
calluna and whortleberry, with the absolute elimination here and every-
where else on the higher ground of North-west Charnwood, of the purple
heather (not seen since 1886), which was, no doubt, as common once as ling
to-day in places. Much of this ground is now calluna heath or dominated
by grass types and grass heath, siliceous grassland, with here and there
holly, rowan, woodsage, seedling pines, Ulex, mat grass, purple moor
grass, etc. Timberwood Hill adjoining, now planted up with larch at
800 ft. on Felsitic agglomerate and Beacon beds, is of similar type, with,
on the open moorland, whortleberry dominant, and bracken likewise here
sub-dominant, and aggressively destroying the other natural vegetation,
of heather moor, etc., which includes the other common species, heath
rush, ling, heath bedstraw, gorse, mat grass, purple moor grass,
heath hair grass, sheep’s sorrel, etc. Sundew once here has gone, like
most of the other rare plants recorded in 1745-47 by Dr. Richard Pulteney,
as found on Charnwood. This was largely, no doubt, due to the Enclosure
in 1829, when great ploughs drawn by eight horses were used to fit for
cultivation an area once forest or ‘ waste.’

Of woodland, Copt Oak at 700 ft. O.D., on Beacon beds, is a sessile oak
wood, with sessile oak, birch, holly, rowan, and alder, with various
forest Rubi, and in the ground flora bracken is dominant, but there is also
much whortleberry, purple moor grass, heath hair grass, bog violet,
soft grass, heath bedstraw, tormentil, heath wood rush, mountain
fern (becoming scarce), bluebell, foxglove, woodsorrel, etc., and in an
adjoining covert, oak-birch heath, with the two birches dominant, some
sessile oak, bracken, buckler ferns, ling ; in swampy, peaty places, creeping
forget-me-not, marsh willow-herb, hard fern, bell heather, purple
moor grass, marsh pennywort, etc.

Swithland Wood, at about 300 ft. O.D., partly on Keuper Marl,
surrounding the Swithland Slates, is a damp oakwood, or oak hazel, with
bluebell, great wood rush, a little bracken, hazel, cow wheat, dog’s
mercury, ramsons, wood anemone, yellow dead nettle, primrose ; and
around the slate pits, on the Swithland Slates, birch is dominant, whilst
amongst the slates in clefts grows navelwort (Cotyledon Umbilicus),

28 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

polypody fern, etc.; and around the pits, Teesdale’s cress, woodsage,
foxglove, etc., typical of birch and sandy oak wood, this being a composite
wood on different soil types.

Buddon Wood is similarly composite, with dry or sandy oakwood types,
much holly and rowan, whortleberry, etc., around the granite, and oak
hazel elsewhere on Red Marl, including the only station now for club
moss. On the edge of the wood is also the only locality for subterranean
clover, and also spreading bell flower, Campanula patula, known there
since 1745. One of the best types of sessile oakwood is Benscliff Wood,
at 570-700 ft. O.D., on Felsitic agglomerate and Beacon beds, with
whortleberry and ling, and birch around the pillars of agglomerate, which
form small kopje-like rocky knolls in the wood, with bluebell, soft grass,
woodsorrel, sheep’s sorrel, heath bedstraw, woodsage, wood pimpernel, in
wet places purple moor grass, etc. Pine, beech, and wych elm have been
planted.

(2) The next distinct type of rock includes the older limestones, or
Carboniferous Limestone of Breedon, Breedon Cloud (the wood itself partly
also on Red Marl, and Boulder Clay, or ash oak, with yellow star-of-
Bethlehem, Solomon’s seal, butterfly orchid, giant bellflower, hybrid
cowslip—primrose, often called ‘oxlip,’ etc.), Barrow Hill, Osgathorpe,
Gracedieu. This is not a pure limestone, but an earthy magnesian lime-
stone of a creamy-buff colour, not blue like the typical limestone at
Calke and Ticknall, just over the Derby border.

At Breedon Hill old quarry, on the limestone grassland formed on it at
380 ft. O.D., a typical limestone flora is developed, including musk
thistle, mountain flax, lady’s bedstraw, wild thyme, mullein, sheep’s
fescue, Keeleria, white bryony, stork’s bill, cudweed, biting stonecrop,
wild parsley, white campion, rue-leaved saxifrage (growing on the rocks),
wall rue fern, Burnet saxifrage, musk mallow, perforate St. John’s wort,
harebell, etc.; and on similar rocks at Barrow Hill (280 ft. O.D.),
oxtongue, marjoram, wood reed grass, creeping rest-harrow, barren
strawberry, quaking grass, etc.

(3) On the third type of soil, sandy as a whole, in the Coal-Measure area,
around Ashby-de-la-Zouch, the woods such as South Wood, Lount
Wood, Ashby Old Parks, Spring Wood, Coleorton, The Smoile, etc., are
of the sandy oakwood type, with pedunculate oak, hazel, bluebell, soft
grass, woodsage, foxglove, common speedwell, rosebay, woodsorrel, etc.,
and in peaty pools, common loosestrife, wood reed grass, tussock sedge,
creeping forget-me-not, Carex Pseudocyperus, etc.

One of the most interesting areas in the county is on the peat and
alluvium formed on Coal Measures at Moira Reservoir, there being aquatic
and marsh formation, alder willow and fen carr, oak-birch heath, and
formerly calluna heath to the west, where purple heather, ling, etc.,
grew. The very rare Tofieldia palustris was found here in 1820 by Dr. J.
Moore, and was a relic of the Arctic and montane flora which extended
south in the Glacial period, and on retreat of the ice was only able to
persist at the higher altitudes formed by the Pennine Chain, of which
Charnwood Forest and its adjacent north-west area is a prolongation.
This is also the only locality for the pillwort, and the sole station for

THE FLORA OF LEICESTERSHIRE 29

marsh cinquefoil, shoreweed being likewise abundant in the Reservoir
itself. Several rare Rubi also grow here, and in the district, and although
now styled a reservoir this, once feeder of the old Ashby Canal, was
doubtless a natural pool in the wildest surroundings, before it was com-
pletely transformed by coal-mining operations. ‘The canal itself contains
Elisma natans, and on its banks Sagina nodosa, etc.

Groby Pool, which is in the south-east corner of Charnwood, in a hollow
of Red Marl and Granite surrounded, at ‘ Frog Hole,’ with a cover of peat
and alluvium, at about 300 ft. O.D., is another old natural reservoir,
where there is quite a large assemblage of rare plants. In the pool itself
mare’s tail, bladderwort, and recently a gentianaceous water plant,
Limnanthemum, have been found. In the marshy alder swamp at the back
grow grass-of-Parnassus, bog bean, marsh helleborine, and other marsh
and spotted orchids, twayblade, marsh pennywort, two kinds of cotton
grass (not the hare’s tail, once erroneously reported), marsh bedstraw,
marsh red-rattle, great and lesser spearworts, bog speedwell, various
water buttercups, a great variety of sedges, some rare, marsh spike rush,
etc., besides all the more usual marsh and aquatic plants. By the roadside
hardby occur, in grass heath, silver cinquefoil, soft knotted clover,
hare’s-foot trefoil, red sandwort; in the quarry clammy groundsel,
American cress; and in the adjoining Sheet Hedges or Groby Wood,
a sandy oakwood in part, both golden saxifrages, bear’s garlic, columbine,
foxglove, cow wheat, pretty St. John’s wort, giant bellflower, hawk-
weeds, etc.

(4) The newer Limestones or Oolites constitute a fourth type, the
Lincolnshire Limestone, forming calcareous soils and limestone pasture.
On the Cotswolds and elsewhere the beech and ash form woodland, but
locally in north-east Leicestershire around Saltby where this type is best
developed there is very little woodland. Limestone pasture occurs
extensively at Saltby, Stonesby, Sproxton, Waltham, on the Mere Road,
and elsewhere. This flora includes the typical grasses, tor grass, as
aggressive as bracken, and tending to destroy or exclude the more interest-
ing members of the association, especially in Rutland where limestone
pasture is better developed, erect brome grass, sheep’s fescue, Keeleria,
rock rose, horseshoe vetch, purple milk vetch, marjoram, autumnal
gentian, field gentian, lady’s fingers, pyramidal orchid, bee orchid
(also on older limestones at Breedon Cloud Quarry and elsewhere on Lias,
etc.), early spotted orchid; long-stalked crane’s bill, yellow wort,
dropwort, greater knapweed, and the rare chalk milkwort at Sproxton
(also in Rutland where I found it six weeks earlier on April 28), squinancy
wort, white mullein (King Ludd’s encampments), field ragwort ; and
formerly pasque flower and mountain everlasting were said to grow near
here. At Saltby also is an interesting limestone swamp at the junction
of the Upper Lias and Northampton Sand, with several plants previously
confined to Charnwood Forest, and thought to be extinct, viz: butterwort,
black bog rush, etc. Besides these there may be found in this north-east
area many other limestone plants of more general occurrence. In the
Harston district also the Marlstone supports a distinctive limestone flora,
and the Upper Lias a series of woods resembling sandy oak woods, with

30 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

Digitalis, Pteris, etc., and at its junction is a limestone swamp, with
Sphagnum (very rare outside Charnwood Forest), ‘mountain fern, heath
rush, and several other interesting helophytes.

(5) In East Leicestershire a series of woods of ash oakwood type
occurs on the Great Chalky Boulder Clay, Middle and Upper Lias clays
and loams and calcareous sandstones and marls, with a characteristic
flora not found elsewhere, including wood forget-me-not, which colours
the woods a cambridge blue in May and June; nettle-leaved bellflower,
lesser teasel, herb Paris, wood vetch, small reed grass, etc.

THE FLORA OF LEICESTERSHIRE IN RELATION TO HuMAN ACTIVITIES.

Leicestershire as a great grassland country.—As ‘ the Shires ’ Leicester-
shire is a great grassland county which affords some of the best hunting
in England, fox hunting having been a recognised occupation as well as
pastime locally since about 1670, when a pack was kept at Tooley Hall,
near Peckleton. This excellence of grassland is no doubt due to the
prevalence of a clayey or clayey loam soil over a wide area. It is in fact
especially characteristic of the clays and loams of the Lower Lias, Upper
Lias, and Great Chalky Boulder Clay, and other less extensive outcrops,
e.g. Middle Lias. On these clays the grassland appears to be especially
suitable for cheese-making. Stilton cheese which goes all over the world
was first made at Withcote, but sold for a family reason as Stilton.
Withcote is in East Leicestershire on these clays. It was the originator
of the old Board of Agriculture, William Marshall, who, in 1790, in his
Rural Economy of the Midland Counties, one of his agricultural surveys of
every county, first showed the necessity for studying the character of the
grassland in order to select the best land for cheese-making. For this
purpose, during his survey of Leicestershire, he made careful lists of all
the species of grasses, legumes, and other types in each field, noting the
frequency of each species. He likewise cultivated grasses to determine
which was more suitable for this purpose. Marshall was thus really the
first ecologist in this country, not only in recognising the difference
between different grass types on different soils and the need for determin-
ing their dominance or frequency, but he also knew that besides the exist-
ence of different natural types of grassland, woodlands were similarly
dependent upon soil ; and that there were different types of woods, based
on this factor. He likewise understood that there were natural woods
and artificial woods, and realised that woods on ‘ ridge and furrow ’ were
of the latter type. By cultivation of the grasses he established one of the
leading principles of modern plant breeding and genetics.

SCENERY AND VEGETATION : THE BEAUTY OF CHARNWOOD FoRrESsT.

Natural vegetation is based mainly upon the geological formation and
soils to which they give rise so that where the one is diverse the other will
be equally diversified. Charnwood Forest is structurally an ancient
mountain chain, with its highest peaks buried and a very small proportion
of its height and extent is visible. The highest point is but g12 ft.
(Bardon Hill), and apart from that the rest of the high ground in the north-
west is about 800 ft., whilst the general altitude of the country west of the

THE FLORA OF LEICESTERSHIRE 31

Forest is about 500 ft., so that the hills form but a miniature range. The
high ground is pierced at short intervals by ragged sharp crags, with
shallow undulations between, with occasionally steeper slopes or cliffs, as
at Bardon. Sometimes the rocks are pillar-like as the Hanging Stone
near Flat Hill, and Charnwood Heath, or at Woodhouse, or the Altar
stones, Benscliff Wood, etc., where the rocks appear as natural altar
stones or menhirs. ‘This contrast of rock and bracken, furze, or ling-
covered slopes or heights is also varied by the large number of small
tracts of woodland dotted here and there, like the relics of scattered forest-
land they really represent. ‘There is thus a great diversity of physio-
gnomic detail which makes Charnwood Forest a fascinating and picturesque
region of primeval rocks and miniature moors, knoll-covered, with pine,
larch, and oak, mountainous, diversified, wild. It is, as it were, a rocky
islet in a sea of grass, the surrounding plains of grassland being flat or little
undulating, until the great Jurassic escarpment running across Leicester-
shire north-east by south-west isreached. ‘This runs north-east to Belvoir,
with a break between Tilton and Burrough, and east of that line is broken
up and cut into a series of meandering valleys or gorges, with striking,
flat-topped hills here and there as at Life Hill, Billesdon Coplow (720 ft.),
Burrough, Robin-a-Tiptoes, Whadborough, etc. This East Leicester-
shire country is also well wooded in places, and with its great tabular,
high-level plateaux (700 ft.) and undulating dells or denes cut by the
rivers Chater, Gwash and Eye, etc., it is a region of great picturesque and
arresting natural beauty, seen at its best perhaps just over the Rutland
border at Wardley Hill, Bushy Dales, Deep Dene—all in the Uppingham
district.

Some LocaL PLANTs oF EcoNomic INTEREST.

In every district some local industry or craft may be found to have
played an important part formerly, if not to-day. Though there is little to
guide us, doubtless woad-growing and dyeing had its share in the pros-
perity of the Leicester community, as it did on the Continent from the
Middle Ages until indigo killed the trade. Blith in 1653 spoke of the
county as suitable for its cultivation, and the ‘ Records of the Borough of
Leicester ’ contain fines for infringement of the strict woad regulations
locally. Flax and hemp were cultivated as part of the native raw produce
for the manufacture of textiles, for which woad served as a dye substance.
In certain old terriers, e.g. one of Claybrooke, 1708, these crops were
rendered also as part of the tithe. Old, dry hollows in the Sheepy district
and elsewhere, unless marl pits, may have been retting pools where flax
fibre was prepared by fermentation (there is a flax pool near Castle
Donington). Hemp occurs here and there as an alien plant, perhaps as
a relic, in the same way as wood and flax, of former cultivation.

Many plants figure in the former use of ‘ simples,’ or household herbal
remedies, and to this cause we may probably attribute the occurrence in
almost every village of such plants as greater celandine, black horehound,
marsh mallow, Good King Henry, etc., and less frequently white hore-
hound, clary, hemlock, vervain, etc. To-day men may be seen to
go round the county in autumn picking mountain or purging flax by the

32 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

sackful. Railway goods guards, I found when resident in Leicester, are
particularly fond of collecting herbs on their journeys, and in this way
I have secured further evidence of the occurrence of such plants as bella-
donna or henbane, in spots where they were undoubtedly alien. In
Rutland the former is perhaps native in some woods, and great quantities
were collected during the Great War for pharmaceutical purposes from
Exton Park, where it is abundant.

Wild fruits of the countryside in some districts figure in season in
the local market periodically, and Pulteney in 1746-1765 records the
local names of the raspberry and of whortleberry brought into
Loughborough or Leicester markets.

Willows of every type, sallows, osiers, etc., play a part also locally in
industry, the Ellmore factory with its osier plantations at Thurmaston
and elsewhere being well known. Mr. Ellmore expressed the belief
that there were no hybrid willows, but Linton at Shipley, was able by
cultivation and experiment to show that there were.

THE CHALKY BOULDER CLay AREA AND ITS EARLY COLONISATION
BY THE ANGLO-SAXONS.

In Essex it has been found by Woolridge that the distribution of the
Great Chalky Boulder Clay coincides very remarkably with the distri-
bution of the Anglo-Saxon settlements and to a less degree the later
Danish ones. The reason given for this is the suitability of the soil,
a stony loam or calcareous marl, for crop cultivation, and the fact that it
is also one of the best superficial water-bearing strata. An examination
of the area of the Great Chalky Boulder Clay, largely confined to that
part of Leicestershire east of the Soar valley, leads to the same conclusion,
that it is more or less that area in which the Anglo-Saxons in their first
settlements in the county took up their abode. That area is, moreover,
almost entirely ‘ ridge and furrow,’ a relic of Saxon drainage.

FORESTRY AND THE FLORA OF THE DISTRICT.

It is reasonable to suppose, since pine occurs in deposits of pre-Glacial
age in the Midlands, that this was one of the forest trees at higher altitudes
in this area, and that Charnwood Forest was once partly pinewood,
which would account for the prevalence (formerly more marked) of ling
and other heaths, which follow in natural succession after loss of pine-
wood in an area, just as bracken follows oakwood—a process in widespread
operation on Charnwood at the present time. In this region the area most
generally afforested was Charnwood Forest. "The Domesday Survey shows
large gaps between scattered woodlands, elsewhere than on Charnwood,
in 1086, and the existence of much land in such areas under plough or
grass as early as that period.

Charnwood Forest itself appears—if Burton be correct (though Throsby
doubted him)—to have been disafforested shortly after the Conquest,
and afforested by Henry II, but disafforested by Henry III. It was also
bare of forest, ‘ almost without a tree,’ in Marshall’s time (1790). -In
recent years, since the Enclosure (1829), much pine, larch, beech, wych

THE FLORA OF LEICESTERSHIRE 33

elm, have been planted. It is thus almost impossible to indicate any single
spot on it that could be called virgin forest, so greatly has it suffered at
the hands of the woodman and his axe in the long distant past.
Note.—The Flora of Leicestershive and Rutland, by A. R. Horwood and the late 3rd
Earl of Gainsborough, will be published by the Oxford University Press before the

Leicester Meeting of the Association. Price £1 15s. With 2 maps, portraits, and
botanical photographs.

IV.
THE ZOOLOGY OF LEICESTERSHIRE

BY

E. E. LOWE, B.Sc., Ph.D. (Director, LkEIcESTER MuszEuUM AND ART
Ga.LLery), W. E. MAYES, R. WAGSTAFFE, anv S. O. TAYLOR,

General—Published accounts—Mammals—Birds—Reptiles and Batrachia—
Fishes—Freshwater Invertebrate Fauna—Protozoa—Porifera and Ccelen-
terata — Platyhelminthes — Rotifera — Annelida — Crustacea — Insecta —
Coleoptera—Diptera—Hymenoptera Aculeata.

LEICESTERSHIRE possesses no geological or geographical features so
remarkable and extensive as to produce a striking or peculiar fauna.
Charnwood Forest is, of course, from a geological point of view unique,
and is the home of several interesting species of insects (Coleoptera)
which are apparently survivals from earlier conditions, but the area of
the forest is now so restricted and so cut up that it offers no other faunal
peculiarities. It is a matter for congratulation, however, that in Bradgate
Park, on the south-eastern edge of the forest, an area of about nine hundred
acres presented to the city and county by the late Mr. Charles Bennion in
1928, certain portions have been reserved from public use and will no
doubt in time produce interesting records.

There are two available accounts of the Leicestershire fauna : (1) that
published in the Victoria County History : Leicestershire, in 1907 ; and
(2) that compiled by Mr. A. R. Horwood for the handbook Leicester and
Neighbourhood, issued to the members of the British Association on its
first visit to Leicester in the same year. Both are admittedly very incom-
plete except in regard to such familiar groups as the birds, butterflies,
moths and beetles. Many additional records have been made since the
publication of these accounts, chiefly by members of the Leicester
Museum staff and by workers in the ranks of the Leicester Literary and
Philosophical Society, and some of these records are mentioned below.
The brief notes on various groups which follow have been kindly contri-
buted by Mr. W. E. Mayes (Mammals, Birds, Reptiles, Batrachia and Fish),
Mr. R. Wagstaffe (Freshwater Invertebrates), and Mr. S. O. Taylor
(Coleoptera).

Cc

34 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

MaAmMMALs.

The red deer and the fallow deer are still preserved in a semi-
domesticated state in Bradgate Park and other parks in Leicestershire,
but by reason of the breaking up of some of these old estates the herds
have become more or less restricted. ‘The red deer in Bradgate Park are
believed to be the descendants of the ancient herd.

The badger is still fairly common throughout the county, particularly
on the eastern side. ‘The otter, on the other hand, is a much-persecuted
species and is rapidly decreasing in numbers.

Leicestershire, with its vast acreage of grassland, provides the best
fox-hunting in England, and it is solely due to the protection afforded to
the fox for purposes of the chase that this beautiful mammal is still
plentiful.

The pine marten (Mustela martes L.) and the polecat (M. putorius) have
long ceased to exist in any part of the county. The last recorded ap-
pearance of the pine marten was at Bradgate in 1868. Of the small
Carnivores, the stoat and weasel are still well represented, though the
latter is by no means as common as the former.

In spite of the persistent war that has been waged against the mole by
professional mole-catchers, for the sake of its fur, there seems to be no
decrease in the numbers and general distribution of this mammal.

Though all three species of shrew are found in Leicestershire, the
water shrew (Sorex fodiens) must be regarded as very rare. This interest-
ing little mammal has been particularly searched for, and only two have
been recorded during the past fifteen years. Both were noted during the
prolonged drought experienced in the summer of 1930. It therefore
seems reasonable to suggest that normally the brooks and streams of
Leicestershire carry too much water to enable the water shrew to become
established.

The lesser or pygmy shrew (Sorex minutus L.) has never hitherto been
mentioned in any previous record of the fauna of Leicestershire, but in
1925 an example was found at Barkby Thorpe. Subsequent investigation
has produced four more examples from other localities, proving the
pygmy shrew to be an established species. ‘That it has long existed in
the county but has been overlooked is almost certain.

The common shrew (S. vulgaris L.) is plentiful in all parts.

Of the fifteen species of bats listed as British, only seven have so far
been recorded for Leicestershire. These are as follows : Barbastelle Bat
(S. barbastellus), Long-eared Bat (P. auritus), Whiskered Bat (V. mysta-
cinus), Daubenton’s Bat (V. daubentoni), Natterer’s Bat (V. nattereri),
Common Bat (V. pipistrellus), and Noctule Bat (V. noctula).

The red squirrel is not so frequently met with as formerly. Several
examples of the grey squirrel have been seen or shot, but so far their
numbers have not given cause for alarm.

The dormouse (M. avellanarius L.) and the harvest mouse (MM. minutus)
seem to have disappeared from the county. The former was doubtfully
recorded previous to 1885, but there seems indisputable evidence that the
harvest mouse was fairly common in the neighbourhood up to 1889.

THE ZOOLOGY OF LEICESTERSHIRE 35

Since that time there has been no record of either of these interesting little
creatures having been seen.

The brown rat (Mus decumanus) is unfortunately too abundant, but no
recent occurrence of the black rat (MV. ratius) has been noted. So far
there is no evidence that the musk rat, which is doing so much damage in
Shropshire and other counties, has invaded Leicestershire, though recent
reports state that it has been seen in Rutland.

BIRDS.

Since the publication of the list of birds in the Victoria County History of
Leicestershire and Rutland in 1907, a number of additional species have
been recorded. It is also pleasing to note that several of the rarer species
in the earlier lists are still occasionally met with. For example, a raven
was seen at Wanlip during the winter of 1919, and remained in the district
unmolested for some days. Ravens nested in different parts of Charn-
wood Forest in earlier days, the last record of a nest being at Garendon
in 1825.

A rough-legged buzzard was observed at Bradgate in 1909, and an
osprey in the same locality in the autumn of 1913. ‘Two hen harriers
were seen and unfortunately shot at Normanton in 1919.

Though recorded as an uncommon summer visitant, the hobby has,
for the last two or three years, nested at Barkby Holt and at Humberstone.

There are several large sheets of water around Leicester, forming part
of the city’s water supply. ‘These reservoirs, of which Swithland Reser-
voir is the largest, have thickly vegetated margins, and form excellent
habitations for most of the commoner species of water-fowl. ‘The stately
great crested grebe visits these waters every spring to nest, with a popula-
tion per reservoir ranging from two to eight pairs. Avery few occurrences
of the sclavonian grebe (C. auritus), the red-necked grebe (C. griseigena)
and the eared grebe (C. migricollis) have also been recorded. ‘The rare
wood sandpiper (TJ. glareola L.) occurred at Swithland Reservoir in the
autumn of 1919. The reservoirs also provide excellent feeding-places for
herons. Leicestershire can boast of but one small heronry, at Stapleford
Park, the seat of the Hon. John Gretton, J.P.,M.P. Stapleford is situated
on the extreme eastern edge of the county, and the herons are very strictly
preserved. Early records show that herons have made unsuccessful
attempts to establish heronries at Mere Hill, Martinshaw Wood, Buddon
Wood and Bradgate.

The lapwing or green plover (V. vanellus) inhabits the low-lying
pastures in the valley of the river Soar in large numbers.

At Wanlip is a large extent of marshy land near the river, which is used
for the cultivation of osiers. ‘The bird population of this ‘ osier holt ’ is
extensive, and several pairs of reed warblers (A. streperus) nest there every
year. The grasshopper warbler’s prolonged ‘ reeling’ notes may also
be heard there almost every spring. In 1931 this interesting little visitor
nested near the village of Queniborough.

There appears to be a marked increase in the numbers of the tawny
owl of recent years, whilst the barn owl becomes correspondingly scarce.
The little owl is now all too common, though in 1907 it was a rarity.

36 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

The nightjar visits the county each year, and nests are frequently found
at Bradgate Park, ‘The Brand, and other parts of Charnwood Forest.

The nightingale is by no means a rare visitant, and reports of its singing
are annually received from many parts of the county.

Among records of casual visitors the following are worth noting: the
black-throated diver (C. arcticus) at Blackbrook Reservoir in 1919 ;
the peregrine falcon at Barkby Thorpe, 1930 and 1931; the spotted
crake (Rallus porzana L.) at Wanlip, 1919; the black redstart (Ruticilla
tithys L.) at Thurmaston, 1925 ; the dipper at Bradgate Park, 1913 (the
dipper was formerly resident there).

REPTILES AND BATRACHIA.

The common grass-snake (7. matrix) is still fairly frequent all over the
county, whilst the viper or adder (V. berus) and the common lizard
(L. vivipara), though not common, are occasionally met with, chiefly in
the Charnwood Forest area. No occurrence of the sand lizard (L. agilis)
seems to have been recorded to support Harley’s supposition that this
species existed in the county.

The blind-worm (A. fragilis) is still to be found, though it is not so
common as formerly.

The common frog and the toad are widely distributed, but the natter-
jack (B. calamita) has never occurred in the county. ‘The great crested
and the smooth newt are common, and the palmated newt is believed to
occur, though there is no reliable record.

FISHES.

According to early records the brook trout (S. trutia) was fairly plentiful
in many of the smaller streams. Its present status is entirely dependent
upon private enterprise in regard to re-stocking. Some of the large
reservoirs, including Thornton and Cropston, contain trout, but owing to
the enormous number of perch which have by some means been intro-
duced into these waters, they are only maintained with great difficulty.
Leicestershire waters have produced some very large perch. It is recorded
in the Victoria County History of Leicester and Rutland, 1907, that in 1888
two specimens taken from Thornton Reservoir weighed g lb. together.
The pike, too, is particularly abundant, and very large specimens have
been recorded from time to time.

The common carp (C. carpio) is to be found in many pools throughout
the county, whilst the crucian carp (C. carassius) is sparingly distributed.

The barbel (B. vulgaris) is practically unknown in Leicestershire waters,
though one or two examples have been taken by anglers at the confluence
of the rivers Soar and Trent. The gudgeon, roach, chub and dace are
all very widely distributed, but the rudd is very rarely met with. The
bleak, once very common, is now rarely seen. The common bream
(A. brama) and the white bream (A. blicca) both occur in the river Soar,
though sparingly of late years. ‘The species last named is common in
some of the larger pools in the county, including Groby Pool and Moira
Reservoir. ‘The stone loach (N. barbatulus) and the spined loach (C. tenia)
have both been recorded. ‘The former species is still to be found in the

THE ZOOLOGY OF LEICESTERSHIRE 37

small streams in Charnwood Forest. The ruffe (A. cernua) and the
‘bullhead’ (C. gobio) occur in parts of the river Soar. The three-
spined stickleback (G. aculeatus), which at one time infested almost every
brook and pool, is now not nearly socommon. ‘The minnow (L. phoximus)
is abundant in nearly all the brooks. The common eel is to be found in
most waters in the county. Early records state that the lamprey (P. flu-
viatilis) was very occasionally seen, but there is no evidence of this
interesting species having occurred during recent years.

THe FRESHWATER INVERTEBRATE FAUNA.

Leicestershire with its large reservoirs of Thornton, Saddington,
Swithland, Moira, etc., together with its innumerable ponds and ditches,
presents ample facilities for investigation to the student of the freshwater
fauna, and there is scope for an immense amount of intensive study.

Protozoa——Many well-known forms have a wide distribution in the
county. Actinophrys sol is to be met with in most suitable localities, while
Actinospherium eichornii is rather more local. Of late years the wider
distribution of Volvox globator has become noticeable, and it is now found
in places where it was formerly considered to be rare. Vorticella chloro-
stigma and V. globularia, although previously unrecorded, are frequent
in the river Soar, the former on Myriophyllum and the latter on Cyclops.
Other species hitherto overlooked or unrecorded are Ophrydium versatile,
Stichotricha secunda, Chilomonas paramecium and Phacus longicaudatus.

Porifera and Celenterata—There are two freshwater species to be
found in the county—Ephydatia (Spongilla) fluviatilis and Spongilla
lacustris. The former is to be found frequently in the river Trent and
river Soar, and the latter, previously recorded only for Saddington
Reservoir, is to be found also in the canal at Great Glen.

Hydra vulgaris, H. fusca and H, viridis are common. It is a surprising
fact that, although of frequent occurrence, Hydra viridis has never
previously been recorded.

Platyhelminthes —Little attention has been paid to this group. It is
noteworthy, however, that epidemics of Fasciola hepatica (the flat-worm
which causes ‘ liver-rot ’ in sheep) have considerably decreased owing to
better drainage of land and modern methods of treatment of infected
animals.

Rotifera.—Almost all stretches of water are profitable hunting grounds
for the members of this group. The ponds and ditches near Desford
have proved particularly good, such interesting species as Rotifer neptunis,
Scaridium longicaudum, and also Polyarthra platyptera being found in
abundance at certain times of the year. In the withy pickle-dykes at
Wanlip osier-beds are to be found Melicerta ringens, Stephanoceros
eichornii and Floscularia campanulata, while Floscularia cornuta, F. ornata
and Limnias ceratophylli are not rare in various parts of the county.
Perhaps the most widely distributed forms to be found in Leicestershire
are Proales werneckii, Rotifer vulgaris and certain species of Brachionus.

Annelida.—It is impossible at present to estimate how many different
truly aquatic species occur within the limits of the county ; that additions
will be made to the already published list there can be no doubt, for

38 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

Leicestershire abounds in suitable localities awaiting systematic explora-
tion. Here it is only possible to remark upon the present-day distribution
of a few interesting species. Nats proboscidea and Tubifex rivulorum are
common in most places ; in fact, examples of the former can be obtained
from any ditch or pond in the county, while the latter is especially abundant
in the reservoirs. Piscicola geometra occurs in many places, together with
allied species, and is often introduced with fish into the Museum aquaria.
In the lists given in A Guide to Leicester and District, 1907, the medicinal
leech (Hirudo medicinalis) is mentioned as having occurred within the
county ; unfortunately, neither date nor place of capture is stated, but
in all probability it is extinct in Leicestershire as elsewhere in England,
if indeed it ever occurred, for the fact that the horse leech (Hemopis)
occurs but is not recorded rather suggests erroneous determination.

Crustacea —Of the five species of Daphnia recorded, D. pulex is the
most widely distributed. In the canal at Great Glen, Ceriodaphnia
reticulata is common, while Scapholeberis mucronata is not rare in some
parts of the county. Bosmina longirostris is not uncommon, but the most
abundant Entomostracan seems to be Chydorus sphericus. ‘Two species
of Cypris have been taken, Cypris fuscata and C. virens. Limnocythere
monstrifica has occurred at Fleckney.

Some seventeen Copepoda have been taken in the county, but no doubt,
when more attention has been paid to the group, the number of species
recorded will be increased. ‘Two species of Diaptomus, D. castor and
D. gracilis, the former more frequent than the latter; ten species of
Cyclops and five species of Canthocamptus, constitute the present list.

Argulus foliaceus is abundant in all the reservoirs. A. coregoni has been
recorded for Leicestershire as the first British-taken example of this
species, but as there is some doubt as to its authenticity, this record is
unreliable.

That the freshwater crayfish exists in the river Soar at Aylestone
has long been known. Recently it has been taken in large numbers in an
artificial pond fed by a small stream at Desford.

INSECTA.

Coleoptera——The Coleoptera of the county have been carefully worked
by several well-known collectors in the past, amongst them Matthews,
Plant, Harris, the brothers Bates, Bouskell and others. The number of
species recorded by them is more than 1,700: quite a good proportion
of the British list. Many of these records depend on the capture of single
specimens which have not been taken since. The most noteworthy of
them was the first British record of Tvopideres sepicolafrom Buddon Wood,
but it has not been seen again. The rare weevil Trachodes hispidus,
which used to be sent all over the country to collectors, is still to be found
at Buddon. An old record of one specimen of the large water beetle,
Hydrophilus piceus, from Syston has been confirmed recently by the cap-
ture of two more from the same neighbourhood. The higher ground of
the Charnwood Forest, although the highest point is little more than
goo feet, has produced a number of mountain species, and the beetles
generally bear a striking resemblance to those found in North Wales.

THE ZOOLOGY OF LEICESTERSHIRE 39

Some of the later additions to the county list are the first British record
of the longicorn (Tetropium Gabriel’) from Sutton Ambion, since occurring
at Bardon and on the other side of the county at Keyham ; Gnorimus
nobilis, from Loughborough, said at one time to be extinct in this country ;
Cenopsis fissirostris, Bradgate Park ; Trachys troglodytes, Owston Wood ;
Aleochara brunneipennis, Sutton-in-the-Elms; Clytus mysticus, var.
hieroglyphicus, Wistow; and Cartodere filum, Leicester. Bembidion
obliquum and a few other species, said not to be found in the Midlands,
are common near the reservoirs.

In the Museum collection of Coleoptera all the local specimens are
marked with red discs, and the records, where there is no local specimen,
are indicated by red discs on pins.

Diptera—The most remarkable recent record is of a Dipteron new not
only to the county but to the British Isles—namely, Argyrameba (Anthrax)
anthrax Schranck, first taken by Mr. P. A. H. Muschamp at Woodhouse
Eaves in 1929. This specimen was presented to the British Museum.
In 1930 Mr. Muschamp took a second specimen at Cocklow Quarry,
which is now in the Leicester Museum collection. It is difficult to under-
stand how so distinct and striking an insect could have escaped observation
had it been long in this country, and the inference is that it is probably
a recent importation.

Hymenoptera Aculeata—It is evident from the brevity of the list of
Hymenoptera Aculeata published in the Victoria County History of Leicester-
shire in 1907 that these insects had not up to that date been seriously studied
or collected in the county. Only 65 species are enumerated out of more
than 350 species then known to inhabit Britain. Many additional species
have since been caught in the county, but there is room for much more work,
particularly in the direction of investigating habits and life-histories.

In the absence of sandy tracts of country, the old mud-walls (now,
alas | fast disappearing) supply favourite nesting sites for many burrowing
species, and others find a congenial habitat in the waste heaps from quarries,
when the heaps have been for years undisturbed—as in some parts of the
Mountsorrel area.

This is not the place to enumerate the additions to the Leicester list,
and only two will be mentioned as typical of many. One is an interesting
new local record among the fossorial forms, namely Agenia variegata Linn.,
a small black digging-wasp which provisions its nest with spiders. Each
spider is paralysed by a sting in one or more of the nerve centres, and so
keeps alive and fresh until devoured by the larva of the digger-wasp. The
first specimen was taken on the top of one of the characteristic dry stone
walls of Charnwood Forest near to Stoneywell Cottage, in the act of
dragging a benumbed spider to its burrow. Others have been taken
since in various parts of the forest, so it is probably not uncommon,
though previously overlooked.

Among the Anthophila perhaps the most interesting new record is
Anthidium manicatum Linn. This bee has been regularly observed for
several years flying at the downy Stachys Janata in a garden on the out-
skirts of Leicester, in June and July. It appears to visit nothing else.
The females visit the flowers for the purpose of collecting nectar and

40 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

pollen, while the males appear to visit the plants only in search of the
females. The flight of this bee is swift, and it hovers like a humming-
bird before the flowers. Oswald Latter says that its nest is like a ball of
white wool, and Gilbert White states that it visits the garden campion
for the sake ofits tomentum. It was suspected to be frequenting Stachys
lanata for the sake of the tomentum, but, though watched carefully many
times, the bee was never detected in the act of gathering or carrying the
down. Nor has a nest been found. The connection between Stachys
lanata and Anthidium manicatum seems close. In early July 1931 a large
patch of the plant was noticed in a garden near Oxford. On going up
to the patch, Anthidium was seen flying in numbers before the flowers.
Any entomologist in the neighbourhood of Leicester could attract Anthidium
manicatum by planting a good patch of Stachys lanata. It is much to be
desired that local students should take up the investigation of the many
biological problems which the Hymenoptera Aculeata present.

The information given in the foregoing brief notes on the Leicester-
shire fauna is necessarily somewhat disconnected and very incomplete.
Members of the British Association who désire further information,
however, are cordially invited to consult the members of the staff of the
Leicester Museum, who will be pleased to help as far as lies in their power.
They would also put visiting members in touch with local workers.

V.
THE CLIMATE OF LEICESTERSHIRE

BY
E.G. BILHAMspiR:Se,,. DIC.

General Conditions—Records kept—Rainfall—Temperature—Humidity— Wind
Direction—Sunshine—Hail— Thunder—Frost.

From the climatic point of view Leicestershire may be regarded as
typifying the ‘inland’ conditions of Great Britain, uncomplicated by
large masses of high-lying land. A line drawn westward from Lowestoft
and a line drawn northward from the Isle of Wight intersect within the
county, which thus lies, as nearly as may be, in the centre of England.
We should expect the climate of Leicestershire, therefore, to exemplify
almost the highest degree of ‘ continentality ’ possible in a land mass of
the size and geographical situation of Great Britain. That is to say, we
should expect a large diurnal and annual range of temperature, a high
frequency of ground frosts and radiation fogs, and a well-marked.
development of diurnal convective phenomena.

THE CLIMATE OF LEICESTERSHIRE 41

Unfortunately the county has never been very well served in regard to
climatological observations, and we are obliged to rely, except in respect
to rainfall, very largely on the records from Belvoir Castle, which is very
near to the north-eastern boundary of the county. In recent years we
have records from Lutterworth, kept by Mr. M. W. Binns, whose kindness
in supplying data I am glad to acknowledge. At the moment of preparing
these notes I have also learnt of a long record kept at Woodhouse Eaves,
near Loughborough, by Colonel Dashwood, but it has not been found
possible to carry out the work of summarising his observations in time
for inclusion in this article.

The station at Belvoir Castle, maintained by the Duke of Rutland, K.G.,
began observation of rainfall in 1855, of temperature in 1896, and of
sunshine in 1906. Averages of these elements, weighted to the standard
period, 1881-1915, are printed in the Book of Normals, Section I. In
the case of temperature (maximum and minimum and mean), averages
for the period 1901 to 1930 have recently been computed, and I am
enabled to include these by permission of the Director of the Meteoro-
logical Office. The observations at Lutterworth refer to the period 1921
to 1932.

RAINFALL.

The mean annual rainfall of Leicestershire varies from about 23 in.
near South Wigston to nearly 29 in. on the high land in the Charnwood
Forest area. Only a small portion of the county has an annual fall
exceeding 27:5 in. Table I shows the mean monthly and annual
totals (referred to the epoch 1881-1915) at three stations, from which
long records are available. It will be seen that October and August are
the wettest months, April and February the driest. In Table II the
rainfall at Belvoir Castle is dealt with in greater detail. The average
annual number of days of rain (o-o1 in. or more) is distinctly higher than
at other places, such as Camden Square, London (163), Shrewsbury (166),
Oxford (168), Hull (185), Wakefield (165), and Portland Bill (163), where
the rainfall is about the same as at Belvoir Castle. Rain occurs on about
two days out of three in October, November and December, and is least
frequent in June, when days without rain outnumber days with rain in
the ratio of three to two. The wettest months of any name were July
1880, and July 1932, in each of which the fall was 6-59 in., or 271 per
cent. of the normal July total. Reckoned as a percentage of the normal
for the month, the rainfall of April 1920 (329 per cent. of the normal)
occupies first place. The driest months were February 1891, and March
1929, in each of which the fall was only 0-07 in. The highest yearly
total, 35-73 in., or 142 per cent. of the normal, occurred in 1882, and
the lowest, 16-05 in., or 64 per cent. of the normal, in 1921. From
data given by Dr. J. Glasspoole,! it appears that the standard deviation of
annual rainfall over Leicestershire is rather more than 18 per cent. of
the annual total. The heaviest rainfall in a day (24 hours to g h.) occurred

1 ‘The relation between annual rainfall over Europe and that at Oxford
and at Glenquoich,’ British Rainfall, 1925, pp. 254-269.

42, SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

on August 6, 1922, when 3-62 in. was measured. At Leicester on that
day, 2-15 in. fell in 12} hours.

At Lutterworth the driest month was June 1925, with a fall of 0:06 in.,
and the wettest, May 1932, with 5-62 in. Mr. Binns points out that
the driest spells of weather and also short heavy downpours associated with
thunder usually occur with winds in the north-east quadrant.

TaBLe I—MOonrTHLY aND ANNUAL RAINFALL (1881-1915).

Kebworth Thornton Belvoir
Beauchamp. Reservoir. Castle.
Latitude. ‘ 1g2° 32 NUP. Psa ag Nos seater
Longitude «. : . 1 Oo W. 1°) 48" W Codie aay
Height above M.S.L. . 390 ft. 371 ft. 259 ft.
In. In. In.
January I-go 1-98 £279
February 1-69 1°67 1°67
March 1-78 1-84 1°81
April . RA of 1°70 Teas
May . 1°88 2°O1 2°11
June . 1°94 2°16 I-QI
July 2°58 2°48 2°43
August C 2272 2°80 2°62
September . 1°87 1-81 1°87
October. 2°82 2°81 2°70
November . 2°26 2°26 2-20
December . 2°56 2°68 2°46
Year : b t ¥25367 26-20 253e0E

‘TEMPERATURE.

The only long series of temperature records available for reference is
that for Belvoir Castle, going back to 1896. Table III shows the mean
monthly and annual value of daily maximum and daily minimum in the
24 hours to 21 h. and the mid-temperature computed as half the sum of
maximum and minimum, for the period 1901 to 1930, together with
extreme values from 1896 to 1932. It may be noted that although on the
average July is decidedly the warmest month, the highest recorded
temperatures have occurred in August and September. In July, go° F.
has been reached on only one occasion, viz. July 10, 1921. A temperature
below 32° F. in the screen has occurred in every month except July and
August. The lowest recorded temperature, 7° F., occurred on January 17,
1926, during a noteworthy cold spell in which a grass minimum tempera-
ture below zero Fahrenheit occurred at several inland stations in southern
England. The mean diurnal range of temperature is 14-2° F. The
corresponding ranges at a few other inland stations at about the same
height above sea-level are as follows : Rounton (Yorks.) 13-9° F., Little
Massingham (Norfolk) 15-0° F., Woburn (Beds.) 15-3° F., Belper (Derby)
13:2° F., Coventry (Warwick) 15-2° F., Hereford 15-5° F., Ross-on-Wye

43

THE CLIMATE OF LEICESTERSHIRE

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44. SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

15°4° F., Cheltenham (Glos.) 14:6° F., Reading (Berks) 15:6° F. The
extreme values recorded at Lutterworth in the period 1921 to 1932
slightly exceeded those for Belvoir Castle, but do not otherwise call for

special mention.

Tas_e [1] —TEMPERATURE (BELVOIR CASTLE).

Mid-
Wea Highest Daily Mean| Lowest Daily /Tempera-
Max Max. Min. Min. ture
"| (1896-1932.) (1896-1932.) + (max.
-+ min.).
se NS oa syle Be ve
Ist, 1916)
Jan 43°6| 57 49th, 19217| 33°7 | 7 r7th, 1926 | 38-7
eee 1922
7th, 1917
Feb; Aas? Whe. Groth (1899) 43381 ke-9 4 E4th, 17th soy
{23rd 8 aie |
)
March. | 48-1 | 69 loath, aot 34.°5-}-13- s- 49th, 1947 AE*3
April EasOoh wher aend estas 43770 | 10 . 2ni, T9or7 45°0
IgOl
May 60-24). 840 23rd, 1922. | 43°1 | 26 ““th, 1967 51°7
6th, 1896 |
June 65-1 | 86 nw eee 47°5 | 302 Beth, aor 56-3
, . {r1th, 1917) ‘
July 69-0 | go" roth, 1928 <|"5r-5 | 35 Uist. oat | 60°3
Aug. 67°7 | 95 9th, r91r | 50-9 | 34 3xst, 1919 | 5973
Sept. 63°31, 92 < Ist, 2nd) |-46"9° j.29 28th, 20th, | 5522
1906 I9Ig
Oct. 55°O | 7o": ‘6thyiz92r |'42'o)'|.23) vagthi roar 48-9
th,
Nov Aza)! O30 «2nd. 1927) |. 30-0, | 15 loc. Babs f)40°7
Dec 44°0 | 59 4th, 1931 | 34:2 | 10 30th, 1908 30°21
Year BS i} Oh) CAugiothy 4 Aie=9 jronth, Janr rghe 48-0
IQII 1926
HumiIpiry.

Table IV gives the mean values of relative humidity and vapour
pressure in millibars at Belvoir Castle for the 25 years 1896 to 1920,
based on readings of dry and wet bulb thermometers at g h. and 21 h.
The tabulations of hourly values of relative humidity at observatories
show (a) that the average value of the relative humidity at g h. and 21 h.
gives a close approximation to the mean for the day, and (b) that the

THE CLIMATE OF LEICESTERSHIRE 45

vapour pressure at 21 h. is on the average nearly the same as at the time
of occurrence of the maximum temperature and minimum relative
humidity. Consequently a close approximation to the mean value of the
daily minimum relative humidity can be obtained from the relation

Minimum R.H. = —V-P-2¢2t b._ y 200
Sat. press. corre-

sponding to max.
temperature

Data calculated from this relationship are included in Table IV.

TaBLe 1V.—Humipity (BELVvoIrR CasTLe, 1896-1920).

Vapour Pressure. Relative Humidity.

Mean of Mean
ah. oe Oe aeeealaan gh.and2rth.| Minimum.
mb. mb. % a Je ye

Jan. 6-9 TEEN SORT (A OL 92 74
Feb. . 6°7 6:8 87 87 87 71
March 733 2 88 88 88 63
April . 8-2 8-0 80 84 82 58
May . 2 Og LON 77 84 80 57
hanie’) « + Pees 12" 3 Fig) 84 80 58
July . 14° 13°9 78 85 81 57
Aug. . I4°0 13°6 80 86 83 59
Sept. . T2395 11-6 83 88 85 58
Oct. . 10°2 Hoa 89 gl go 66
Nov. . 8-1 8-2 gI gI gi 73
Dec. . 7°4 775 | 92 | 92 92 77
Year . 9°9 9:6 85 88 86 66

The results show that Belvoir Castle experiences a high average moisture
content of the atmosphere. From October to January the average
relative humidity (mean of g h. and 21 h.) reaches go per cent. or more.
The mean values of daily minimum relative humidity do not differ much
from those computed for York.?

WIND DIRECTION.

Table V shows the percentage frequencies in each month, and the
year of winds from the different points on the 8-point scale as determined
from the observations at Belvoir Castle in the period 1896-1930. The

2 ‘ The climate of York,’ Scientific Survey of York and District, B.A., 1932.

46 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

results show the usual predominance of winds from south-west, particu-
larly in the winter months. East winds are very infrequent, averaging
only 2:5 percent. North and north-east winds show a marked maximum
frequency in the spring and early summer.

TaBLE V.—WIND FREQUENCIES
(BELVOIR CASTLE, 1896-1920).

Percentage Frequencies of Wind Direction (9 h. and 21 h.).

Caton, Ne NE oo ES ev nt eee ane eee

To |e folio thi %o, |. 7 1/0. | ave) | eam cave
Jan. 10°3 | 5°9| 4:1 | 2°3 | 5°9 | 17°2 | 32-0 | 13-1 | 9°3
Felal) | 1rho 89643) |) ¢4:-0}|)a°'7 | 6-2 | 20-1 |,29°1" | 1256)" 920
March!y| 12:oligxofp | 9°3:|'2-0 | 3°9 | 14-9 "| 25; EU! 13"0 | 10°9
April cl 13°93. \_mge8! og: 3} aca |.5-0.). 20-8 4tp- yl Oe sz 3
May .)\57-x 16ers! | 52-3) | 309 | -5:-8.1 20-7 naw | Teta 87
Junes." |), 20"G, 04" Shleso' 71,64 | 54.) 10s | cae) Opeg aae
July2. |, 20°2 6118) |ou5-8)| 286 | 4525) 10-0-)-18*3 | 16:05) 1226
Aug, . | 26-Sdle 9° E! |) a3e3hhite2 |°327-| 13°01229: 74) 5eO 1s op
Dept. . || 17°T deto-4) | grzil Se2 | 5:40] 13°20) 20-g | 1350 oss
Oct, .).| ROrG1o Fe 4 |p 52: |. Set 4570.) 20-0, |-2e-Aigiso-2 i eorp
Nowe . || t5*o lo 8-2, (ae 8h\a77. |. 4:6.) 16°01) 20-3 | T2:Qrlro ed
Dee, eat Ip Aro) neae 7 eeet [Set | 20°45) 34 Sa] TE Gn
Wear.) /' 05 "4 Jo O+7;.| 60°! | 2am 5405). 14°9.| 23; Fanta tero

The station at Belvoir Castle is not well exposed for observations of
wind force. From observations of the highest wind each day at
Lutterworth, Mr. Binns concludes that January is the windiest month and
September the quietest.

SUNSHINE.

In Table VI the first column of figures shows the mean daily duration
of daylight in each calendar month. The second column shows the
mean daily duration of sunshine, adjusted to the standard period 1881—
1915, as registered by the Campbell-Stokes sunshine recorder at Belvoir
Castle. ‘The third column shows the mean recorded sunshine expressed
as a percentage of the possible duration—that is to say, as a percentage of
the value given in the first column.

May is the sunniest month, with an average daily duration of 6-55 hours,
42 per cent. of the possible amount, a value which compares favourably
with the records at other inland stations. ‘The winter sunshine at Belvoir
Castle is relatively abundant, being exceeded only at stations on the

THE CLIMATE OF LEICESTERSHIRE 47

east and south coasts. The yearly mean daily duration, 4-21 hours, is
compared below with corresponding data for other inland stations.

Belvoir Castle . . 4°21 hours
Cockle Park (Northumberland) 428994 .}
York . ABT &
Cambridge . d i A ag?',,
Rothamsted (Herts) 422"? 5
Harrogate G:Or-9
Sheffield Z°6r os
Nottingham 3 63.4 AN
Oxford es ig ar
Cirencester Eg!
Greenwich J : ; Tahar ORI f
Stonyhurst . F : ‘ 2 TAZA! OLN
Bath . : ; , ; Se oc ae

The mean value for the ‘ Midland Counties ’ district, as defined for

official climatological purposes, is 3-82 hours, a value exceeded at Belvoir
Castle by ro per cent. ;

TaBLE VI.—SuUNSHINE AND MISCELLANEOUS PHENOMENA
(BELVorR CasTLE).

Sunshine, 1881-1915. Mean Number of Days of :
Mean | Bright Pp Snow, P peli Hail, Thunder, Ground
Length | Sun- | P& |,896-IY™81;896-| 1896— | Frost,
8 . cent. |1°9> |rg13-°9 ag 1908—
of Day. | shine. 1930, ro30,| 1930 1930. 1930.
Hrs Hrs. A
aie). ore 1°74 AT (OR a heal oe orl 16°3
Pepe. 2) ery iad ae LO) 273 Ont EO) LO" & 673 ar
March. | 11-78 3°58 307 5 | LAr eee Ong 14°5
pat y..| 13-88 | 5-50 |-40 | r-7-| 0-4.) D1 1-4 IL" 5
Mayer -. 0)... 25°73 6°55 42 |.0°3 o | 0:8 A082 4°1
June . | 16°75 G84 38 fo) 0 | 0°3 3-9 0'9
ary) £O"S9 "| 6-23 38 fe) 0 | 0-3 4:0 fe)
meee ..| 14°67 | 6-00 | 41 fo) Oo fo) 3°9 fo)
pept. ...|. 12°66 | 4°83 38 ) Oy|,,0*2 ge E32
Oet.y. 110-58 3°35 32 | o'r ovo-3 [4 vo“8 7°0
Nov. .| 8-68 | 2:23 26 | 1-4 |'0°3:}'0*3 0°2 13°9
Pecs6, 7°60 | 1°45 19 | 3°1 | O-9 | o-4 Orr 14°4
Meat b..|.12:22 | 4-21 34° /19°8 | 7-1 | 5°7 | -19°9 99°5

48 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

MISCELLANEOUS PHENOMENA.

The right-hand portion of Table VI shows the mean monthly and annual
frequencies of days of snow, snow lying, hail, thunder and ground frost
as observed at Belvoir Castle. A day of ‘ snow lying ’ is defined as one
on which more than half of the country surrounding the station is covered
with snow at the time of the morning observation. A day of ground
frost is one on which a minimum thermometer exposed on short grass
registers 30°4° F. or below. Similar data for other stations are given in
the Book of Normals, Section IV. The frequency of days with snow
has varied from 3 in 1928 to 53 in 1917, in which year there were 44 days
of snow lying. ‘There were 39 days of snow in 1919 and 37 in 1906.
Hail is relatively infrequent, but occurs most often in the spring months.
Thunder, with an average frequency of 20 days a year, occurs more often
at Belvoir Castle than at any other British station for which the data are
available, a fact which seems to indicate that Leicestershire is in the
region of maximum thunderstorm frequency for the British Isles. As is
commonly the case in the Midlands and the south-eastern half of England,
the months giving the highest frequencies of thunder are the summer
months from May to August.

Ground frost is frequent but not remarkably so, considerably higher
frequencies being observed at some other inland stations. During the
year 1932, for instance, there were 184 ground frosts at Rickmansworth
(Herts), 132 at Sprowston (Norfolk), 131 at Chelmsford (Essex), and
135 at Ascot (Berks), as compared with g5 at Belvoir Castle.

VI.
FARMING IN LEICESTERSHIRE

BY

THOMAS HACKING, M.Sc.,
DIRECTOR OF AGRICULTURE AND AGRICULTURAL ORGANISER FOR
LEICESTERSHIRE.

Rock formations—General Characteristics of County—Soils—Management of
Grassland—Vale of Belvoir—Western Area—Melton Mowbray Area—
Agricultural Statistics—Decline in Arable Land—Crops and Grass—Cattle—
Sheep—Pigs—Horses—Cereals and Potatoes—Permanent Grass—Agricul-
tural Holdings—Agricultural Workers.

THE agriculture of a county is largely determined by its geology and
climatological conditions. If we take a brief general survey of
Leicestershire, we shall find the rocks fall into five broad divisions :
(1) In the north-west rises the hilly, almost mountainous region of
Charnwood Forest, composed of very ancient igneous and meta-
morphic rocks.

FARMING IN LEICESTERSHIRE 49

(2) Westward of Charnwood Forest and extending across the western
boundary of the county into Derbyshire, the coal measures, with
their accompanying beds of grit, shale and limestone, form the
region known as the Leicestershire Coalfield.

(3) ‘ Red Rocks’ of Triassic age form much of the land north, east,
south, and south-west of Charnwood, covering, in fact, the greater
part of the western half of the county. The river Soar may be
regarded as the eastern boundary of this division.

(4) In the eastern half of the county, stiff bluish clays of Liassic age
preponderate, with a hard bed of marlstone, whilst above them
in the extreme north-east, and in one or two outlying patches else-
where, sand and limestone of Lower Oolitic age are found.

(5) Lastly, scattered in varying thickness and with great irregularity
over all the rocks mentioned, there are beds of clay, gravel, and
sand, with occasional boulders of varying size which are described
as ‘ Drift —relics of the last glacial period, or Great Ice Age,
when the Midlands were covered with sheets of ice. The alluvial
deposits in the valleys of the main rivers are extensive and give
rise to fairly rich soils which are liable to repeated and extensive
flooding.

GEOLOGICAL CHARACTERISTICS.

The nature, composition, and arrangement of the underlying rocks
have a most important bearing upon the formation of soils as well as
their subsequent cultivation. The average rainfall of the Midland area
is by no means high, and the general topography of Leicestershire is that
of a gently undulating county, which only rarely exceeds 600 feet above
sea-level. ‘Though the county does not possess many large rivers it has
a large number of well-distributed small streams of great value to the
farming industry ; these serve as tributaries to the Soar, Welland, and
Wreake, which are the main rivers in the county. It should be noted,
however, that at certain points on the county boundary the rivers Trent
and Avon are reached, though only over limited distances,

SOILS OF THE COUNTY.

The soils of the best grazing area are varied. The eastern half of
Leicestershire and part of Northants and Warwick lie chiefly upon the
lower Lias clay, and soils from this formation are to be found in the
valleys, as in the Vale of Belvoir, where many excellent pastures lying
directly on the Lias clay are to be seen. ‘The outcrops of the middle
and upper Lias generally appear upon the gently rising slopes and summits
of the rounded hills. Over the whole of the Lias formation, and especially
in the more elevated parts of this roughly defined Midland area, varying
expanses of boulder clay are met with and patches of glacial drift are not
uncommon. ‘These give rise to soils of a sandy and gravelly character,
usually supporting a herbage of only moderate quality, but generally
making good land for the rearing and growth of store cattle and sheep ;
and occasionally the best of this type of land will fatten heifers quite
satisfactorily.

D

50 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

In the Market Harborough district many gradations of soil from a
tenacious clay to medium loams are met with, most of which, in the
hands of experienced graziers, produce beef and mutton of the very best
quality. Some of the best old pastures have been down in grass for a
large number of years. We know very little as to the conditions under
which these pastures were seeded—probably they were self-sown, or it
may be, in those far-off days when enclosure took place, the natural grass
and clover seeds were used, and these were probably obtained from the
bottoms of haystacks ; at any rate, we have no definite knowledge about
the early conditions under which these famous grasslands were sown
down. But in recent years much valuable scientific data relating to the
chemical composition of the soils and the botanical character of the
herbage has been obtained, and in addition there is also much practical
information available as to the system of management pursued on these
pastures which has been carefully recorded by several observers during
the last hundred years. The best of these pastures have received very
little more than the droppings from the sheep and cattle which have
grazed them, many of them have never received fertilisers of any
description, they have never been mown, and cakes or other concentrated
foods have very rarely been used, and then only for a very limited portion
of the grazing period. When the soils are examined, analyses show that
they are in a fertile condition, usually rich in phosphates, potash, lime
and nitrogen, and similarly the analysis of the herbage shows that the
soil fertility is reflected in a herbage of superior quality, and surprisingly
simple in its composition in so far as the species of herbage plants are
concerned. The truth is that the finishing of full-grown cattle and sheep
on this land does not make a serious demand on those constituents of
the soil upon which fertility depends. These pastures have always
been heavily stocked and well grazed, and consequently there is rarely
any indication of anything in the nature of ‘ tuftiness’ or matted con-
ditions of surface ; the constant trampling by cattle and sheep maintains
the surface soil in excellent condition. ‘The scythe may occasionally be
used to mow coarse or strong-growing patches, and this helps to keep the
pastures uniform ; and in addition great care is taken to spread evenly
all manurial droppings, a process known locally as ‘ clot knocking.’ In
years gone by it was a common practice to collect ‘ clots,’ which were
carefully preserved and spread over the weaker portions of the pasture
during the following autumn and winter months. The fences, mainly
whitethorn, are well kept, and a special feature is made of providing well-
constructed drinking-places for the grazing stock. ‘Thistles are kept
under rigid control by spudding and pulling: local blacksmiths make
a special kind of implement for the purpose of pulling thistles which is
very effective.

MANAGEMENT OF GRASSLAND.

The management of the grassland in this area is of a distinctly high
character ; it is, in fact, a fine art—the grazier’s art—which has done so
much to make the Harborough district famous. Its graziers possess an
unrivalled knowledge and judgment of the merits of grazing cattle and

NN <r Cr er eee

—

FARMING IN LEICESTERSHIRE 51

sheep. The occupation of the grazier is one of very great interest, and
whilst perhaps not so strenuous as arable or dairy farming it offers
considerable variety. The management of land and stock occupies the
grazier’s close attention for a considerable portion of the year, but
opportunities for relaxation are usually sought in the hunting field during
the winter months ; many good graziers are ardent supporters of fox-
hunting, and excellent horses, both hunters and shires, have been bred
in the Harborough country.

The chief breeds of cattle grazed in the Market Harborough district
include Shorthorns, Lincoln Reds, Herefords (pure and crosses), Devons,
Aberdeen Angus, and Angus and Shorthorn crosses, whilst the sheep are
usually crosses of Suffolk or Down breeds crossed usually with Border
Leicester, Cheviot or half-bred or Mashams. These make excellent
grazing sheep and during recent years have become exceedingly popular.

During the early part of the grazing season 1931, the following notes
were made in order to show how some of the best grazing fields were
stocked about the end of May or early June in that year :

Field. Acreage. Bullocks. Sheep.

I 9:0 9 12
2 5°7 8 15%
3 28-0 27 25
4 136 14 14
5 16°2 20 22
6 14°4 18 22

86° 96 95

The foregoing table shows clearly that the stocking of good pasture
land is very heavy and has much to do with maintaining these pastures
in a condition of high productivity.

THE VALE OF BELVOIR.

The Vale of Belvoir in the north-east of the county is mainly given
over to the grazing of cattle and sheep and the production of milk, which
is partly sold for the liquid milk trade, though a very great proportion
is used in the manufacture of the famous Stilton cheese for which the
Vale is well renowned. The Sixhills district comprises a wide area of
land of moderate quality, mostly in grass, and here milk production and
the rearing of young stock is pursued in conjunction with the breeding
of sheep.

THE WESTERN AREA.

The western half of the county is given over to farming of a rather
more mixed character. On the ploughed land, wheat, oats, barley,
beans, sugar-beet, mangolds, and other green crops such as cabbage and
kale are grown, but the majority of the farms are mainly devoted to milk
production. In rather scattered and isolated areas Leicestershire cheese
is still made, though not to the same extent as in former years. With

52 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

regard to sheep, it is a remarkable fact that the famous breed of Leicester
sheep is not found in the county ; this breed, which is popular in many
parts of this country and has also a great reputation in the colonies, was
the outcome of the work done in breeding by the famous Robert Bakewell,
who was born and died at Dishley Grange, near Loughborough (1726-1795).
The last pure-bred flock of Leicester sheep was kept for many years at
Beau Manor, near Loughborough, but this flock was dispersed several
years ago. Bakewell also did much to improve the breed of Longhorn
cattle, and whilst there are no herds of this breed in this county, it is
well to note that the work he carried out at Dishley in the eighteenth
century had much to do with laying the foundations of a system of farm
live-stock breeding for which Great Britain has become deservedly
famous.
THe MeLTON Mowsray AREA.

There is also marked agricultural activity all round the famous hunting
centre of Melton Mowbray. Here excellent grazing land is to be found,
and to the north-east considerable areas of ploughed land on the red
soils of the middle and upper Lias. More limited in extent but under
the plough are the lighter soils on the Northampton sands and Lincolnshire
limestone ; here sheep and arable farming are closely connected. During
recent years good progress has been made in this district in the application
of co-operative principles to the business of marketing agricultural produce.
The Farmers’ Co-operative Association controls an extensive business
which deals with the disposal of cattle, sheep, pigs and poultry; a
successful National Mark egg depot is also in operation which has done
much towards developing a keen interest in the extension of the poultry
industry, and most of the eggs produced are now graded and sold under
the National Mark and through a progressive collecting depot. The
Association also conducts a butchery business very successfully, and for
this purpose the animals are supplied by its members. Agricultural
co-operation has had a chequered experience in this county, but it is
gratifying to note that co-operation amongst farmers at Melton Mowbray,
Long Clawson, and other places in the Vale of Belvoir has been very
successful. Progress at most of these centres has been largely due to
enthusiastic leaders who possessed a wealth of energy and sound practical
judgment, and have been imbued with a keen desire to be of service in
securing the improvement of marketing conditions. ‘The country to the
south and south-west of Melton Mowbray is mainly in grass and on the
whole well farmed, and is of a gently undulating character. ‘This area
comprises the land over which the famous Quorn pack is regularly hunted.
Lying still further south is the almost equally famous Fernie country
occupying much of what is called High Leicestershire, and centring
round Billesdon Coplow. Both ‘ countries’ consist of rolling uplands
requiring the best of horses and horsemanship, and some excellent
hunters are bred and trained in these areas.

AGRICULTURAL STATISTICS FOR LEICESTERSHIRE.

Like the farming in most counties, that of Leicestershire has under-
gone many changes, and the following statistics have been chosen with

FARMING IN LEICESTERSHIRE 53

the object of showing the nature and extent of such changes, especially
with regard to cultivated land and the fluctuation in crops and stock.

Total area (excluding water) ; . 1932 530,642 acres
Total acreage under crops and grass . 1932 457,930 ,,
Rough grazings ‘ : . - 1932 g 072+? ts

Decline in Arable Land.

ear, Acreage.
1870 179,892
1875 176,249
1895 120,854
1914 96,977
I9Ig 131,023
1923 107,962
1926 92,189
1933 731542

From the foregoing table it will be seen that during the last sixty years
or so the arable area has decreased by over 100,000 acres. In more
recent years, notably the period between 1919 and 1932, it shows a
decrease of no less than 57,481 acres, and this in a period of only thirteen
years. Even in the acreage under crops and grass there has been a
serious decrease, owing, no doubt, to the extension of building schemes
and other demands upon the agricultural area of the county.

The enormous change in the arable area has undoubtedly produced
very great changes in the systems of the farming pursued and -has had
far-reaching effects on the social life of the country side. Broadly the
results have been a serious and steady decline in the numbers of the rural
population and consequently the local and allied industries such as those
of the blacksmith, wheelwright, and saddler have also declined and in
some districts have disappeared entirely.

Generally speaking, grassland requires far less labour than arable land,
and is usually less productive, though in the case of dairy farming the
aggregate value of milk produced may well be greater than the value of
the crops when the land was under the plough. The number of active
farm workers in such cases may not be seriously less, but taking the situa-
tion as a whole, it is certain that this great change in arable farming has
been accompanied by a very considerable decline in the number of agricul-
tural workers. A still more serious feature of the decline in arable land
is the fact that during the last ten years there has been an average annual
decline of nearly 3,500 acres, equivalent to an area of about 5 square miles
per annum.

CROPS AND GRASS.

A steady decline in the acreage of crops and grass is also taking place
and the figures show that there has been a decline of over 9,000 acres

54 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

during the last ten years, which means a serious encroachment upon the
farming area of the county.

Year. Acreage.
TQ22 he. 5 - . 460,978
TQ bails . , = (r459:049
Lg2z0t : : . 456,306
1932, -% : ‘ . 451,930

CATTLE, INCLUDING DaIRY AND GRAZING STOCK.

Between 1915 and 1923, the cows and heifers increased by 8,755.
This increase was spread very evenly over every Petty Sessional Division
and showed that the change over to milk production was taking place
more or less throughout the county.

During the last ten years the number of cattle has not altered to any
very serious extent, though there has been a steadily increasing tendency
for farmers to extend their activities in milk production, and consequently
dairy cows have further increased in numbers. As to breeds of dairy
cows the Shorthorns are pre-eminent, though excellent herds of Jerseys,
Friesians, and Ayrshires also exist in the county. ‘The business of milk
production has reached a very high standard and flourishing associations
for milk recording and graded milk have been in existence for several
years and have done excellent propaganda work. During recent years
improved methods of feeding and equipment have been adopted, and over
one hundred milking machines are now in regular use.

The breeding of good dairy cattle has been materially assisted by the
Ministry of Agriculture’s Live Stock Improvement Scheme, under which
are placed at various centres in the county no less than thirty-four premium
bulls. With regard to grazing cattle, a large proportion are bought as
stores and brought into the county during the autumn and spring ;_ they
comprise a wide range of breeds such as Shorthorns (both English and
Irish). Aberdeen Angus, Devons, Welsh, Herefords, and their respective
crosses are very popular with the Leicestershire graziers, but it should be
here recorded that the grazing industry, like other sections of British
farming, has experienced very difficult and unremunerative conditions
during the last few years, and a careful analysis of live stock statistics show
that a gradually declining number of cattle have been grazed in recent
years. Improved prices would no doubt do much to improve the grazing
industry.

The following table gives the figures of dairy and grazing stock and
other cattle from 1923 to 1932:

Year. Head of Cattle.
TO230:* 5 . : 4 149,107
1925°™. : : . 161,049

1926. 2 : . 158,387
1932. : : . 156,996

FARMING IN LEICESTERSHIRE 55

SHEEP.

Sheep have been steadily declining in the county for many years and
between 1915 and 1923 there was a decrease of 59,798, but the following
figures for the last ten years indicate that a steady recovery is taking place.

Year: No. of Sheep.
LOSS ts . P +n ihQ2,102
TO ar : : wn BBA 570
1020) . 2 - 253,485
to gy a é : . 312,490

Whilst there have been great changes from the plough to grass, the
increase in the number of dairy cows limits the grazing area available for
sheep, and for many years a steady decline in the numbers of sheep has
been experienced. In 1923 the figures for sheep were the lowest ever
recorded in the county.

Since that year there has been a steady increase up to the end of 1929,
when sheep made reasonably good prices ; then came a sudden and serious
depression in the price of wool as well as mutton. At the present time,
however, the price of mutton shows a gradually improving tendency,
though wool remains at a very poor price. The favourite breeds of sheep
for a long period included Leicesters, Lincolns, and occasional flocks of
Down sheep, such as the Oxfords, Suffolks, Dorset Horn, Hampshires,
etc. The heavier breeds are gradually giving way to breeds of sheep
which are more suitable for grassland conditions and recent years have
seen considerable introductions of the half-bred, Border-Leicester, and
Cheviot cross, pure Cheviots, Kerry Hills, Cluns, Mashams, and many
crosses with Suffolk, Oxford, and Hampshire rams. There has been a
tendency to concentrate upon the production of fat lambs, which have
yielded, under good management, fairly satisfactory results. Recent
prices of wool have not been encouraging, but should an era of better
prices set in, it may be safely prophesied that the sheep population will
continue to increase, but it is extremely probable that any such extension
will be almost entirely amongst breeds suitable for grass feeding.

Pics.

The variation in the numbers of pigs in Leicestershire is shown in the
following table :

1923 . . - 23,547
TOAG Ys : ‘ » ene OZ
1926. : j Pies iO 9
TO32" *"s 4 : 26,7770

The pig population of Leicestershire was much greater in the years
when larger quantities of Stilton and Leicester cheese were made. ‘The
whey, a by-product in cheese making, is a very useful addition to the
usual meals used for pig feeding, but with the decline of this by-product
pig feeding became a less attractive section of farming, and the increase
of imported bacon was also a powerful factor in steadily limiting the

56 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

production of bacon pigs. In the vicinity of our manufacturing towns there
has always been a ready market for porker pigs, and whilst prices have
fluctuated—at times violently—the pork trade has maintained a moderate
degree of steadiness in the matter of price.

The more popular breeds have been the Large White, Middle White,
Berkshire, Large Black, Tamworth, Wessex, Welsh and many indis-
criminate crosses. A growing interest in pig breeding is being steadily
stimulated by the pig-rnarketing scheme which is now before the country,
and which will doubtless be adopted and put into operation about August
this year. This scheme offers a price for bacon pigs which is definitely
associated with the price of feeding stuffs, and, moreover, the price is such
as to practically guarantee a definite market for all bacon pigs of suitable
breeding and weight, with little or no risk of loss. The pig population
recorded in 1932 was the highest during the last ten years, and under the
new reorganisation scheme there is every prospect of the pig industry
extending upon a very considerable scale. ‘The British pig breeder can do
much to supply a greater proportion of the bacon consumed than here-
tofore. In preparation for developments the County Milk Recording
Society has started a litter recording scheme which is meeting with a fair
amount of support from progressive pig breeders. The object of the
scheme is to help breeders to select their breeding stock with a greater
degree of confidence than has been possible in the past. There are
twenty pedigree boars in the county under the Live Stock Improvement
Scheme of the Ministry of Agriculture.

AGRICULTURAL HorsEs.

The reduction in the numbers of horses in the county is shown in the
following table :

1923. : : . 23,519
EQ25 81, : d . 21,084
1926. L ‘ . 19,855
193. : : . 16,249
THZ2 “1 : ; . 16,061

The influence of the machine age is clearly evident in the foregoing
figures, for it will be noted that a steady but relentless decline in the number
of horses is in operation. In past years, Leicestershire has held a well-
merited reputation for breeding some of the best shire horses, and for
many years Leciestershire breeders have always occupied excellent posi-
tions in the list of awards at the Shire Horse Show in London. It is also
a noteworthy fact that some of the most successful breeders of shires have
been tenant farmers, many of whom have been ardent supporters of the
activities of the Melton Mowbray Shire Horse Society. This Society
has contributed materially to the developmient of horse breeding, and has
readily paid very high premiums for the hire of some of the best stallions.
The breeding of hunters is keenly pursued, especially by farmers and
others interested in hunting, and for many years King’s Premium stallions
have been available. The undulating character of the county and its
strong and well-laid bullock fences necessitates the breeding of a type of

FARMING IN LEICESTERSHIRE 57

hunter which must have not only great powers of endurance, but well up
to average as a weight carrier, and, in addition, possessed of great speed
and a clever jumper. ‘The nature of the country and the character of the
fences necessitate horsemanship of a very high order, and the hunting
“countries ’ of Leicester may well claim to have provided for many long
years some of the very best training grounds for cavalry officers and all
others who desire to excel in that noble art of riding ‘ straight ’ to hounds.

CEREALS AND POTATOES.
FO7G 09M g2y. 1925. 1926. IQ3I. 1932.

Wheat . . 44,404 25,298 19,786 21,126 13,599 14,185
Barley . St Age ne ORet.) Sete 2 S27 44,004 aeAOU
Oats : Peo OOO SS EQZO5 E7007. 07 cot. Le.e7e, Ee bak
Potatoes . o Laas eg SONG ye AOO . 2hat © Agee or

Total acreage . 100,296 55,154 47,414 46,511 35,373 33,914

From the foregoing table it will be seen that the decline in the acreage
of cereals in the last fifty-six years amounts to very nearly 70,000 acres,
and that during the last ten years a decrease of no less than 21,000 acres
has to be recorded. ‘The low prices of cereals during recent years have
been such that arable farmers have been compelled to limit the acreage, so
far as they could consistently do so, keeping in mind the requirements of
the farm so far as the straw for bedding was concerned. Of the three
cereals a decline of barley and oats was inevitable, and the slight increase
in the acreage of wheat is undoubtedly due to the stimulating influence
of the wheat quota. During the last ten years the acreage of potatoes
has gradually increased, and under the new marketing scheme for potatoes
it is very probable that the potato acreage in future may increase still
further. Crops of mangolds and swedes, during recent years, have shown
a marked tendency to decline in acreage, but this decline has been prac-
tically met by the increase of crops of marrow-stemmed kale, cabbage, and,
notably, sugar beet.

During the last ten years the interest in the growth of sugar beet has
been steadily increasing ; this crop has the advantage of being one that the
farmer can turn directly into cash, and, in addition, the tops and crowns
provide a very useful fodder. Sugar beet growers are also entitled to
receive a proportional supply of dried beet pulp at a preferential price.
Dried beet pulp has been proved to be an excellent food for dairy cows
and other farm live stock.

PERMANENT GRASS.

1923. 1925. 1926. 1931. 1932.
Not for hay . 254,827 265,606 203 -LOm * 2OL.aeo” "27a 200
For hay . 98,189 95,544 100,948 115,004 107,108

353,016 361,150 364,048 = 376,224 380,388

58 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

With the gradual decline of the arable acreage it is natural to expect
that such decline would be reflected in the increase of grassland, and
from the above table it will be seen that a steady increase in the permanent
grass acreage has taken place during the last ten years, and, in addition,
there has been a gradually increasing area mown each year for hay, this
being necessary for the increased number of dairy cattle which have to
be wintered indoors, with the consequent need for more bulky fodder.
The acreage under permanent grazing has not only increased, but during
the last ten years there has been a decided advance in the management of
grassland. Surface cultivation coupled with liberal phosphatic manuring
has done much to increase the stock-carrying capacity of the pastures.
The use of fertilisers has also assured heavier crops of hay of a superior
feeding value, the value of a high quality hay being now more fully
recognised by progressive dairy farmers. The soil and climatic conditions
of the county are extremely favourable for the development of good grass-
land, and these natural advantages are being more fully utilised each year.

Total Number of Agricultural Holdings.

1922. 4 ; . . 6,526
L925... > é : . 6,460
1926 . e : : »f 1105380
E31}... s ; : . 6,050
1932... " ‘ ; . 6,008
Holdings above 1 Acre and not Exceeding 50 Acres.
ge), ; : : Lo hao
rg25- * : : é IM 4.765
1926 . : : ‘ § 92050
IQ3I_ . ’ é s #f Bare
RG3ar : : ; aA eAG

During the last ten years there has been a decline in the number of
agricultural holdings to the extent of slightly over 500. It is not possible
to analyse fully all the causes of this decline but doubtless the demands
for building sites of various kinds and public improvements have played
an important part.

It will be noticed that there has been a decline in the number of small
holdings, and whilst there has been much said in recent years about the
necessity of small holdings, it will be seen that during the last ten years
there has been a decline in the number of holdings above 1 acre and under
50 acres of no less than 586 holdings in this county.

This result would seem to support the idea that there cannot be a real
and substantial reason for increasing the number of such holdings. It
may well be that this result is due to the difficult times which agriculture
has experienced during the last few years. Better times may possibly
stem this unfortunate decline, for it is admitted on all hands that the finest
asset a nation can possess is a healthy, numerous, and rural population, a
virile and prosperous countryside. It should be noted that no less than

FARMING IN LEICESTERSHIRE 59

54 per cent. of the holdings in the county are under 50 acres in extent,
veritably a county of small holdings.

Regular Workers.

1923)" ; ‘ : «18256
1G25. , , : » #6958
1920 ; : : . 8,196
1931. . . . - 7,439
pS cp hae : s ‘ ani fe -7

(Excluding the occupier and his wife and domestics.)

Total Workers, Regular and Casual.

LQS3 i108 . ° . - 9,957
1925. d : d . 10,062
1926 . , ; , 5 ps E
EOUE. ; ‘ ‘ te zig)
1932. ; : : ’ . 8,269

When we come to consider the common problem associated with the
drift of agricultural workers to the towns, the figures in the foregoing
tables emphasise a tendency which has often been deplored by all who have
the welfare of the countryside at heart. Of the regular workers in agricul-
ture in the county there has been a decline of no less than 1,091 during
the last few years, and the figures seem to suggest that the decline has by
no means been arrested. The same tendency is also seen when the total
number of regular and casual workers is considered. If any evidence were
required as to the seriousness of the agricultural depression which has
extended over the last ten years, it is amply provided by this brief
review of Leicestershire farming.

60 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

VI.
THE INDUSTRIES OF LEICESTER

BY

L. W. KERSHAW, B.Sc., A.M.Inst.C.E., F.G.S. (PRINCIPAL,
LEICESTER COLLEGE OF TECHNOLOGY) ; F.R. ANTCLIFF, B.Sc.,
A.M.1I.Mech.E.; J. CHAMBERLAIN, F.T.L.; J. P. IVENS,
M.A.; anp F. W. ROBERTS, F.B.S.1.

The Hosiery Industyy.—Introduction—State of Employment—Early Period—
Introduction of Machinery—Materials Used—Purchase of Raw Materials—
Processes—Machines Used—Labour—Marketing—Piece-work—Technical
and Art Training.

Boot and Shoe Industyy.—Mass-production—Invention of Machines—Domestic
System—Raw Materials—Specialisation—Processes—Statistics—Relations
of Employers and Employed—Wages—Agents and Merchants—Women’s
Shoes.

Engineering Industvyy—Products—Hosiery Machines—Elastic Web Industry—
Shoe Machinery—Machine Tools—Quarry and Roadstone Machines—
Wood-working Machines—Heating and Ventilating—Scientific and Optical
Instruments and Photographic Lenses—Electric Clocks—Cardboard Boxes
—Typewriters—Technical Training.

Subsidiary Industries and other Industries, including Printing.

THE popular slogan which avers that ‘ Leicester clothes the world,’
doubtless owes its origin to a sudden consciousness of local patriotism
strengthened by the city’s relative prosperity in a world of economic
depression. As a statement of tendency and asa reference to the multi-
plicity of trades established there, the boast is true and invites analysis,
as affording a possible explanation of this prosperity. Of the population
of 239,000, nearly 50 per cent. (115,000) are insured workers, of whom
65,000 are men and 50,000 women. ‘This percentage, in respect of both
men and women, is nearly double the average percentage for the whole
of the country, and indicates that the purchasing power of the working-
classes in Leicester, other things being equal, must be approximately
twice as great as that of the ‘ average’ worker for the whole country.
Other things, however, are not equal. At the beginning of the present
year about 16,000 men and women in Leicester were unemployed, a
proportion (x4: 4 per cent.) which compares very favourably with the
national percentage of 21-5. Some explanation of these figures is to be
sought in the nature of the two staple industries on which the economic
life of the city and county depends. If food and rent together constitute
a ‘first charge’ upon income, clothing and footwear are none the less
to be included among primary necessities. Further, the fact of the
existence of two staple industries exerts, even in normal times, an im-
portant influence on local conditions. It is true that these trades are
seasonal and that their ‘ off’ seasons usually coincide; it is also true,

THE INDUSTRIES OF LEICESTER 61

however, that in a long period consideration a non-seasonal depression
in the hosiery industry rarely corresponds in time to a non-seasonal
depression in the boot and shoe industry. There has thus grown up in
Leicester a considerable body of mobile labour capable of ready assimila-
tion into either of these staple trades—a phenomenon relatively rare in
industrial towns and possessed of very definite advantages.

Tue Hosiery INDUSTRY.

Since the time of King Alfred the scarps and meadows of Leicestershire
have been recognised as highly suitable pasture lands for sheep, and
even in that remote age crude textile fabrics were produced in both town
and country. In the thirteenth century wool was spun by hand and
woven into blankets and coarse fabrics, and wool fairs were held in
Leicester.

In the sixteenth century a new industry had arisen; wool-combers
supplied the yarn they spun to persons willing to knit stockings by hand.
The trade prospered, and about two thousand people were employed.
Meanwhile in 1589 the Rev. William Lee of Calverton, Nottingham-
shire, invented the hand stocking-frame, and in the early years of the
following century the industry established itself in Leicester and Leicester-
shire. Although the frame-work knitters of London obtained a Charter
in 1663, the trade gradually left London and developed in the Midlands.
The eighteenth century witnessed a period of trade depression, and
stockingers who had been earning from nine to eleven shillings per week
were compelled to refund from two to four shillings for certain ‘ charges,’
such as frame rent, standing room, light and fuel, winding, taking-in,
deductions for faulty work, etc. The workers were even required to
purchase the needles to replace breakages, and, before the passing of the
Truck Act, were often forced to accept commodities in lieu of money.
A large number of small stockingers’ shops existed, and ‘ middlemen ’
obtained yarn from the warehouses and knitted it into stockings, which
they returned at the end of each week. This method of trading continued
until the Industrial Revolution, when factories were erected and power
machines introduced.

By about 1860 machinery developments had resulted in the construction
of several types of machines, the chief of which were ‘ Cotton’s Patent
Frames’ in 1863 (which produced fully fashioned garments), circular
loop wheel and sinker wheel machines, and, thanks to Matthew Townsend’s
invention of the latch needle in 1849, circular and flat latch needle
machines. Cotton, who was born at Seagrave, Leicestershire, in 1819,
invented his machine at Loughborough, whilst Townsend was a Leicester
‘fancy hosier.’ Since that time many improvements have been made in
the mechanisation of knitting, and knitted fabrics are now used for all
types of hose in both underwear and outerwear. The ‘ fancy ’ trade was
inaugurated in Leicester by William Kelly early in the nineteenth century,
and although many different articles of apparel were knitted—gloves,
cravats, franklins or jerseys, children’s boots, etc——the term “ hosiery ’
still held its ground ; even to-day it is still used in a generic sense.

62 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

In the early periods of the trade each of the three knitting
counties tended to specialise in the use of a particular material. As time
went on, however, this distinction disappeared, although traces of its
effect still exist. ‘Thus as finer counts of cotton and silk could be spun,
stockings of finer gauge were made in increasing quantities in Nottingham-
shire and Derby, and this tendency still holds in a lesser degree to-day.
Similarly, as fancy hosiery is more often made of wool, that trade increased
more rapidly in Leicester than elsewhere. To-day practically all textile
materials are used for knitting—viz., cotton, wool, silk, rayon, acetate silk,
and, to some extent, flax, ramie and camel-hair. Modern hosiery yarns
differ considerably from those used in weaving, in that they have less
‘twist’ and more fullness. Australian, Cape and Argentine wools are
largely used, owing to their peculiar properties, although a certain amount
of wool is spun in Leicester itself. Other yarns are spun in Yorkshire
(wool), Lancashire (cotton), Warwickshire and Derbyshire (artificial silk),
raw cotton is obtained chiefly from the U.S.A., Egypt, India, Brazil and
Peru, and silk is imported from Japan and Italy.

In the purchase of these raw materials spinners do not as a rule
approach manufacturers directly, but through agents. The latter call
periodically on manufacturers, and may each represent a number of
spinners. Orders for yarns are usually placed ‘ firm,’ although orders
for knitted goods are subject to cancellation. This system is somewhat
disconcerting to manufacturers, but is said to have its compensations in
regard to early placements of orders, and is still in being. The method
of payment usually provides for one month’s credit and a cash discount.
The prices of yarns vary, of course, with fluctuations in raw material
prices or tops. Hence a certain amount of speculation exists, and
manufacturers follow raw material prices, crop reports, etc., with interest
if not always with profit.

The cycle of processes involved in manufacture depends upon the type
of garment to be produced. For our present purpose, however, we may
regard the following operations as constituting the customary succession :

(a) Winding (and in some cases warping).

(6) Knitting (circular, seamless, fashioned).

(c) Seaming, linking, welting (closing operations).

(d) Cutting out and machining (making-up operations).

Mending is carried out on rough fabric and also on dressed fabric or
goods. Scouring, dyeing, or bleaching and finishing may be carried out
either on a fabric before it is cut out or after goods have been knitted to
shape and seamed.

All goods are subsequently taken to the warehouse and paired (if
necessary), folded, stamped, etc., and boxed ready for sale.

The machines used in the manufacture of hosiery do not require a large
amount of power. Formerly gas, steam or oil engines were used, but
modern practice prefers the electric drive. One horse-power is sufficient
to drive eight sewing machines, four to six seamless hose machines, or
three fabric machines. In some cases the motor is incorporated with
the machine, but generally small groups of machines are driven from orie

THE INDUSTRIES OF LEICESTER 63

motor. This method effects a great saving in shafting, belts, etc., and
total stoppages are therefore rare.

Although mass production of like articles is carried out as far as possible,
the great variety of styles which prevails in single garments rendered the
team system very difficult. If the fastest operation be taken as unity,
the numbers of machines may be regarded as multiples of this in the
production of a given garment, and the machines so arranged that a
conveyor system becomes possible. A change in garment or style,
however, necessitates a complete re-arrangement, and, in practice, the
machines are often ‘ averaged ’ in order to take account of a more or less
constant variety of articles. Factory planning has now developed to a
high degree so as to ensure a flow of goods in a given direction.

Hosiery manufacture demands a large proportion of skilled and semi-
skilled labour. The most highly skilled work is that of ‘ legging ’ fully
fashioned silk hose of fine gauge, and this is usually done by men, while
‘ transferring ’ and ‘ footing ’ are done by mixed male and female labour.
Seamless hose machines, web frames, and warp-knitting machines are
operated by both male and female labour, usually by women during the
day and by men during night-shifts. Winding, mending, seaming,
linking and machining are carried out by women.

In dyeing and finishing, the light operations, such as turning, brushing,
calendaring, etc., are carried out by women, but scouring, milling, dyeing,
napping, pressing and boarding are usually done by men. A shortage
of skilled labour sometimes occurs, owing to the custom of working shifts
in a busy season.

There is no systematic method of training labour, no scheme of
apprenticeship, for example, but youths and girls are first employed as
assistants or ‘ runabouts,’ and afterwards transferred to knitting or sewing
machines. Opportunities for practice work are afforded by the Leicester
College of Technology and by the colleges at Loughborough and Hinckley.
This assists in some measure, although the conditions under which the
work is done do not approximate very closely to those of the factory.

The earlier system of marketing, whereby wholesalers, after purchasing
finished goods, distributed them to shopkeepers, still persists on a con-
siderable scale. To-day, however, many quite small firms supply the
multiple stores and largeshopsdirect. In other cases, especially with large
firms, manufacturers advertise their own goods and employ travellers or
salesmen, both at home and abroad. Manufacturers’ agents also assist in
the distribution.

Within the factory the system of piece-work applies generally through-
out the trade, although the time-rate is not unknown. Prices which were
established before the war are still utilised as a basis, and to these is added
a bonus which varies according to the cost of living. This plan has
proved very satisfactory, and few disputes have taken place. Wages are
high in comparison with those paid on the Continent and, of course, in
the East, and the industry has been protected to some extent by the
imposition of tariffs.

During recent years Leicester has developed a large knitting-machine
building business, which has enabled manufacturers to benefit by the

64 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

installation of improved machinery ; several types of machines used are,
however, still made abroad. The community, too, has benefited greatly
by the introduction of knitted garments, which are cheap, efficient,
hygienic, comfortable and stylish. In many cases woven goods have
been replaced by knitted goods, so that Leicester has prospered at the
expense of her competitors. On the whole, considerable enterprise has
been shown in the development of new garments, new fashions and new
designs. Nevertheless, in spite of statements to the contrary, the hosiery
trade remains a seasonal trade subject to fluctuations of weather and
fashion. As production is high and machinery developments are
prodigious, severe competition at home and abroad is inevitable.

Both machine builders and manufacturers have realised the advantages
of technical and art training, and at the local colleges combined courses
have been instituted with success. At Leicester alone some 500 students
attend courses in the Hosiery Department, and that in spite of the
absence of any definite apprenticeship scheme. Of these, approximately
80 per cent. attend in the evenings, but signs are not lacking that more
attention is being paid to the advantages of day training. In this and in
other ways the Leicester and Leicestershire hosiery manufacturer is
playing a worthy part in British trade. Fortunately or unfortunately, the
hosiery industry lends itself to the establishment of small self-contained
manufacturing concerns which may employ from 300 to 400 people without
the necessity of instituting elaborate and costly systems. ‘Thus personal
contact is preserved between employer and employee, matters can be
arranged quickly and satisfactorily, and rapid changes can be effected to
follow the day’s fashion. Businesses launched with comparatively small
capital outlay may, by the use of modern methods, the purchase of
modern machines, and the study of modern fashion and design, be
developed quite successfully by sheer grit and hard work.

Tue BooT AND SHOE INDUSTRY.

The history of the hosiery trade in Leicester and Leicestershire takes
us back into the remote past ; both town and county have grown up in
a ‘ tradition of wool,’ and we acknowledge a certain fitness in the sequence
of events on learning, for example, that on the site of the present Friar
Mills there once stood the Monastery of the Black Friars of St. Dominic,
themselves wool merchants as long ago as the early thirteenth century.
In contradistinction to this, the story of boots and shoes is quite modern,
and falls almost entirely within the last hundred years. A company of
* jornemen of schomakers ’ existed in the days of Elizabeth, but it remains
doubtful whether before 1830 the shoemakers of the town ever satisfied
a wider need than that of its own inhabitants.

In long-period considerations of industrial growth we perceive the
principle of development as a transition from the slow handicraft of many
highly skilled individual productive units (a system characterised in its
early stages by personal acquaintance between craftsman and customer)
to the rapid mass production of mechanised industry, in which the
craftsman is replaced by the ‘machine minder,’ and the customer
becomes, at least for the workman, a generalised abstraction. ‘This

THE INDUSTRIES OF LEICESTER 65

development has taken place in the manufacture of boots and shoes.
Its meaning is better seen if we consider the function of the shoe. Most
feet, like most faces, appear to have their individual peculiarities of
proportion, and a slight misfit, such as in clothing would pass unnoticed,
is of vital importance in shoes. Again, the simple and inert rigidity of
the last contrasts with the complex flexibility of the human foot. Herein
lie the problems of the mass production of boots and shoes—to produce
them by the million and to place them upon the market so that any one
can walk into any shop and obtain a pair that will fit his own ‘ particular ’
pair of feet.

Until 1790, when Thomas Saint invented a chain-stitch machine for
sewing together the various parts of the upper, shoes were made entirely
by hand, slowly and laboriously. While to-day some four hundred types
of machines are in common use, the wider application of machinery to
manufacture did not really begin before the middle of last century.
Mechanisation, however, once established, made rapid progress. Walter
Hunt’s first lock-stitch machine (1832), improved by Elias Howe in 1846
and followed in 1849 by Allen Wilson’s rotary hook principle, represents
a further stage in the manufacture of the upper. Early in the century
Randolph and Brunel had applied themselves to methods of riveting by
machinery. Then Thomas Crick, the ‘father of the Leicester shoe
industry,’ securing an iron plate to the sole of his last, clinched rivets,
driven through the leather, against it. His son introduced the method
of inside riveting, whereby uppers and insoles were riveted together,
then turned and the sole attached. This was in 1853. In the same
decade appeared the ‘ Blake ’ sewer, whereby the outer and inner soles
(the latter with upper attached) were sewed together, an invention which,
by its revolutionary effects, heralds the modern period. The rest is a
matter of detail—the ‘ clicking’ press, the eyeleting machine; screwing
and heeling machines, edge-trimming machines, burnishing machines and
so on, until the introduction of the hand-method lasting machine in 1885
completed the industrial revolution from hand to machine.

Under the Domestic System, when each worker’s home was a law unto
itself in the matter of hours and working conditions, when father and sons
riveted and ‘finished’ and the womenfolk performed the ‘ closing ’
operations on crude treadle machines, when workshops were badly
ventilated and insanitary, and tuberculosis was rampant, life was a frantic
struggle, a demoralising experience. When this system, even under
rapidly improving conditions, received its death-blow, after the national
strike of 1895, and the present factory system firmly established itself,
most people looked to the future with much confidence and little regret.

A century ago the raw materials of shoe production included horse-hide
and ox-hide, the skins of sheep, calves and goats, and little else. ‘To-day
a wonderful variety of materials, drawn from all over the earth and made
from scores of species of animals, birds, reptiles and fish, enters into the
routine of large-scale manufacture. The canvas is too large for even the
sketchiest of outlines.

Boot and shoe manufacture has thus become a highly specialised
industry. Even so, few realise to what extent variety in choice of material

E

66 . SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

and multiplicity of styles and ‘ fashions’ have influenced methods of
construction ; more than a dozen different manufacturing methods exist,
each of which may involve some 150 distinct operations and, at least,
100 different machines. It is possible in this brief survey to refer only to
a few of those major operations through which all boots and shoes must
pass in the process of manufacture.

The making of the ‘ last’ model has remained a highly skilled craft
through its defiance of the application of a formula. Its evolution owes
much to the inventive genius of Leicester firms. ‘Taking account in its
form of every movement of the foot, to the end that movement shall be
easy and natural, the last must yet be rigid in the shoe and mobile in
removal. Dried Canadian maple wood is used. The rough block,
weighing nine or ten pounds, is first shaped and trimmed until it satisfies
the necessary conditions. ‘This original is then used as a model in a
turning lathe for the production of as many as are required. The
necessary mobility has been attained by dividing the last into two parts,
while its rigidity in the shoe depends upon the use of suitable devices
inserted into the V-shaped aperture between the parts. The finished
product weighs about a pound.

After last-making comes pattern-cutting, a process which calls for a
high degree of skill in the correct placing of curves and seams in the upper
in order to maintain the form of the shoe in wear, and necessitates further
study of the shape of each part to effect economy in cutting.

‘ Clicking ’ and ‘ closing ’"—the cutting out and the sewing together of
the parts of the upper—and the accurate preparation of bottom stock
are not merely automatic machine processes. While the old hand-sewer
produced some ten or twenty stitches per minute and the early treadle
machine about 300, the modern power-driven machine makes 3,000
stitches per minute, equivalent, in machines fitted with four needles, to
200 stitches per second—a truly amazing speed, and one which is eloquent
of the deft touch of the skilful ‘ closer.’

But it is in the lasting and making departments that the genius of the
modern machine finds its fullest expression. Here are machines which
by means of mechanically operated pincers seize the flat-cut upper,
stretching and drawing it to conform to the subtle curves of the last, and
securing it by tacks or staples. Here are machines which imitate at
high speed the ‘ welting’ methods of the old-time craftsman with awl
and thread. Here, too, are machines which cut and drive thousands of
nails a day. Every type of machine known within the industry operates
in Leicester’s factories. It was in no small degree due to the opposition
in other parts to the introduction of machinery into factories that so many
workers from these centres came to Leicester and placed their experience
and skill at the disposal of local manufacturers.

The number of boot and shoe manufacturers in Great Britain is esti-
mated at 950, with about 132,000 employees and an output of 117 million
pairs per year. The comparatively recent industrialisation of manufacture
partly explains why the industry is not confined to just one or two large
centres, but has grown and developed in small towns and villages over a
wide area. Despite this, Leicester is the greatest shoemaking centre in

THE INDUSTRIES OF LEICESTER 67

the world, the industry supporting 30,000 operatives (of whom 20,000 are
men) and producing an annual output of approximately 25 million pairs.
The statistics of employers, employees and output for Leicester and
county are 130, 350,000 and 40 million pairs respectively.

From the bitter fight between employers and employed in 1892 (the
only serious dispute in Leicester in the history of the trade) emerged the
Boot and Shoe Operatives’ Union and the Federation of Boot and Shoe
Manufacturers. The Arbitration Board (founded in 1878), which
gathered strength from the same struggle, affords a notable example of
how trade disputes may be amicably settled without recourse to strike or
lock-out. This conciliatory spirit has been responsible for the almost
entire absence of industrial disputes during the last forty years. Few
large manufacturing centres can claim so happy a record.

The actual wages earned are good. For men of 22 years and over, as
for women of 20 years and over, standard minima have been established,
with the following graduated scales for boys and girls :

Sano So, ots
Boys: Ages. » askgreud Girts: Age 15 . q tol esd
56. epptQe6 307 LOK ote ee
did Foe win 2Bi20 35: SEGAL 2 pahide
swonkbis sy 290E 0 sso ntSies 256
fon Lhe a5 GS gx Ques shiBih}-2
yhnc2Or» vere 42030 519 2 213620
isk s and§Se00
Lp 2rio . 60 0

The National Conference Agreement provides that ‘ Piece-work or Quantity
Statements shall be prepared on a basis to ensure the average worker
earning not less than 25 per cent. over the minimum wage.’ When
employed full time, men may earn as much as £5 Ios. or £6, and women
from £2 10s. to £3 10s. per week. Piece-work is the usual basis of
payment.

Agents and merchants, who supply manufacturers with their raw
materials, owe their commanding position in the industry to the fickleness
of fashion, which effectively frustrates manufacturers’ attempts to place
orders for any considerable period ahead or to produce largely for stock.
This increasing inconstancy tends to cause the flow of orders to become
more and more irregular and to result in alteration of periods of * rush’
and of short time, tendencies whose ultimate influence may be reflected
in comparatively high production costs. As in Leicester women’s shoes
form the bulk of the output, this tendency is marked.

While women’s shoes make up the bulk of the output, there is also a
very large production of boys’ and girls’ footwear and of sports goods.
Leicester-made football boots have long been well known in the trade,
while white duck and canvas shoes for tennis and other purposes are
exported to all parts of the world. On the whole, it may be said that the
great mass of production is for the ‘ medium ’ and ‘ better medium ’ trade,
and aims at the making of good-wearing shoes at a reasonable price.

68 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

Despite the difficulty referred to above, of basing the commercial side of
the industry upon long contracts owing to ever-changing styles, production
in Leicester still takes place on so large a scale that each season’s novelties,
after separation into numerous categories, may be subjected to massed
means of manufacture with the required economies of production.

Even the most rapid survey of the shoe industry in Leicester would be
incomplete without some reference to the conditions which prevail in
the factories and to the men and women who work in them. For in vivid
contrast to the dark and dirty ‘ up-entry ’ workshops of a generation or
so ago are the bright and spacious factories of to-day, pure of air, warm,
well-ventilated and clean. They are filled with ‘ operatives ’ who do not
merely take a decent interest in their exterior, but display pride in their
work and a sense of progressive efficiency.

THE ENGINEERING INDUSTRY.

Engineering ranks third among the industries of Leicester. In addition
to supplying and maintaining machinery for the boot and shoe and hosiery
trades, the engineer in Leicester is responsible for the provision and
upkeep of plant in many subsidiary industries. The following list will
serve to show how diverse are his activities : quarrying and road-making
machinery ; machine tools; woodworking machinery; heating and
ventilating engineering ; box-making machinery ; hoisting appliances ;
iron-founding ; constructional engineering ; optical instruments and fine
measuring machinery ; clocks ; typewriters ; small electrical machinery ;
printing machinery.

Leicester produces vast numbers of automatic hosiery machines. The
evolution of the modern machine, from Lee’s stocking-frame to the
automatic or ‘ Straight Bar Machine,’ and thence to the early circular
knitting machine made by Thompson of Leicester and incorporating the
latch needle of Matthew ‘Townsend, also a Leicester man, is a fascinating
romance. ‘To every fresh demand of the hosiery makers of the country
the machine builders of Leicester have responded; indeed, in many
cases, the machinery inventions have dictated the changes which have
occurred in the design and production of hosiery wear.

Leicester can claim to be the birthplace of the elastic web industry,
its craftsmen having journeyed to the Continent and America to teach
the technique of elastic web weaving. ‘The recent introduction of wide
corset web and the use of artificial silk in the manufacture of elastic web
necessitated both the adaptation of the Lancashire piece-goods loom to
the industry and the invention of many new types of machines to deal
with preparatory processes. ‘These adaptations and inventions are, in
many instances, the work of local engineers. "The whole of the machinery
necessary for the manufacture of shock-absorbing rings for aircraft was
designed and produced in the engineering department of a Leicester firm.
It is interesting to record that Mr. L. Rowland, B.Sc., A.M.Inst.C.E., a
distinguished Leicester engineer, has been a member of the British
Standards Committee on Rubber since its inception. Some years ago,
when a member of the engineering staff at the College of Technology, he
designed the standard machine used for the testing of rubber.

THE INDUSTRIES OF LEICESTER 69

The story of another of Leicester’s industries, the manufacture of
boots and shoes, illustrates inventive genius. Leicester boot and shoe
manufacturers have always encouraged machinery engineers and have
been quick to place the very latest shoe-machinery in their factories. As
some 400 different machines are used to-day in the manufacture of boots
and shoes, the place of the engineer in this industry is paramount.
Further, nearly the whole of the shoe factories of the British Empire are
equipped with Leicester-built machines, while many machines are
exported to foreign parts. In the section of this survey which reviews
the boot and shoe industry reference has been made to types of machines
used and to their evolution.

Specialisation in branches of engineering not immediately connected
with Leicester’s staple industries occupies the energies of many firms
in Leicester and district. A number of firms, for example, specialise
in machine tools, and mass production in the engineering workshop owes
much to Leicester. Drilling machines, capable of drilling fifty-six holes
at one operation, have recently been made in Leicester, and the products
of the Leicester machine tool manufacturers are to be found in every
large motor car works in the country.

Leicester lies at the apex of a wedge of igneous rock which provides
granite for road-making, and granite quarries stretch from Mountsorrel
through Whitwick, Bardon Hill and Cliffe Hill, southwards to Enderby,
Stoney Stanton and Croft. These quarries, from which granite has been
extracted since the earliest times, provide one-quarter of all the granite
used on English roads, and Leicester has thus become the home of the
quarry and roadstone machinery maker. Leicester-made breakers,
granulators, crushing rollers, washers, driers, concrete and tarmacadam
mixers are exported to every part of the world, and the manufacture of
these machines provides employment for many hundreds of men. Leicester
has earned the reputation of being one of the cleanest cities in the kingdom.
Her road-making engineers, by their careful study of road surfaces, have
contributed to this result. It is of interest to note that the modern
concrete mixer and tarmacadam mixing machine originated in Leicester.
There is also a considerable industry in the production of auxiliary quarry
equipment, in sand and gravel washing, and in the manufacture of screening
plant for concrete-making and of excavating plant for quarrying.

The engineers of Leicester have specialised for nearly thirty years in
the making of woodworking machinery, including machines for sawing,
mortising, tenoning, planing and moulding operations. Of special
interest is the exceedingly ingenious machine known as the universal
pattern miller, by means of which practically every pattern-making
operation can be performed. The patterns both for the Rolls Royce
Schneider Trophy engines and for the huge fans installed at the Ford
works at Dagenham were produced in Leicester.

Heating and ventilating is a highly important branch of engineering in
which Leicester specialises. The new Parliament building of Northern
Ireland and the Shell-Mex edifice in London are two of the more recently
erected structures of repute to be heated and air-conditioned by Leicester
engineers. In addition, many of the most modern cinema theatres have

70 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

called upon Leicester for the installation of their heating and ventilation
equipment. The quarrying, boot and shoe and woodworking industries
require, of course, dust-extracting plant, and the satisfaction of this need
has consequently become an associated branch of the work of specialists
in heating and ventilation. Dust-extracting plant made in Leicester has
been installed in industrial houses all over the world.

An industry in which Leicester stands as a pioneer, and one which has
become peculiar to the town, is the manufacture of scientific and optical
instruments and of photographic lenses. When it is stated that a
Leicester-made lens has to fit a standard gauge to within a half-millionth
part of an inch, the degree of precision in its manufacture will be realised.
Some of the most accurate machines in the world must be those engaged
in the production of optical instruments and measuring machines for
which the city is famous. In view of the extraordinary degree of accuracy
in screw-threads necessary in the manufacture of optical instruments,
extensive research was an essential preliminary to manufacture. This
research proved invaluable in the fixing of the British Standard Specifica-
tion for screw-threads, and it can be truly said that many of our present
standards emanated from Leicester. In addition, the majority of films
exhibited in British cinemas are both produced and projected through
lenses made in Leicester, while the greater proportion of projectors at
Hollywood are equipped with these same Cooke lenses.

The largest electric turret clock in the world, that in the tower of the
Singer building at Glasgow, was constructed by a Leicester firm which
has specialised in bells, clocks and other electrical devices for sixty years.
‘ Pul-syn-etic ’ electric clocks are met with in every country in the world.
Delhi is timed by ‘ Pul-syn-etic,’ with five master clocks and 400 auxiliaries ;
while the new Parliament building at Belfast is equipped with 137 of these
clocks. Electro-motor chiming gears for use in conjunction with the
‘ Pul-syn-etic ’ system constitute a further activity of the same firm, while
travellers by Cunard and other lines will set their watches and take their
meals by clocks made in Leicester. Thus can Leicester engineers claim
to keep the world punctual.

There may be something coincidental in the fact that the multifarious
industries of the city and county seem to agree upon the desirability of
producing especially those classes of goods which the ultimate consumer
insists upon receiving in cardboard boxes. Leicester, of course, makes
her own boxes, and her many box-makers are, moreover, well served by
local engineering firms engaged in the manufacture of highly ingenious
machinery for that purpose. Box-making machinery from Leicester is
despatched to all parts of the country, and a very satisfactory export trade
is maintained.

Leicester possesses the largest typewriter factory in the British Empire.
The modern typewriter, consisting as it does of some 2,000 parts, is a
triumph of engineering skill, and one learns with interest that the Leicester
firm of manufacturers permits a margin of error of only one-thousandth
part of an inch.

The cordial relations which have long existed between the Engineering
Department of the College of Technology and the engineers of Leicester

THE INDUSTRIES OF LEICESTER 71

are attested by the large amount of experimental and investigation work
which the staff of the department undertakes for industry. The splendidly
equipped testing laboratory and the staff are thus available for all testing
and investigation work received from local firms. The major portion of
the equipment has been generously provided by the Engineering and
Allied Employers’ Leicester and District Association, the Leicestershire
and District Munitions Committee’s Engineering Education Fund, and
the Leicester Association of Engineers.

THE PRINTING INDUSTRY.

Leicester is accepted throughout the country as being a prominent
centre for the production of printing of the higher class, especially colour
printing. Within a small radius of the city there has grown up a body
of manufacturers educated in the art of national distribution of their
products, skilled in the application of branding to salesmanship, and
fully appreciative of the value of modern printing. Their requirements
are more fully met by the local members of the printing industry than
elsewhere, and the standard of excellence established has attracted the
attention of students and buyers of printing in all parts of the country.

Despite the unhelpful conditions prevailing generally, considerable
progress is being made in the development of printing and printing
processes. Fundamentally, there is more adequate provision of facilities
for the technical training of printing apprentices. Steadily working over
a number of years, executive and district committees have evolved systems
of apprentice selection which are resulting in the introduction of a more
intelligent and more highly educated type of apprentice. They have
been helped in their work by the very favourable rates of remuneration
in all branches of the industry.

In Leicester this problem is being solved by the Gateway Secondary
School, which is unique in the kind of pre-apprenticeship training it
offers to printers. In addition to a secondary education, specially selected
boys are given practical instruction in the various branches of printing.

In Leicester, as in the other more important centres, day as well as
evening training is provided for apprentices. Here the training is
carried out in the College of Arts and Crafts—a fact that accounts in a
large measure for the high artistic standard of local printing.

CONCLUSION.

The extremely varied character of the many subsidiary industries of
the town and county renders a connected account quite impossible within
the limits of space at disposal. More than seventy classifiable trades,
many of which thrive with no apparent links to connect them, provide
employment for thousands of workpeople.

It is interesting to observe that the two staple industries tend more
and more to be independent of other areas, save in the provision of raw
materials. The extremely large number of manufacturing processes
involved and the derived demand for commodities, to be used again in
further manufacture, have led to the growth of numerous subsidiary
industries which, while remaining ancillary to the main industry, serve

72 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

a wide industrial field beyond the confines of the county. In respect of
the shoe industry, for example, there are several thread factories, while
local manufacture supplies nails, tacks, knives, wires, hammers, etc., in
far greater quantity than is required for use in Leicester. Thus too do
we explain the prosperity of local tanneries and of firms specialising (on
the chemical side of the business) in the manufacture of dyes, stains,
inks, waxes, cements, paints, and so on. A further step in the same
direction brings us to an understanding of Leicester’s unique position
in boot and shoe distribution: hundreds of retail stores with branches
scattered all over the country are owned and controlled by Leicester
firms, who thus bridge the gap between manufacturer and customer.

The position with respect to the hosiery industry is very similar.
Wool-spinning, the manufacture of cotton threads and of rubber latex
threads, dyeing and finishing, box-making, needle manufacture, and so on,
tend to make Leicester more and more independent of her neighbours,
more and more self-sufficing.

Tyres for all types of vehicles, from perambulators to omnibuses and
aeroplanes ; elastic web measured in miles, buttons in millions ; all sorts
of celluloid articles; fountain pens, dolls, cameras; cigars; pies and
cheeses, confectionery ; ready-made suits; show-cases, shop fronts,
metal stands, electric signs ; umbrellas ; medical dressings and surgical
appliances ; corsets, corselets, brassieres, girdles ; furniture, upholstery,
cane goods ...and so might one prolong the list. Versatility, a
refusal to hang on to just a couple of staples—this is, it would appear,
the interpretation of the group-mind of Leicester.

VIII.

MUNICIPAL ACTIVITIES OF
LEICESTER

BY
H. A. PRITCHARD,
TOWN CLERK.

The Corporation— Water supply—The Derwent Valley Water Board—Gas
undertaking—Electricity supply —Tramways and Omnibuses—Sewage dis-
posal—Open spaces and recreation areas—Roadway development— Judicial
Courts—Diocese—Civic status restored—Arms of the City.

IT is now just a century since the Royal Commission was appointed to
examine the then existing municipal corporations’ activities, and it was
in consequence of the famous Report of this Commission, generally known

MUNICIPAL ACTIVITIES OF LEICESTER 73

as ‘ the postscript to the Reform Bills,’ that municipal corporations were
established as they exist to-day.

The ancient governing authority of Leicester passed into history, and
on Saturday, December 26, 1835, the new Council was elected. ‘ Peace
and honour be unto the memory of their predecessors. January 1st,
1836.’ Thus reads the last entry in the Common Hall Books, the records
of the ancient Chartered Corporation which had governed the town for
so many centuries.

The newly-elected Corporation entered upon their duties with an
enthusiasm which the extreme democrat may admire, the antiquarian
regret. No doubt inspired with a desire to be thorough, the newly-elected
governing body proceeded forthwith to dispose of all the Corporation
plate and regalia. The gold mace was sold as a useless bauble. ‘Their
successors, during the decades which followed, have done their best to
recover what their predecessors so hastily disposed of, and, by the public-
spirited action of the citizens, much of it has since been restored. The
mace, purchased during the Commonwealth in 1669 to replace one lost
at the siege of the town in 1645, was repurchased from the then owners
by subscription in 1866. A mayor’s chain was acquired, and the serjeant’s
mace presented to the Corporation by a gentleman who purchased it
at the time of the auction.

A citizen of a century ago would gaze with astonishment upon the city
to-day. A country town of about 44,000 inhabitants in 1836, to-day
Leicester embraces a population of approximately a quarter of a million,
but to attempt an epitome of the doings, and to record the progress of
one of our great industrial centres within the space at disposal, is not
an easy task.

For many years there is little to relate of general interest. ‘The gradual
progress of the industries, the introduction of and improvement in
machinery, particularly in the boot and shoe trades, the enterprise of their
business men, and possibly their geographical position, and the nature of
their industries all tended to convert the old country town into the large
industrial centre we know as Leicester to-day.

Prompt advantage was taken of the powers conferred by the Sanitary
Acts, and Leicester as a public health authority was early in the field, but
it was not until the seventies, when the general trend was to absorb
existing undertakings for the supply of gas and water, that we find Leicester
enlarging her scope of control so as to include what are known as ‘ trading
undertakings,’ and it may be of interest to describe what the city’s activities
embrace at the present time.

WATER SUPPLY.

By the enterprise of a private company, Leicester received a supply of
water for some years before the date when public authority controlled it,
but as time progressed and the population increased, this supply became
inadequate, and further efforts on behalf of the private undertaking were
found to involve financial assistance by the city to enable their enterprise
to be carried on. Eventually the city authorities decided to acquire the
water undertaking, and contemporaneously to acquire the undertaking

74 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

carried on by a private company for the supply of gas for lighting purposes.
The water undertaking in Leicester is to-day supplied from ‘Thornton
Reservoir, completed in 1854 ; Cropston Reservoir, completed in 1870 ;
and Swithland Reservoir, completed in 1894. From these reservoirs the
undertaking can obtain 6 million gallons per day, but it was realised many
years ago that this supply was not sufficient to meet the ever-growing
demand.

Eventually a bill was promoted in Parliament in 1899, upon the advice
of the late Mr. John Breedon Everard, authorising the impounding of
water from the Valley of the Derwent in Derbyshire. The cities of
Nottingham and Sheffield and the borough of Derby at the same time
considered they were entitled to a supply from this area, and the result
was an arrangement whereby a joint board was established by an Act of
Parliament passed in that year. The Derwent Valley Water Board to-day
consists of representatives of the corporations of Leicester, Nottingham,
Derby and Sheffield, and from this source Leicester (being the pre-
dominant partner) receives an average daily supply of approximately
seven million gallons. ‘The whole of the works authorised to be con-
structed have not yet been carried out, but when they are completed, the
joint board will be enabled to supply an amount of water which will
furnish to Leicester an average daily amount of 10} million gallons.

The water obtained from the Derwent is excellent and, following upon
filtration at Bamford (the southernmost point of the Derwent watersheds),
the Leicester portion is delivered at Hallgates, some five miles out of the
city. At Hallgates the water is subjected to mechanical pressure filtration,
during which process it is decoloured and rendered alkaline. The first
process renders the water suitable for drinking and manufacturing pur-
poses, and the latter process is carried out as a prevention against plumbo-
solvency and action upon iron pipes.

Gas AND ELECTRICITY.

It has already been observed that the gasundertaking of the Corporation
was acquired contemporaneously with the water undertaking. Originally
operated by a private company, it has since 1878 formed part of the
Corporation’s activities. ‘The undertaking has developed extensively in
the course of years, and. to-day supplies the city and a considerable area
beyond with gas for power, industrial, and domestic purposes. There
are two large works, one at Aylestone, where the plant established is of
the Glover West vertical retort system, of a producing capacity of
105 million cubic feet per day, together with carburetted water gas plant,
capable of producing 6} million cubic feet per day. ‘This includes the
latest automatic plant of Messrs. Humphreys & Glasgow, capable of
producing 2+ million cubic feet per day. The second works, at Belgrave,
is also equipped with Glover West vertical retort coal gas plant, of a
producing capacity of 4 million cubic feet per day. The undertaking
has been financially a great success, and the Corporation have always
endeavoured to keep their plant in good condition and up to date.

Originally, the electricity supply by the city, under the powers of a
Provisional Order obtained in 1891, formed part of the undertaking

MUNICIPAL ACTIVITIES OF LEICESTER 75

carried on by the city’s gas department. A small plant was established at
Aylestone, and although current was taken for lighting purposes some-
what extensively in the centre of the city, it did not progress to any marked
degree for some years. It was found to be not entirely suitable for power
purposes.

In 1908 the Corporation, in order to meet the demand, promoted a
Private Act, and obtained power to sell current from the plant operated
by them for the purpose of supplying power to their tramways under-
taking, and under this provision they were enabled to supply consumers
by agreement for power purposes. ‘Thereafter, we find the demand for
current increasing to a very marked extent. Further plant was estab-
lished from time to time, and eventually the undertaking was severed
from the control of the gas department, and power obtained to build a
new generating station.

In 1919 the Corporation acquired a large area of land known as the
Freemen’s Meadow, and, in pursuance of powers possessed by them, have
erected on that site a very fine modern station. At Freemen’s Meadow
they have installed six units of 69,750 kilowatt capacity, generating
upwards of 108 million units per annum, of which they dispose of
approximately 86 millions. The rates for supply are low, and electricity,
largely the prime mover in the city factories, is becoming more and more
extensively used.

TRAMWAYS AND OMNIBUSES.

In pursuance of their general policy to absorb all public utility under-
takings, the Corporation acquired in 1902 the then existing tramways,
and obtained powers by an Act of that year to operate them municipally.
They at once proceeded to extend their route mileage, and to-day operate
178 tramway cars upon 23 miles of route. The undertaking has been
maintained out of revenue, and is to-day probably one of the best services
of its kind in the country.

In order to link up, and to meet the growing demands for transport,
the Corporation further obtained powers in 1930 to operate a fleet of
omnibuses. These, sixty-two in number, now serve most districts within
the city.

SEWAGE DISPOSAL.

Leicester is so situated that, except in the river valley, it is surrounded
by rising country, and as a result the city has been put to considerable
expense in dealing with its sewage. In common with other large cities,
the proper drainage of the district and the sewage disposal have become an
ever-increasing problem. This difficulty was somewhat accentuated in
Leicester in consequence of the extensive pumping required.

The first works were constructed at the Abbey Meadow in about 1853.
The sewage was then pumped into tanks, lime was mixed by means of
agitators, and the effluent run off into the river. In 1877 ten acres of
additional land were purchased, and additional tanks were constructed,
but following a report by their then surveyor, the Beaumont Leys Farm
was acquired, consisting in the aggregate of about 2,000 acres. The

76 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

scheme was completed in 1891, and consisted of a pumping station and
14 miles of double 33-in. rising mains, sedimentation tanks, etc. In
1894 an 8-ft. diameter storm outfall culvert was constructed at a cost of
£80,000, leading from the Abbey Pumping Station to Wanlip, about four
miles away, with a discharging capacity of about 80 million gallons per day.

An increase in the population necessitated further works, and in about
1902 the sewage from the Belgrave district was, by increased pumping
plant, dealt with at Beaumont Leys Farm. Further sedimentation tanks
were constructed, and 12 acres of contact beds laid down. The sewage
was treated in this manner until 1912, and, despite the fact that the main
beam engines at the Abbey Pumping Station had been working night and
day with efficiency for nearly forty years, the town had outgrown their
pumping capacity, with the result that slight storms overflowed the weir
discharging into Wanlip.

A scheme was prepared by the late City Surveyor, Mr. E. George
Mawbey, in consultation with the late Mr. G. Midgley Taylor. It has
already been observed that Leicester lies in a basin, and all sewage has
consequently to be pumped 167 ft. to Beaumont Leys Farm for treatment.
Belgrave Pumping Station raises the flow from that district, amounting
to 660,000 gallons d.d.w.f. through a 15-in. pumping main to the old
high-level works. ‘The remaining d.d.w-f. flows to the Abbey Pumping
Station, partly through three 5-ft. diameter cast-iron pipes passing under
the river into the large bellmouth, and partly through the new 5 ft. g in.
diameter western main outfall, the whole discharging into the new
screening chamber. The flow enters the screening chamber by a new
16-ft. by 5-ft. reinforced concrete culvert, and is joined by the western
main before referred to. ‘The sewage is then screened by four electrically
driven screens and raking apparatus. It then passes through four
detritus tanks, 108 ft. long by 20 ft. wide, where heavy mineral matter is
intercepted. The detritus is removed by an electrically driven travelling
grab crane which runs along the outer walls of the tanks. The detritus
is tipped on land which has been purchased by the Corporation for this
purpose. The sewage flows continuously through these tanks over weirs
at both inlet and outlet ends. At the latter three times the dry weather
flow, amounting to 23 million gallons per day, flows direct to the pumps.
The sewage in excess of the 23 million gallons flows over a weir 148 ft.
long, through a reinforced concrete spillway to five underground storm
water tanks, having a total capacity of 24 million gallons. There are
numerous other ancillary works, and the sewage system to-day in Leicester
is proving very effective.

OPEN SPACES AND RECREATION AREAS.

Leicester has long been known for its numerous open spaces, and
approximetely one-tenth of its area is appropriated for this purpose.

The Victoria Park embraces an area of 69 acres. It is situated on the
main road to London, and was for a number of years used as a race-course.
The site forms part of the town’s ancient estate, and is now appropriated
for general use as an open space. It is in this park that Leicester’s
famous War Memorial, designed by Sir Edwin Lutyens in the form of

MUNICIPAL ACTIVITIES OF LEICESTER 77

an Arch of Remembrance, is situated, and the gates at the entrances to
London Road and Lancaster Road, the generous gift of Sir Jonathan
North, were also designed by the same architect.

The Abbey Park, situated to the north-west of the city, embraces
57 acres. This park was constructed upon land reclaimed after Leicester’s
flood prevention scheme. Upon the opposite side of the stream stands
Leicester Abbey, the gift to the city of Lord Dysart. Cardinal Wolsey
was buried here, though the actual position is not known.

The Western Park, situated as its name implies on the western side of
the city, is the largest open space possessed by the city. One hundred
acres are appropriated as a park and for recreation, cricket, football, and
tennis, and 84sacres for the purpose of an 18-hole golf course.

About a quarter of a mile away, another intersting addition to the
Corporation’s parks and open spaces has recently been acquired. ‘The
city purchased a few years ago a large estate of approximately 1,000 acres
to enable them to proceed with their very extensive housing schemes.
The park has been appropriated by the Corporation as an open space.

There are numerous other recreation grounds and open spaces, and it
would not do to leave this feature of our city without a reference to
Bradgate Park, which consists of some 1,000 acres, once the home of
Lady Jane Grey. It was purchased by the late Mr. Charles Bennion and
presented to the city and county. The freehold is vested in the city and
county jointly, and is managed by a trust, upon which the city and county
are represented, together with three donor’s trustees. ‘The park is main-
tained in its original condition, and forms one of the most attractive features
of the county.

Roapway DEVELOPMENT.

Leicester, in common with all other of the old English towns, has had
to consider and, at very serious expense, endeavour to adapt itself to
modern requirements. Many improvements of purely local importance
have been effected from time to time by our ancestors, but the exigencies
of modern traffic have forced us to consider town development upon
a greater and more far-reaching scale.

Apart from an improvement in the High Street about thirty years ago,
Leicester had made no serious attempt to widen her main thoroughfares
until 1922, when a proposal was submitted for widening the main street
from the Midland Station to the Clock Tower. This proposal, while
relieving one of the most congested thoroughfares in the city, would
have had to have been supplemented by some means by which the traffic
could have passed on. It did not, however, gain local support and was
abandoned.

Later, a scheme was submitted by the Corporation of a somewhat
Napoleonic character. This scheme, prepared with great care, would,
in effect, have immensely improved the internal communications in
Leicester in the course of time, in addition to providing better means for
dealing with through traffic. The scheme would have involved a gross
expenditure, according to the estimates submitted, of approximately
£3,830,000, and would have dealt with traffic east and west as well as

78 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

north and south. It was not intended to do otherwise than take parlia-
mentary powers to acquire the requisite properties compulsorily, and the
scheme would have been put in hand in sections as and when time
proved practicable.

The proposal, however, met with severe opposition. ‘There appeared
to be a general impression that the huge expenditure involved would be
incurred immediately, and was beyond the financial capabilities of the
city. Without expressing any view as to whether this objection could
have been sustained, it undoubtedly would have made Leicester, in days
to come, a vastly different town from what it is at the present time. How-
ever, the proposal was not approved, and in consequence, in the year
1924, the Corporation submitted a modified scheme which involved the
construction of a new street passing from the London road immediately
below the present Midland Station and going straight across the Humber-
stone Gate to the Old Cross, Belgrave, and by the widening of Belgrave
to the Great Northern Station, achieving a wide and direct thoroughfare
north and south. Certain connecting approaches were also embraced.

The proposal was submitted to Parliament and duly sanctioned. The
estimated expenditure for the execution of the necessary street works and
the acquisition of the lands was £1,111,000.

Parliament considered the work so essential for traffic purposes, that
the Corporation were placed under an obligation not only to acquire the
lands, but to construct the works within ten years from the passing of the
Act. The actual street construction has been carried out, and through
communication has been effected, the new road being 85 ft. wide.

This internal improvement, the largest ever undertaken by the city of
Leicester, and one of the largest undertaken by any of the great towns, is
undoubtedly proving an immense traffic convenience.

JupiciaL Courts.

The city of Leicester has long had its separate Commission of Assize,
and although prior to the Reformed Corporations Act, Leicester had long
possessed a Recorder, it was granted a separate Court of Quarter Sessions
in 1836 and a separate Commission of the Peace in the same year.

Tue DIOCESE OF LEICESTER.

Leicester was a diocese in the year 680, consequent upon the division
of the diocese of Mercia, but ceased to be a diocese in 870, following the
Danish Invasion. In 1072 it became part of the then newly established
diocese of Lincoln, and in that diocese it remained for more than 750 years,
until it was transferred to the diocese of Peterborough in 1839. It was
separated from the diocese of Peterborough in 1927, and now forms the
centre of the diocese of Leicester. ’

Civic STATUS AND City ARMs.

Leicester, as we have seen, was a city so far back as 200 years before
the Norman Conquest, but lost its civic status in the manner already
related.

MUNICIPAL ACTIVITIES OF LEICESTER 79

In the year 1919 their present Majesties King George and Queen Mary
officially visited the city, and in commemoration of that occasion by
Royal Warrant restored to the city their civic title, and in 1928 by Royal
Warrant the title of Lord Mayor was conferred upon its Chief Magistrate.

Leicester is proud of its ancient history, and it may be fitting to con-
clude with a short description of the Arms of the City.

The Arms of the City of Leicester are held by prescription and not by
grant, and date back earlier than the College of Heralds itself. ‘The
circumstances attending the user of portions of the Arms are lost in the
mysteries of the past. The cinquefoil, forming the centre-piece, probably
takes its origin from the following circumstances.

After the Conquest, the Norman earls controlled the small centres of
population, which then constituted the boroughs, and the townsmen were
the earl’s men who followed him, each using the device effected by their
respective lords. The cinquefoil was the device adopted by Robert
de Beaumont, first Earl of Leicester, and used by Fitz Parnel, one of his
successors. It was commonly used and adopted at that time by the
burgesses as their device. Its origin is uncertain.

The Wyvern, which appears as the crest upon the helmet, is derived
from Thomas, Earl of Lancaster and Leicester. It appears upon his seal
in 1301. Itis described in Boutell’s English Heraldry Book as ‘ a fabulous
creature, being a species of dragon with two legs and represented with its
tail nowed, that is to say, coiled in a knot as a snake.’ It would appear
probable, that the Wyvern was used by the men of Leicester from the
earliest times. It is recorded in the early days of the Wars of the Roses,
that the followers of each lord were led to the field under distinctive
banners, which were emblazoned with well-known crests or heraldic
emblems. The townsmen played a conspicuous part in the battle of
Towton Moor on the Yorkists’ side, and it is recorded that they met
under their various banners: the Black Ram of Coventry, the Ship of
Bristol, the Dragon of Gloucester and the Griffin of Leicester. ‘The
Griffin is the Wyvern referred to.

The Arms of the City were confirmed in 1681, in the reign of Charles II,
and upon the charter already referred to, granted by his present Majesty,
restoring the title of the civic dignity to the city, the College of Heralds
granted supporters—‘ on either side a lion reguardant Gules gorged with
a Ducal Coronet suspended therefrom by a Chain or a Cinquefoil ermine
pierced Gules.’

80 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

IX.
EDUCATION IN LEICESTER

BY
F, PP) ARMITAGE,’ C:B‘E.,"M.A:,
DIRECTOR OF EDUCATION.

Early History—Thomas Wyggeston—Collegiate School—Technical Classes—
College of Art and Technology—School of Cookery—Wyggeston Boys’ and
Girls’ Schools and Alderman Newton’s—Mary Royce’s Night Classes—
Canon Vaughan and the Vaughan Working Men’s College—Adult School
Union—Workers’ Educational Association—Leicester Education Authority
and the 1918 Act—Schools Grouping Scheme—Provision of Playing Field
Facilities—‘ Experimental’ School—Special Schools—Medical Inspection—
After-school Employment—Additional Secondary Schools—Growth of- the
Colleges of Art and Technology—Founding of the University College—
Vaughan College becomes the Extra-mural Department of the University
College.

IN the sixteenth century Thomas Wyggeston founded a free school in
High Cross Street, and for 150 years there was no other place of public
education in the town. Then, in 1708, a school was built in East Bond
Street by members of the Great Meeting. In 1761 Alderman Newton
founded his Green Coat School; St. Mary’s, the first parochial school,
was built in 1783; St. Martin’s in 1790, St. Margaret’s in 1807. The
County National School, built by subscriptidn in 1814 on a piece of land
provided by the Crown, was intended to be a central model school for
town and county; here young masters received. their first lesson in
the art of teaching. The population of Leicester was then 24,000.

Between 1814 and 1870 more schools were built by the Established and
Free Churches and by the Roman Catholics. Private enterprise provided
the Collegiate School—at first a private secondary school for boys, among
whom was Wallace the naturalist—and the Proprietory School, the
buildings of which were taken over by the Corporation for the purposes
of a museum in 1848.

By 1870 Leicester’s population had grown to 96,000. In the various
schools in the town providing an elementary school education there
were 10,053 pupils; the accommodation required under the 1870
Education Act was 17,903. During the next five years eight schools were
built accommodating over 7,000 children.

At this time the leaving age was 13, but total exemption could be
attained at the age of 10. The percentage of attendance was sometimes
as low as 70. By 1892 it was 81—but 818 cases were heard by the
magistrates. ‘To-day the percentage of attendance is almost go, and
scarcely a case ever comes before the magistrates. In 1892 there were
1,588 half-timers on the school rolls—two years later there were none.”

EDUCATION IN LEICESTER 81

Meanwhile special instruction had been provided for the mentally
deficient, the blind and the deaf, and a school at Desford opened for
children committed by the magistrates.

For many years a Committee working under the influence of the
Leicester Chamber of Commerce was responsible for technical classes
in hosiery and boot and shoe manufacture; these were held at the
Wyggeston Boys’ School (now the Alderman Newton’s) and in the old
Mercury Office, 21 St. Martin’s. Moreover, since 1870, a private
society had maintained a School of Art.

In the early nineties a Technical and Art Schools Committee of the
Corporation was formed; the first wing of the College of Art and
Technology was opened in 1897.

In 1877 the Leicester and Leicestershire School of Cookery was
established in No. 21 St. Martin’s. From 1890 to 1907, before it was
taken over by the Education Committee, it was known as the North
Midland School of Cookery.

When the Education Act of 1902 came into force there were three
secondary schools in the borough—the Wyggeston Boys’ and Girls’
Schools and the Alderman Newton’s. The former came under the
Education Authority in 1909, the latter in 1910. In 1908 what had been
a pupil teachers’ centre was converted into a dual secondary school, the
Newarke School.

During the second half of the nineteenth century private effort had
done much to put the tools of knowledge within reach of the illiterate.
Mary Royce chose to teach boys when the Sunday school was opened
in Sanvey Gate in 1868. Soon she was teaching the three R’s, chemistry
and French to week-night classes, then taking her pupils for holiday
rambles. Ultimately she built the Royce Institute in South Church
Gate.

The Rev. Daniel James Vaughan was Vicar of St. Martin’s. Following
the example of his friend F. D. Maurice, who founded the London
Working Men’s College, he opened, in 1862, the Working Men’s
Institute in Union Street. This institute became known as the Working
Men’s College, and when Canon Vaughan died in 1905 there were over
2,000 students on the rolls. In 1908 the Vaughan Working Men’s
College and Institute in Great Central Street was opened by Sir Oliver
Lodge.

In 1822 Thomas Cooper, the Chartist, started an adult school ‘ for
the poor and utterly uneducated.’ Other schools gradually came into
being in town and county, and in 1889 the Leicestershire Adult School
Union was formed.

In 1908 a branch of the Workers’ Educational Association was formed
in Leicester.

The passage of the 1918 Education Act almost coincided with the end
of the war and the consequent return of teachers from military service.
All was ready for an advance. The first thing done was to institute a
-general examination for all children between 11 and 12 who were
competent to get a fair percentage of marks. This threw on the
Authority the responsibility of pointing the way to secondary schools to

F

82 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

qualified children. The examination revealed the extraordinary differ-
ence in attainment of children of the same age in the elementary schools.

In accordance with the new Act, the Leicester Education Authority—
like other Authorities,—prepared a scheme to cover the developments
proposed for the next ten years. The core of their scheme lay in
grouping the schools in the several areas of the town. This grouping
allowed the bringing into certain schools of sufficient children over 11
to allow at least duplication of classes (boys and girls separately) for
those of approximately the same year of age, the schools from which
they were transferred becoming Junior Schools with a similar duplication
of classes. Moreover, it was found possible to reserve one school in an
area for children who had qualified for a secondary education but whose
parents for one reason or another could not permit them to go to the
secondary school. In these intermediate schools children were to
follow a curriculum similar to the conventional secondary school curri-
culum, that they might easily be transferred to secondary schools should
their parents on second or third thoughts wish this.

The Geddes axe came down upon many of the proposals made under
the 1918 Act, but that portion of the Leicester scheme which affected
‘ grouping ’ was put into operation, area by area, till in 1929 all the
Council schools and most of the non-provided schools were reorganised.

Meanwhile the Hadow Report in 1926 gave national recognition of the
principle on which Leicester had worked since 1921.

About the same time that the Authority began to reorganise their
schools they began to provide playing-field facilities for the senior
children. To-day every child over 11 has one organised game per week
on the 87 acres owned or rented by the Authority, or on the parks and
recreation grounds.

As one result of the duplication and triplication of classes and the
consequent modification of curricula to suit different categories of
intellect and interest it has been found possible to reduce the number
of those transferred to special schools. On the other hand, it became
very apparent that there was need for a school of a special type to deal
with cases of special disability as to reading, writing, behaviour, etc. The
Committee, therefore, opened an ‘ experimental ’ school at Haddenham
Road, where such problem cases could spend 3, 6, 9 months, 1 year,
2 years, as the case might be, until the disabilities were removed and the
children could return to the normal schools.

Infant departments were unaffected by grouping, but, during the
last five years, nursery classes to the number of 23 have been provided
where children between 3 and 5 can be educated as in nursery schools
in good social habits.

The school for the deaf and semi-blind is accommodated in a mansion
situated in beautiful grounds in Stoneygate. A new school for the
mentally deficient has recently been built. The much larger premises
hitherto occupied by them—also a mansion in extensive grounds,—have
been appropriated by the experimental school.

The Leicester Education Authority have made very complete provision
for the medical inspection and treatment of children in the elementary

EDUCATION IN LEICESTER 83

and secondary schools. Every child in the former is inspected three
times during school life. There are three dental clinics, an eye clinic,
an operative clinic with twelve beds for tonsils, adenoids and mastoids
and an operative clinic for crippling. For many years X-ray treatment
has been provided. It is worth noting perhaps that the records of school
medical officers show that since 1902 there has been an average increase
in height of the Leicester boys of 1 in., girls, 14 in., and an average
increase in weight of boys by 6 lb., girls 8 lb.

During the last term of an elementary school child’s life he is visited
at the schools by the Committee’s employment officers and advised as
to the vacancies that have been notified by employers, and his own
qualification for filling them. At the age of 16, when he becomes eligible
for unemployment benefit, he must attend an evening institute as a
condition of getting this benefit.

It has been stated already that one result of the general examination
was to show the extraordinary diversity of academic attainment among
elementary school children—it also showed how many there were qualified
to profit by the conventional type of secondary education in comparison
with the number of places in secondary schools available. ‘The Education
Committee, in 1919, immediately took steps to remedy this—the provision
of intermediate schools has been referred to above,—by providing a
Secondary Boys’ School and two Secondary Girls’ Schools, one (the
Collegiate) by purchase from a private owner. ‘There were then 3,500
places available. But the Committee were not satisfied that the con-
ventional secondary curriculum was adapted to provide a right form of
secondary education for all of ability to profit by staying at school till
at least 16. In consequence they opened a new type of school—the
Gateway School for Boys,—in which those of marked ability but with
no special interest in acadeinical subjects could be educated till 16 years
of age at least. They built, moreover, a ‘ Gateway School’ for Girls
in the Newarke, but for reasons of economy. transferred the Newarke
Girls’ School there and used the old Newarke School buildings in part
for administrative offices.

But it was not only in respect of full-time education that the post-war
enthusiasm displayed itself; each year the number of those attending
the evening schools, particularly students over 18, increased. The
evening classes at the Technical and Art School—now the Colleges of
Art and Technology,—grew till they more than filled the premises of a
large Secondary School as well as that of the College which had already
been increased by an additional wing in 1898. It was necessary to add
another wing, and even then the premises were not big enough—the
completion of the building is only held over until the present straightened
circumstances are passed.

The 1918 Act made it incumbent on the Authority to make such
provision that no boy or girl should be deprived of any form of education
by which he or she could profit. ‘There was no University or University
College in the immediate neighbourhood : Leicester set out immediately
to develop one of her own. The University College was registered as
a company in 1921; a site had been presented and a considerable

F2

84 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

endowment fund provided. ‘To-day there are 94 full-time and 116 part-
time students on the College rolls.

It should be noted that during the year 1931-32, from the city alone,
11g secondary school pupils obtained exemption from the London
Matriculation and 21 passed the Intermediate Examination for the
B.A. Degree.

Since its opening the Vaughan College has been the centre of education
conducted in the spirit of its founder. In 1930 the Board of Governors
handed the buildings and endowment over to the University College
as a home for the extra-mural classes conducted under the latter’s zgis.
The development of extra-mural work has been in consequence very rapid.
Half the building was let to the Education Committee for the holding of
adult classes in connection with the Evening Institutes. This adult
Vaughan Institute has proved extraordinarily popular.

In connection with the great developments referred to above, one
name must be mentioned, that of Alderman Sir Jonathan North, D.L.,
J.P., who for 26 years has been chairman of the Education Committee,
and (from its earliest days) chairman of the University College Council.

It is believed that in very deed the way to the top by any recognised
route is open to every Leicester child. By free places, maintenance
allowances, scholarships, and loans the travelling along this route is
made possible to the poorest.

X.

MEN OF SCIENCE IN LEICESTER
AND LEICESTERSHIRE

BY
F. B. LOTT, M.A.

Individual Scientists in Early Days—William Lilly, 1602-1681—William
Ludlam, 1717-1788—Robert Bakewell, 1725-1795—-Richard Pulteney,
1732-1814—Richard Phillips, 1767-1840—Henry Walter Bates, 1825-1892
—tThe Scientific Sections of the Leicester Literary and Scientific Society—
Geology, Botany, Zoology, Meteorology, Chemistry and Physics, Ento-
mology, Economics, and Astronomy—tThe Leicester Museum, 1849—-1914—
Brief Sketch of more Recent Changes and of Present Conditions.

Tuis chapter gives a short account of men born in, or connected with’
Leicestershire who did notable work in science.

The first of these is that of one widely known and important in his
lifetime—William Litty (1602-1681). He was born at Diseworth and
educated at the Grammar School, Ashby-de-la-Zouch. Early in his life

°

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 85

he went to London, and there he was a very successful practitioner in
astrology—not without some mixture of medicine and politics. He
wrote his autobiography. He occupies more than eight columns in the
Dictionary of National Biography.

The next name is that of the Rev. William LupLam (1717-1788),
mathematician. He was the son of Richard Ludlam, M.B. Cambridge,
who practised in Leicester. He went from Leicester Grammar School
to Cambridge and became a Fellow of St. John’s College. In 1749 he
was Vicar of Norton-by-Galby, Leicestershire. In 1768 he had the living
of Cockfield in Suffolk. He then gave up his fellowship and came to
live with his brother Thomas, who was Confrater of the Wyggeston
Hospital in Leicester. In 1772 he married, but he lived on in Leicester
till his death in 1788. During these last twenty years of his life he wrote
most of his works. His Rudiments of Mathematics (1785) ‘ became a
standard Cambridge text-book, it passed through several editions and was
still in vogue in 1815.’ Six other mathematical publications are named
in the Dictionary of National Biography. An essay of his on Newton’s
Second Law of Motion, for which he proposed to substitute something
of his own, was rejected by the Royal Society. The Society accepted
papers by him on mechanics and on astronomy.

Robert BAKEWELL (1725-1795), the son of a farmer, was born at Dishley.
He succeeded his father in the farm and became one of the most successful
and perhaps the most renowned of scientific agriculturists. His fame
rested on his great success in improving the breed of sheep. He developed
a breed known as ‘ Leicesters,’ with long lustrous wool. This was of
importance not only to the manufacturers of hosiery in Leicestershire ;
the ‘ Leicesters ’ were prized in other counties, and were for many years
known in France as ‘ Dishleys.’ Bakewell also improved the breed of
cattle. He was successful in irrigating grassland and in all details of
farm management.

“Many of the present humane notions regarding animals were antici-
pated by Bakewell, his stock being treated with marked kindness, his
sheep being kept “‘ clean as race-horses, and sometimes put into body
clothes,”’ and even his bulls were remarkable for obedience and docility ”
(Quotation in the D.N.B. from Throsby’s Views in Leicestershire).

Joseph PaceT (1700-1789) and ‘Thomas PaGeT (1732-1814), of Ibstock,
were friends of Bakewell of Dishley. ‘They worked on the same lines,
being pioneers of land drainage and of cattle and sheep breeding. Later
Pagets were eminent in Leicester as surgeons and as bankers. One of
the family, John Paget (1808-1892 see D.N.B.), having married a Hun-
garian lady, introduced scientific agriculture in Hungary. He wrote
a book on Hungary and Transylvania.

Richard PuLTENEY (1730-1801), physician and botanist, was born at
Loughborough. His father, Samuel Pulteney, was a tailor who had
some landed property, which passed to his son Richard. Richard Pulteney,
after being apprenticed to an apothecary, went to Leicester and was for
some years in practice there, with little success. He had, however, begun

86 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

to write on botany in the Gentleman’s Magazine, and had sent some papers
to the Royal Society. His mind had been guided to botany by an uncle,
his mother’s brother.

In 1764 he went to Edinburgh to get the degree of M.D. He got it
without spending time in residence. In the same year he went to London
and was introduced to William Pulteney, who in 1742 had been made Earl
of Bath. The Earl recognised him as a kinsman and made him his own
physician. Very soon the Earl died. Dr. Pulteney then went to Bland-
ford in Dorset. He quickly made a fortune by a very widely spread
practice. He devoted his leisure to botany and conchology. His most
important works were A General View of the Writings of Linneus (1781),
and Historical and Biographical Sketches of the Progress of Botany in
England (1790). Among his minor writings was ‘ A Catalogue of rare
Plants found in the Neighbourhood of Leicester, Loughborough, and
Charley Forest.’ This was contributed to Nichols’s great book on
Leicestershire.

Richard PuILuips (1767-1840) came to Leicester and opened a com-
mercial academy in 1788. He is not eminent as a man of science, but he
did, in conjunction with William Gardiner, Leicester’s most famous
amateur musician, found a society for scientific investigation. It was
called ‘ The Adelphi.’ A number of young men joined it. It was, so
far as the compiler of these notes can ascertain, the first attempt in
Leicester to initiate the co-operative scientific study of a society, as dis-
tinguished from the studies of individual persons. The society had a
short life. It was suspected of sympathy with the French Revolution
and soon suppressed by the Town Authority. In 1790 Richard
Phillips opened a shop for books and medicines. He was imprisoned for
eighteen months for selling The Rights of Man by Tom Paine. In 1796
he went to London. He became a remarkably successful publisher of
educational and scientific books. In 1807 he was Sheriff of London.
In 1808 he was knighted by George III. Sir Richard Phillips lived till
1840.1

In 1845-46 a friendship began in Leicester between two young men
who both afterwards became famous. Henry Walter Bares (1825-1892),
a native of Leicester, and Alfred Russel WALLACE (1823-1913), who was
at that time an assistant master in the Collegiate School.2 H. W. Bates,
after some education at Creaton’s boarding school at Billesdon, had been
apprenticed to a hosier, his duties comprising opening and sweeping up
the warehouse between seven and eight in the morning. Subsequently
he worked as aclerk. ‘ His scanty leisure he devoted to self-improvement
at the liberally managed Mechanics’ Institute. His holidays when
possible were spent in scouring Charnwood Forest with his brothers ;
for he was already an enthusiastic entomologist and collector. His first
contribution to entomological literature was a short paper on ‘ Coleopterous

1 An Old Leicester Bookseller, by F. S. Herne.

* The first headmaster of the Collegiate School was William Thompson, then
Fellow and afterwards Master of Trinity College, Cambridge. J. F. Hollings

was a master and F. T. Mott a scholar at the Proprietary School. (They will be
mentioned later.) (Leicester Memoirs, by C. J. Billson.)

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 87

Insects frequenting Damp Places,’ dated Queen Street, 3 Jan., 1843,
and printed in the first number of the Zoologist.

A. R. Wallace had taken up botany and started an herbarium in 1840.
They joined in the study of entomology and they both read Malthus on
Population and Darwin’s Journal of a Naturalist. In 1848 they went
together to the Amazons. Bates spent eleven years there, and in 1863
published The Naturalist on the Amazons, having been urged to publish
the book by Charles Darwin. In 1864 he became assistant-secretary to
the Royal Geographical Society : ‘a post which, to the inestimable gain
of the Society, and to the advantage of a succession of explorers, to whom
he was alike Nestor and Mentor, he retained till his death’ (Encyclopedia
Britannica, Article ‘ Bates, Henry Walter ’).

LEICESTER LITERARY AND PHILOSOPHICAL SOCIETY.

So far these notes have been about men whose scientific studies were
personal and shared, if shared at all, only by kinsfolk or private friends.*
In the last quarter of the eighteenth century and in the first half of the
nineteenth many local societies for co-operation in studies were formed.
This movement was checked and suspended during part of that period
by the shock of the French Revolution, by the long war which followed
it, and by the bitter party spirit which prevailed after the war.

Among the earliest of these societies was the Manchester Literary and
Philosophical Society. It was founded in 1781. It lived through the
troublous years. In 1835 George Shaw, M.D., who had been a member
of the Manchester Society before he came thence to Leicester, and his
friend, Mr. Alfred Paget, were the prime movers in the foundation of
the Leicester Literary and Philosophical Society.4 In 1837-38 this
Society began to collect a museum. The collection rapidly increased.
In 1849 it was presented to the town, formally accepted by the Mayor
at a large gathering, and housed in the building (which a few years
before had been built for the Proprietary School) purchased by the
Town Council for what thus became the Town Museum.

The Society had formed committees of its members to manage
departments of its Museum before presenting it to the town. For a
long time the connection between the Museum Committee of the Town
Council and the Council of the Society continued to be very close indeed,
the same persons being in many cases members of both. There can be
little if any doubt that the ‘ Sectional Committees’ of the Society for
the study of particular branches of Science, afterwards called simply
the ‘ Sections,’ originated from the committees appointed for ‘ depart-
ments’ of the Museum before it became the Town Museum. In the

3 Some more of the early botanists, especially the Rev. W. H. Coleman and
the Rev. A. Bloxam, whose works were used by the editors of The Flora of
Leicestershire will be mentioned later.

4 Prof. Sedgwick, at a dinner given to him in Leicester in October 1837, said :
‘The additions made to the great stream of knowledge by societies formed in
provincial towns were rich and copious. Manchester, from a period when it
was not more extensive than Leicester, had taken the lead. Cambridge and
Newcastle, York and Bristol, were following that bright example, he trusted that
Leicester would soon distinguish itself in the same noble course.’

88 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

course of years the relations between the Society and the Museum have
greatly changed, but up to the present time much of the most valuable
work of the Society, that of its Sections, has been done in close connection
with the Museum, not a little of it by officers of the Museum. The
following pages will tell of the subjects studied by the Sections and
indicate the shares in the work of some of the chief workers.

Geology was taken up by the Society before the Sections were definitely
constituted in 1849. In March 1837 the Rev. Andrew Irvine, B.D.,
F.G.S., in his Presidential Address, suggested that a Natural History
Museum should be formed, and said that he would willingly present to
it his own collection of specimens, mineralogical and geological. The
first honorary members of the Society were the Rev. William Buckland,
D.D., F.G.S., and the Rev. Adam Sedgwick, B.D., F.G.5., pioneers of
geology in Oxford and Cambridge. The latter spoke about the geology
of Charnwood Forest at a dinner given to him at the Three Crowns on
October 6, 1837.

The two members of the Society, who in these early days read most
papers on geology, were Mr. John Laurance,® who left Leicester and
became an honorary member in 1842, and Mr. James Plant, F.G.S.
The latter also spoke on geology at the Society’s excursions. On March 28,
1870, he lectured on ‘ Geological Formations of the County as illustrated
by the Column of Rocks in the Museum Grounds.’ He had constructed
this column in order to preserve in a permanent and educational form a
large number of specimens liberally supplied by the owners of quarries
throughout the county for exhibition at the meeting of the Royal Agri-
cultural and Royal Horticultural Societies at Leicester in 1868. The
column was removed when the Museum building was enlarged in 1877.
It was an imitation on a small scale of a huge column at the Great
Exhibition of 1851, and of others at the Crystal Palace.6 The late
Dr. F. W. Bennett remembered seeing it.

The section of the Society for Geology decreased in numbers during
the eighties, and though there were a few who were diligent in the study
hardly any papers were read, and the meetings dwindled away. The
Council in their Report in 1889 ‘ regret that Section C (Geology) has
been obliged to follow the example of Section B (Astronomy, Physics
and Chemistry), and ask the Council to terminate its existence. They
have however made arrangements for the amalgamation of Section C
with Section E (Zoology), so that the opportunity for organised study of

5 John Laurance was the author of a book entitled Geology in 1835: A
popular sketch of the Progress, Leading Features, and latest Discoveries of this
vising Science. The first sentence of the preface is: ‘ The attempt to compress
so vast a theme as Geology within the narrow limits of a duodecimo volume of
such spare dimensions will be regarded by those, who in ponderous tomes have
communicated to the world the results of years of labour in this department of
science, as absurd and futile.’ I

The book was published by Simpkin and Marshall in London, 1835, but printed
by Cockshaw in Leicester. Geology was then a rising science. The Geological
Society of London was founded in 1807. The Oxford Dictionary gives 1795
for the first quotation of the word in the modern sense. For many geological
words later dates, e.g. “ Cambrian,’ 1836. ¢

6 Leicester Chronicle, April 2, 1870.

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 89

Geology may not be lost.’ The records in the Transactions of Section E
show that the study was maintained.”

On January 16, 1899, while Geology was still amalgamated with Zoology,
Dr. Frederick William Bennett, M.D., gave an account of ‘ The Rocks
of Charnwood Forest.’ It was the first time in which his name appears
in the Transactions. The opening is thus recorded: ‘ During 1898
I studied the detailed descriptions of the Charnwood Forest Rocks given
by Mr. Hill and Professor Bonney and obtained a large number of
specimens of the rocks. I have arranged about 300 of these on a rough
map of the district so that comparison can easily be made between the
rocks of different parts.’

In 1899 those who were especially interested in geology petitioned
the Council ‘ in view of the increased interest in the subject to reconstitute
Section C.’ This was done. The reconstituted Section had for its
chairman, Hermann Alfred Roechling, C.E., F.G.S., whose professional
address was ‘ The Office of the Borough Surveyor,’ and for its vice-
chairman, Mr. Louis B. M. Hodges, the Headmaster of St. Martin’s
School. Mr. C. Fox Strangways, of H.M. Geological Survey, was a most
valuable member. The first paper on May 4, 1899, was by Mr. Hodges—
‘ Suggestions for working a Geological Section.’ In the first session there
were seventy-nine members. ‘There were twelve evening meetings, in-
cluding a conversazione, and six summer excursions, four of which were
conducted by Mr. C. Fox Strangways. The activity of the Section was
suspended during the war. It was very active before the war, and it has
been so since the war, under the leadership of the late Dr. F. W. Bennett,
who devoted the bulk of his spare time to the study of, and possibly
possessed an unrivalled knowledge of, the rocks of the Charnwood Forest.

List OF GEOLOGICAL PAPERS.

Mr. H. H. Gregory, M.A., the Honorary Secretary of the Geological
Section, has supplied the following bibliography of the works of members
of the Section. He has pointed out that it does not contain many valu-
able addresses, especially those by leaders of excursions, of which there
are scanty records in the Minutes of the Section. '

Bibliography of the Works of Members of the Geological Section
of the Literary and Philosophical Society.

1. PLaNnt, J.: ‘ Are the (Slate) Rocks of Charnwood Forest Laurentian ?’
Geol. Mag., 1865.

2. PLANT, J.: ‘ Geology of Leicestershire,’ Leicester Lit. & Phil. Soc.,
1874-75.

7 At this period the Transactions were printed at great length. ‘ A Contribu-
tion to the History of the Geology of the Borough of Leicester,’ by Montagu
Browne, F.G.S., F.Z.S., Curator of the Museum and Art Gallery, read before
Section E, begins with p. 123, and ends, with half a page of thanks to the many
who had helped him and to the Society for the publication, on p. 240. There
are illustrations and diagrams.

go

SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

. Harrison, W. J.: © The Syenites of South Leicestershire,’ Mid. Nat.,

1880, also 1884.

. BENNETT, Dr. F. W.: ‘The Charnwood Forest Rocks,’ Trans. Leic.

Lit. & Phil. Soc., 1903.

. BENNETT, Dr. F. W.: ‘ The Buck Hill Grit,’ zbid.
. STRACEY, Dr. B., and BENNETT, Dr. F. W.: ‘ The Felsitic Agglomerate

of the Charnwood Forest,’ Part I, ibid.

. StRAcEY, Dr. B.: ‘ The North-west of Charnwood,’ Trans. Lit. &

Phil. Soc., 1906.

. Keay, W., and Gimson, M.: ‘ The relation of the Keuper Marl to

the Charnian Rocks at Bardon Hill,’ ibid., 1907.

. STRACEY, Dr. B., and BENNETT, Dr. F. W.: ‘ The Felsitic Agglomerate

of the Charnwood Forest,’ Part II, ibid., 1907.

. Horwoop, A. R.: Vol. xii, Part ii, The Fossil Flora of the Leicestershire

and South Derbyshire Coalfield, and its bearing on the age of the Coal
Measures, 81-181.

. BoswortH, T. O., B.A., B.Sc.: The Keuper Marls around Charnwood

Forest. (Published by Leicester Lit. & Phil. Soc., 1911.)

. BENNETT, Dr., STRAcEyY, Dr., BoswortH, T. O.: ‘ Excursion to

Charnwood Forest,’ Proc. Geol. Assoc., xxii, 24, 1911.

. BENNETT, Dr., and Stracey, Dr.: ‘ Excursion to Charnwood Forest,’

ibid., Xxii, 205, IQI1.

. BENNETT, Dr., and Lowe, E. E., B.Sc.: ‘ Excursion to Mountsorrel,’

ibid., Xxili, 25'7, 1912.

. BENNETT, Dr. F. W.: ‘ Note on Morley Hill,’ Trans. Leic. Lit. G& Phil.

Soc., 67, 1922.

. BENNETT, Dr. F. W.: ‘ The So-called Junctions at Bardon Hill,’ Trans.

Leic. Lit. & Phil. Soc., 1923.

. BENNETT, Dr. F. W.: ‘ Age of the Charnwood Rocks,’ Trans. Leic.

Lit. & Phil. Soc., 1925.

. Lowe, E. E., Ph.D., B.Sc.: Igneous Rocks of the Mountsorrel District.

(Published by Leic. Lit. & Phil. Soc., 1926, price 6s. 6d.).

. Jones, F., M.Sc., F.G.S.: ‘ The Petrology and Structure of the Charnian

Rocks of Bardon Hill,’ Geol. Mag., xviii, 1926.

. Jones, F., M.Sc., F.G.S.: ‘ Preliminary Inquiry into direction of

Joints, Faults, etc., at Groby,’ Trans. Leic. Lit. & Phil. Soc., 1926.

. Jonss, F., M.Sc., F.G.S.: ‘A Structural Study of Charnian Rocks and

Associated Igneous Intrusions,’ ibid., xxviii, 24, 1927.

. Grecory, H. H.: ‘ Swanimote Rock,’ vol. xxix, Geology of Charnwood

Forest, Trans. Leic. Lit. & Phil. Soc., 15-20, 1927-28.

. BENNETT, F. W., Lowe, E. E., Grecory, H. H., Jones, F.: vol. xxxix,

Geology of Charnwood Forest, Proc. Geol. Assoc., 241-298, 1928.

. BENNETT, F. W.: ‘ Remarkable Features in the Ulverscroft Valley,’

vol. xxx, Geology of Charnwood Forest, Trans. Leic. Lit. & Phil. Soc.,
40-45, 1928-29.

. Lowe, E. E., Stracey, B., Grecory, H. H.: Jbid., vol. xxxii, Geology

of Charnwood Forest, 26-34.

. Stacey, B.: ‘On Some Swiss Glaciers,’ ibid., vol. xxxii, p. 45.

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 91

What is to be said of the botanists of Leicestershire may be introduced
by referring to the title-page and the preface of The Flora of Leicestershire.
This is the title-page :—

THE FLORA OF LEICESTERSHIRE
INCLUDING THE

CRYPTOGRAMS
WITH MAPS OF THE COUNTY
IsSUED BY THE LEICESTER LITERARY AND PHILOSOPHICAL SOCIETY

COMPILED BY THE FOLLOWING SUB-COMMITTEE OF THE
Socrety’s BioLocicaL SECTION : ®

F. T. Mort, F.R.G.S. Tuomas Carter, LL.B.
E. F. Cooper, F.L.S. J. E. M. Fincu, M.D.
C. W. Cooper, M.B.

On the basis of a manuscript prepared in
1852 by the late Rev. W. W. CoLeman,
which has been enlarged, completed, brought
up to date, mostly rewritten and entirely
rearranged in accordance with the third
edition of HooKer’s ‘ STUDENT’S FLORA.’

WILLIAMS AND NORGATE
1886

In the preface it is stated that the only published Flora of Leicestershire
was that of Miss Mary Kirby,® published in 1850; and that in 1875
Edwin Brown, Esq., of Burton-on-Trent, placed the manuscript of his
friend the Rev. W. H. Coleman ‘at our disposal.’ The manuscript
was dated 1852 and was almost ready for publication. Mr. Brown had
stipulated that if it were published Mr. Coleman’s name should be on the
title-page.

The preface goes on to say that there had been great changes in Botany
since 1852, and that more modern Flora had been published, that of
Plymouth by T. R. Archer Briggs, and that of Hampshire by F. Townsend.
Coleman had omitted nativity and habitat.

Three periods of botany in Leicester are then distinguished. The
first was before 1820. Its authorities were Richard Pulteney, George
Crabbe,!® and Dr. Arnold, a physician in Leicester. ‘The second period
of botany in Leicestershire was 1820-1850 A.D. Its authorities were the

8 At that time Section D was for ‘ Biology (Zoology and Botany).’ After-
wards it was for Botany only.

® Miss Mary Kirby (Mrs. Gregg) and her sister Elizabeth Kirby wrote many
story-books for children. She also wrote a very interesting book, Leaflets of
my Life. She had many botanical correspondents, including the Rev. W. H.
Coleman and the Rev. A. Bloxam.

10 See above, p. 85, for Richard Pulteney. George Crabbe, the poet, had
made a catalogue of plants in the vicinity of Belvoir.

92 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

Rev. W. H. Coleman and Miss Kirby (already mentioned), the Rev.
Churchill Babington, D.D., Fellow of St. John’s College and Professor
of Archeology, Cambridge, and the Rev. Andrew Bloxam of T'wycross
and Harborough Magna, near Rugby. He had been the naturalist on
board the frigate Blonde, in the Pacific Ocean in 1824-25. He was
Coleman’s chief colleague and he prepared the list of plants for T. R.
Potters’ book on Charnwood Forest.'? Others mentioned are the Rev.
Charles Cardale Babington, Professor of Botany, Cambridge; James
Harley, a well-known local naturalist; James Francis Hollings; the late
Rev. R. W. McCall, F. T. Mott; and John Plant.

The editors of the Flora stated that they owed the chapter on ‘ Algze’ to
Mr. Frederick Bates, a brother of ‘ Bates of the Amazon,’ and that they
had adopted, with some alterations, the chapter on ‘ Geography and
Hydrography ’ from the manuscript of the late Rev. W. H. Coleman.

Mr. Frederick Bates is also named in a comparatively long list of
those who helped the editors in their third period from 1850 to 1886.
In writing of this period the editors were to a great extent writing of
the work of themselves and of their contemporaries. One of them,
Frederick Thompson Mott, is remarkable in many ways in the history of
the Society. He was its President twice: in the sessions 1874~75 and
1890-91. He was chairman of the Section then named ‘ Natural
History,’ and later ‘ Biology,’ from 1879-80 to 1895-96, except for two
sessions, 1891-92, in which the Rev. 'T. A. Preston was chairman, and
1892-93, in which Mr. Thomas Carter was chairman. Mr. Mott’s
subjects were generally botanical or zoological ; but sometimes literature,
art, or philosophy. In March 1878, in a lecture to the Society entitled
‘A Modern Theory of the Universe,’ he ‘ proceeded to lay before his
audience the outline of a theory which, he contended, preserved all the
old truth, while at the same time it cast off all the worn-out garments,
and added a great deal that was necessary to bring it up to date.’ ... It
might seem to those who had been accustomed to regard matter as a real
and substantial thing, and energy as something altogether different,
that this theory which made active energy the only substance in the
universe was a mere dreamer’s speculation, but they must remember
that it was little more than a modern development of the conclusions of
such well-known thinkers as Plato, Descartes, Spinoza, and Bishop
Berkeley. In conclusion Mr. Mott said that in his judgment ‘ the
evolution of the organic world and the puzzling problems of social life
were much more rationally explained by this philosophy than by the
laws of natural selection and political economy as now understood.’

11 The Rev. William Higgins Coleman was a master in Christ’s Hospital School
at Hertford ; he was part author of a book on the Flora of Hertfordshire. In
1847 he came to the Grammar School of Ashby-de-la-Zouch. He contributed
notes upon mosses and flowering plants to the Flora of the district surrounding
Tutbury and Burton-on-Trent, by Edwin Brown in Sir Oswald Mozley’s Natural
History of Tutbury, 1863. The writer of the article on him in the Dictionary of
National Biography does not seem to have known of his manuscript Flora of
Leicestershire.

12 The Rev. Andrew Bloxam is also in the D.N.B.. It is there said of him ;
‘ He may be regarded as perhaps the last of the all-round British naturalists.’

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 93

Further, that, as an elevating and moralising influence upon mankind,
some such view of the universe as that suggested by this philosophy
would be the next great influence brought to bear upon society in the
next era of mental struggle and reform (Transactions of Leicester Literary
and Philosophical Society, vol. iv. (1895-98), pp. 510-513.7%

Mr. Mott was certainly a man of a very active and self-confident mind
which delighted in the details of botanical observation, and in those bold
flights or dives by which science soars or plunges into philosophy.

Among those who were thanked by the editors of the Flora was
James Francis Hollings. He was a master in the Proprietary School and
had taught F. T. Mott. ‘He was a deeply learned man and studied
science as well as literature.’ ‘ His weekly lectures on science, many
of which were open to the public, were, as Mr. Mott says, “ an important
feature of the curriculum of the school.” They were always “ illustrated
by experiments,- specimens or diagrams. His varied and accurate
knowledge was surprising. Chemistry, geology, botany, or physics—
he seemed to be familiar with almost every branch and was always able
to make his subjects interesting. . . . Many of his pupils have kept up
their interest in science and owe to him their initiation into this delightful
study.” ’ 14

But though he taught science not only to schoolboys but to adults in
lectures and papers at the meetings of the Literary and Philosophical
Society and at the Mechanics’ Institute, his chief studies were in literature
and history, of which he had a very wide knowledge, together with the
ability of dealing with a particular subject, as in his History of Leicester
during the Great Civil War. He was thrice President of the Literary and
Philosophical Society and Mayor of Leicester in 1859. He died in
1862.

The Rev. Thomas Arthur Preston, Rector of Thurcaston (1885-1905),
was an excellent member of the Botanical Section of the Society. In
December 1gor he read a paper in which he sketched a plan for a second
edition of the Flora and enumerated seventeen points for immediate
consideration. It is hoped (April 1933) that this edition will soon be
published. Other papers were Reports on the Herbarium. In 1898 the
number of specimens had been calculated to be 5,826. In 1902 he con-
sidered that the Herbarium had just been doubled. ‘Two old Herbaria
had been acquired, one of them that of Miss Kirby.

At the first meeting in February 1905, after the death of Mr. Preston,
the Section placed on record an emphatic minute to express appreciation
of his work in all branches of botany and of his kindness in helping
members individually.1°

An interesting botanical theory was introduced in a paper, entitled
‘On Lichens,’ read by Miss Gertrude Clarke in February 1893. She said

13 In 1883 he argued that instead of two great divisions of organic life there
should be a primary fourfold division into Thallophytes, Protozoa, Cormophytes
and Metazoa (Transactions, 1882-83, p. 53).

14 Leicester Memoirs, by Charles James Billson.

15 ‘A Reminiscence and an Appreciation,’ by Mr. William Bell, was read
before Section D, May 20, 1908 (Tvansactions, xii, 211-220).

94 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

that it had been first propounded twenty-five years before by Prof.
Schwendener, that it had at first been met with contempt and ridicule,
and was still disputed. The theory was: ‘ Each Lichen is not a simple
plant at all; but each is really an establishment of two plants living in
intimate union and for their mutual benefit. Every Lichen 1s a Fungus
and an Alga.’

In October 1894 she (Mrs. C. D. Nuttall, B.Sc.) read a paper entitled
‘ Symbiosis.’ She emphasised the difference between Symbiosis and
Parasitism, and told that for many years Symbiosis was only known to
exist in Lichens. But Prof. Marshall Ward, a great botanist, ‘ of
whom England may be proud in these days of the ascendancy of German
scientists,’ had described two other examples of Symbiosis: at the roots
of many trees, beeches, willows, poplars, etc., and zm the roots of
leguminous plants.1®

In 1897 Prof. Marshall Ward lectured to the Society on ‘ Symbiosis.’

‘ Mendel’s Discoveries in Heredity ’ was the title of a paper read on
January 8, 1904, by Mr. C. C. Hurst, F.L.S., of Burbage. He added
to the paper a list of sixty books and articles bearing on this subject ;
fifty-one of these had been published in the years 1900-1904. He read
two more papers on ‘ Mendelism,’ and in February 1908, in a lecture on
‘ Mendel’s Law of Heredity and its application to Man,’1? he told that
after, by his own experiments and observations, witnessing Mendelian
phenomena in peas, poppies, sweet-peas, antirrhinums, primulas, tomatoes,
orchids, and other plants, as well as in poultry, rabbits and horses, he had,
with the willing co-operation of the inhabitants of Burbage, compiled
tables showing the working of Mendel’s law in the inheritance or non-
inheritance of eye-colour, hair-colour, and musical sense.

An important paper on ‘ The Cryptogamic Flora of Leicestershire,’ by
Mr. A. R. Horwood, was read in March 1907. It is somewhat amplified
in the Transactions, vol. xiii, pp. 15-87.

Steady work was carried on by the Botanical Section till the outbreak
of the war. During the war the work was hampered, but not suspended.
The report of the Section to the Council in vol. xx of the Transactions,
a volume covering the years 1915 to 1919, stated that meetings had been
held fairly regularly during the winter months throughout the war, but
the attendance had not been good. Owing to train difficulties the summer
excursions had been very few, but there had been some footpath walks
and some visits to gardens. ‘The report of the Flora Committee recorded
with regret the deaths of its members, Dr. Finch, Mr. Pattison and
Mr. Cooper, and also of Lieutenant G. E. Mercer, who was killed in
action. His paper on the Flora of Belgrave and Birstall had been pub-
lished in the last volume of the Transactions. Mr. A. E. Wade, whose
paper on the Flora of Aylestone and Narborough was in the present
volume, had returned from active service with an injured arm; despite
this he was, as he had been before, giving valuable aid in getting the
Herbarium into good order. The work of the Committee had been

16 There were other papers by Mrs. Nuttall, and she gave a lecture on Trees

to the Society in October 1910 (Tvansactions, xv, 26-45).
17 Tyansactions, xii, 35-48.

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 95

much hampered by the absence on active service of Mr. A. R. Horwood,
the general editor of the Flora.

. Two papers by Mr. G. J. V. Bemrose, an officer in the Museum, were
printed in the Transactions of the Society: one on ‘'The Adventitive Flora
of Leicester and District ’ and one on ‘ The Flora of Rutland.’ '*

Mr. Bemrose was appointed Curator of the Museums and the Art
Gallery of Stoke-on-Trent in 1930.

Two notable additions were made to the Herbarium about this time.
Mr. Horwood’s collection of Leicestershire plants was purchased by
Mr. Turner and presented to the County Herbarium. A very unex-
pected donation was received from the National Museum of Wales—
specimens collected by the Rev. W. H. Coleman and Miss Kidger of
Ashby-de-la-Zouch.

Geology and Botany are two scientific subjects which have been most
continuously and successfully treated by sections of the Literary and
Philosophical Society. Other scientific sections have done good work,
but only one has rivalled them in years of working. The work of no
other has had such results as the sequence of treatises on Geology or
the Flora of Leicestershire.

There has nearly always since 1849 been a section for the study of
animal life, but its name has often changed : so has its relation to kindred
studies. Zoology and Botany have been separate sections ; they have
been simply joined as ‘ Zoology and Botany’; joined as ‘ Natural
History’; joined as ‘ Biology (Zoology and Botany)’; and then very
soon a new Section, ‘ Zoology,’ was started which was separate from
‘ Biology (Zoology and Botany).’? The chief object of the new Section
was to study the Fauna of Leicestershire. From 1894 to 1915 there
was a separate section for Entomology.

To give a just appreciation of the work done by the students of the
various branches of Biology is not within the capacity of the compiler
of these pages, and it seems to him that the generally abbreviated records
of their papers on very various subjects hardly give sufficient material
for such an appreciation. But something should be said about the
duplication of the Section for Biology, and the working of the new
Section.

At the first meeting of the new Section its Secretary, Mr. Montagu
Browne, F.Z.S., urged that it should have some definite scheme of work
and suggested that the MSS. notes of the late James Harley, * our
Leicestershire Gilbert White,’ should be arranged and edited for publica-
tion. In the report of the Section 1883-84 it is stated that the published
lists of Potter, Babington and Macaulay, and unpublished lists of Harley,
Davenport, Ellis, Widdowson, Ingram, Walker and others, have been
carefully gone through, and are now being edited by the Secretary. In
the report 1884-85 it is stated that the publication of ‘ The Vertebrate
Animals of Leicestershire,’ by the Secretary, Montagu Browne, F.Z.S., had
begun in the Zoologist. In 1889 Mr. Montagu Browne published The
Vertebrate Animals of Leicestershire and Rutland. In the preface he said

18 Tyansactions, xxviii, 45-72, and xxix, 21-25.

96 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

that he was in possession of the whole of the MSS. of the late James
Harley.?®

While Mr. Harley’s notes were in the hands of Section E,?° Mr. F. T.
Mott put before Section D, the other biological Section which studied
Botany and Zoology, the MS. of Mr. John Plant’s Catalogue of Leicester-
shire Mollusca, with the author’s comments and with hisown. Mr. Plant’s
catalogue gave eighty-two species. It wascompletedin1850. It referred
to two lists, one by the poet, the Rev. George Crabbe, of shells found near
Belvoir,” and one of shells found near Congerstone by the Rev. A. Bloxam.”
Six persons are named as finding certain Mollusca, among them ‘ my
friend, Mr. James Harley.’ Three manuals of Conchology #? and
Pennant’s British Zoology are referred to.

The references to, or rather the indications of, old-time students of
science, in the preceding paragraphs seem to be pertinent to the purpose
of these pages, which is to give an account in an historical sketch of the
study of science in Leicestershire. ‘These men gave their minds to their
studies without having the encouraging suggestion or the assistance
afforded by an already existing Society. Because there were such men
it was possible for a Society such as the Leicester Literary and Philo-
sophical Society to be founded and to be strengthened and increased by
the formation of its ‘ Sections’ for the study of particular branches of
science.

The original scientific Sections for Geology, Botany and Zoology were
founded in 1849. In 1850-51 two were added: one for Meteorology,
and one for Chemistry and General Physics. These were less permanent.
The Section for Meteorology became Meteorology and General Physics
in 1871, but it ended in 1882. Chemistry and General Physics went under
that name or as ‘ Chemistry ’ till 1870. Then it vanished, but reappeared
in 1883 in a new Section for Astronomy, Physics and Chemistry.

The Meteorological Section began its work in 1850, the year in which
the Royal Meteorological Society was founded in London by Mr. Glaisher.
He selected the instruments, which at first were only barometer, thermo-
meter and rain gauge. They were kept at the Museum. In 1873-74
the Rev. A. Mackennal was chairman of this Section. On his advice
the Museum Committee of the Town Council purchased a complete set

19 James Harley was a notable man, much thought of by those who knew him.
He lectured to the Society four times in 1844-1858. His lecture on his friend
and correspondent, the great ornithologist, the late Prof. Macgillivray, was
published in the Society’s volume of selected lectures, 1855. The death of the
well-known naturalist, Mr. James Harley, was spoken of in the Annual Meeting,
1861. “J. Harley’ was an active member of the Society (see lists of officers)
between 1844 and 1853. Ina list of dates of arrival of summer birds in Leicester-
shire Mr. Montagu Browne states that the dates between 1843-55 are from
Harley’s MSS. (Tvansactions, i (1889), Parti, 27).

20 No date is given. The text is in vol. i, Part ii, of the Tvansactions, 1887.

*1 Nichols, vol. i, p. cxci.

22 This is in the Analyst.

*8 In the Shorter Oxford Dictionary the first known use of the word ‘ Conchology ’
is 1776, of ‘ Mollusk’ and ‘ Mollusca’ 1783.

*4 A Section for Chemistry began again in 1924-25, and a Section for Physics
in 1926-27.

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 97

of meteorological instruments. The Museum was made a Government
station. Observations were made and reported and tabulated, the work
being at first shared between members of the Section and the Curator
of the Museum. As time passed the Meteorological Station became a
department of the Museum. In the Museum Report for 1890 the follow-
ing paragraph occurs: ‘The death of the Meteorological Assistant
(Mr. J. C. Smith), in 1888, led the Committee to consider if the expendi-
ture of some £70 per annum in keeping up a station of the second class
—so near to Loughborough, a station of the first class—was warranted
by results. The Committee fully considered the matter in all its bearings,
and unanimously decided to discontinue the observations.’

There is nothing in the printed records of the Society about the meetings
of, or the subjects discussed by, the Section for Chemistry and General
Physics between 1850 and 1870.

In 1883 the Section was reconstituted for Astronomy, Physics and
Chemistry. The Rev. Edward Atkins, B.Sc., was the chairman, and
Mr. W. S. Franks, F.R.A.S., was the Secretary, till the Section again
ceased in 1886-87. Summaries of several of the papers read are in the
Transactions. They are on abstruse questions in the three branches of
science for which the Section had been re-established. ‘There were not
many members, and on some dates for which meetings had been announced
no meetings were held. The report of the chairman to the Council of
the Society in 1887 was a statement of the reasons why the Section resigned
its existence. He said that the absence of any kind of apparatus was an
almost insuperable barrier to the investigation of physical problems.
There would not be enough students to justify the purchase of sufficient
apparatus to meet even the elementary requirements of a Section whose
title embraced the whole range of physical science from Astronomy down
to Chemistry. Experimental researches in even one branch like
Chemistry would need a properly equipped laboratory. The members of
a Section which embraced as its basis so many sciences could not enter
into each other’s work. The report ended with a recommendation that
the Section should be omitted from the list of Sections for the coming
year, for which no officers had been elected.”*

A Section for Entomology was appointed by the Society in January
1894. It ‘ made a vigorous beginning.’ It had a vigorous separate life
for about twenty years. In 1919-20 it was amalgamated with the Section
for Biology. When it was founded there were some keen students of
Entomology who wished for a section of their own. Some practical
work was done by a committee of this Section, which studied and gave
advice about injurious insects in farms, gardens and orchards.

After a paper by Mr. Frank Bouskell on October 28, 1896, on ‘ ‘The
Disappearance of Certain Species of Insects, with notes on their Slaughter
and Protection,’ it was decided to urge upon the Entomological Society

25 The Rev. Edward Atkins was a master in the Wyggeston Boys’ School.
The latter meetings of the Section were held in the new laboratory of the school.
It seems that it was the first laboratory in Leicester. In 1883 the Society had
contributed £100 towards its erection.

98 SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

of London and on local societies the danger of the extermination of
species of rare insects by ‘ over-collecting,’ not so much by collectors
who were ‘ simply foolish ’ as by those who collected for dealers. The
London Society appointed a Protection Committee. The Societies of
Northampton, Birmingham, Glasgow, and Marlborough concurred.
Lists of insects of which the captures should be limited or inhibited were
circulated.

An interesting paper on ‘ The Scientific Aspect of Entomology ’ 2° was
read before this Section in January 1898 by J. W. Tutt, F.E.S., in which
he enlarged on the great change in the science which had come about
since the publication of Darwin’s Origin of Species (1859). ‘ The “‘ how ”
and ‘‘ why ” of the things rather than the things themselves became the
main consideration of the student, and the sleepy, dry-as-dust science,
represented by the herbaria and the cabinets, had breathed into it the
breath of movement, of life, of intellectual possibilities hitherto never
conceived by its votaries.’

Mr. Frederick Bates,?? a brother of ‘ Bates of the Amazon,’ was a member
of this Section. He made a collection of Coleoptera, which after his
death was purchased by the British Museum. In 1907 Mr. Herbert
Ellis, who had been chosen to be President for that year because he was
considered by all to be the best person to represent the Society during
the visit of the British Association, gave a really remarkable presidential
address on social questions, and suggested that there should be a Section
for Economics. The Section was formed. It has not flagged since its
formation.

In the year 1915 a Section for Astronomy was formed. Its first
meeting was on June 23, 1915. Before Armistice Day there had been
twenty-one meetings, including one open-air study of the sky. This
Section was the result of two courses of University Extension lectures.
Its last meeting was on April 8, 1925. During its short life it owed
much to Mr. J. W. Durrad, F.R.A.S.,?8 and to Dr. J. E. M. Finch.

It is hoped that what has been written so far will give the reader an
intelligible sketch of the study of science in Leicestershire, and of its
development in Leicester into the co-operative studies of the ‘ Sections ’
of the Literary and Philosophical Society. The sketch is, of course, not
a complete view : it represents the chief stream of such studies.

In this as in other matters the war was a great break. Post-war is
other than pre-war. It has been indicated above that the Sections for
Botany, Astronomy, and Economics did not cease their activities during
the war. Another piece of work which had begun before the war was
not suspended. In 1913 Mr. C. J. Bond, F.R.C.S., Mr. E. E. Lowe,
the Curator of the Museum, and the Rev. J. Wallace Watts, Chairman,
Vice-Chairman, and Hon. Secretary of the Section for Biology, with
the approval and the help of the Museum-and Art Gallery Committee,
gave lectures with practical work on Zoology. These classes were con-

26 The paper is in vol. iv, pp. 527-539, of the Transactions.

27 A paper on the Coleoptera of Bradgate Park by him, with a list of 507 species,
is in the same volume, pp. 170-176. .

#8 Mr. Durrad designed the table of the sun-dial in Museum Square.

MEN OF SCIENCE IN LEICESTER AND LEICESTERSHIRE 99

tinued, though not without difficulty and not throughout by the same
lecturers, all through the war time.”

The Report of the Council of the Society for the session 1922-23
contained this sentence : ‘ It may now be said that the depression and
difficulties due to the war have passed.’

With regard to the work of the Sections for Geology, Botany, Biology,
Economics, and of two new *° Sections, one for Chemistry and one for
Physics, it may after ten years be said that that sentence was not too
optimistic.

No attempt is here made to give particular accounts of the post-war
work of these Sections, but something may be said of changes in or
affecting them all.

The different Sections seem to help one another more than in former
years, not only by such a permanent partnership as that between the
Sections for Zoology and Botany, but by arranging joint meetings to
discuss overlapping subjects. Meetings also are arranged with technical
or academical bodies, and visits are paid to places where work is carried
on under the guidance of applied science.

The Museum was the child of the Literary and Philosophical Society.
After a period in which it may be said to have been first a nursling and then
a pupil of the Society, it acquired independence not only from parental
authority but from all parental interference. In the many years since
this emancipation was completed there has been harmony between parent
and child. The Museum as an institution and its curators and other
officers—not a few of them have held office in the Society and its Sections—
have been leaders in scientific studies in Leicester. Till late in the
nineteenth century this could be said of no other institution. In modern
days the growth and development of the University College, of the
Colleges of Art and Technology, and of the Scientific Departments of
Secondary Schools, have made a great change. There are in Leicester
a number of men and women who are in virtue of their profession students
and teachers of science. There has also been an increase of the number
of experts in applied science who are employed in the service of the city,
or are engaged in industry. The conditions of local scientific study have
changed, and its possibilities are greater than ever. It may reasonably
be hoped that there will always be a number of people who, though not
professionally engaged in science, will find in some of its provinces an
attractive but serious parergon for their leisure time, and that those who
are professionally learned in one province may be amateurs in others.
So it is reasonable to hope that such little societies as the Sections of the
‘ Lit. and Phil.’ may in the future surpass the good work of their bygone
years.

Such a hope was expressed long ago in the Report of the Council to
the Annual Meeting in June 1877: ‘ There is no reason why the Sections
should not become small Societies in themselves, of recognised position,

29 Three out of four first-year medical students who were attending these classes

were killed in the war. ,
30 The Section for Chemistry began work in 1924-25, that for Physics in 1925—
1926.

too SCIENTIFIC SURVEY OF LEICESTER AND DISTRICT

able to hold their own by the side of other large Societies in the kingdom ;
why in fact there should not be a Geological, a Natural History, or other
Society, affiliated to the old Parent Society, but each working in its own
sphere.’

In his Presidential Address in 1912 Dr. Astley V. Clarke spoke of the
Sections as the raison d’étre of the Society.

Times have changed since 1877, and since 1912. It is still much to
be wished that such small societies may continue to work each in its own
sphere, but each ready to work together with others, so that there may be,
in effect, a Leicester Association for the Study of Science.

The writer is aware that the foregoing is an incomplete account of the
study of science in Leicester. It gives no account of institutions which
have among their work in other subjects given instruction in science—such
as the Mechanics’ Institutes from 1834 to about 1860, Working Men’s
College (now Vaughan College), Adult Schools, University Extension
Lectures, and other bodies—but it is hoped that it gives a correct account
of the most permanent and important streams of science study other than
that in modern colleges and modernised schools.

Printed in England at THE BALLANTYNE PRESS
SPOTTISWOODE, BALLANTYNE & Co. LTD.
Colchester, London & Eton

INDEX

References to addresses, reports, and papers printed in extended form are given

in italics.

* Indicates that the title only of a communication is given.
When a page reference to a paper is given in italics, it is to a note of its
publication elsewhere, or to a note of other publications by the author

on the same subject.

References preceded by the abbreviation Appdx. will be found in the appendix

_ immediately preceding this index.

Abelian integrals, by W. V. D.
Hodge, 456, 6117.

Account, General Treasurer’s, 1932-3,
XXiv.

Accountancy, réle in scientific man-
agement, discussion by A. Salt,
F. R. M. de Paula, Prof. W.
Annan, 507, 6r4.

Acquired characters, inheritance, by
A. F. Dufton, 522.

Activated sludge or bio-aeration, by
J. Haworth, 514, 674.

Apams, J., Fauna and flora of rivers,

Adaptability, limitations in animal
kingdom, by Dr. G. C. Robson,
487.

ADENEY, Prof. W. E., Natural puri-
fication of sewage, 513, 614.

Administration and business, train-
ing for, discussion by Prin. H.
Stewart, T. Kingdom, E. I. Lewis,
F, W. Lawe, G. C. Wickins, Prin.
J. C. Smail, 562, 617, 678.

ApRIAN, Prof. E. D., Activity of
nerve cells, 163, 533*.

Adult education; cultural value of
science in, symposium by Sir R.
Gregory, Prof. W. J. Pugh, Prof.
W. B. Brierley, Dr. A. Ferguson,
Prof. J. L. Myres, Dr. V. Cornish,
Sir J. Stamp, 568, 617, 678.

Adult education, science teaching in,
report, 330, 564*.

discussion by Prof. J. L. Myres,

Dr. C. H. Desch, A. S_ Firth,

Miss H. Masters, R. J. Howrie,

Prof. R. Peers, G. C. Hickson,

564*, 618.

Aeronautical research, by H. E.
Wimperis, 511.

Aerosols, particles in, by H. L.
Green, 463.

Africa, kinship and family in West,
by Dr. M. Fortes, 521.

Africa, report on human geography of
tropical, 2'74.

African Colonial Governments,
present tendencies, by Dr. R. S.
Rattray, 524, 615.

African peoples, growth of economic
individualism among, by Dr. L.
Mair, 521.

Agriculture, downland of E. Sussex,
by H. C. K. Henderson, sor.

Agriculture, education for, by J. R.
Bond, 566*.

Agriculture, efficiency in, and social
results, by Prof. A. W. Ashby,
572, 618.

Agriculture, objective, by R. R.
Enfield, 571.

Agriculture, sociological aspects, dis-
cussion by R. R. Enfield, Prof. A.
W. Ashby, 571, 678.

Agriculture and chemistry, by Dr. A.
Lauder, 243, 571*.

Air layers, instability, by A. Graham,
460.

Aircraft noise, reduction, by R. S.
Capon, 511, 674.

Aire, gauging at Esholt, by T. Roles,
407.

AKEROYD, G. I., Organisation of
economic distribution, 509.

ALLEN, R. W., Experiences in
mechanical engineering, 129,
510*.

102

ALLIBONE, Dr. T. E., High voltage
vacuum tubes, 452.

ANNAN, Prof. W., Accountancy in
average business, 507, OI 4.

Annual meetings, table, xii.

AntTcLIFF, F. R., Industries of
Leicester, Appdx. 60.

Apis Rock, excavations, by Dr. L. S.
B. Leakey, 528*.

Arid’ regions, variations in native
economy, by Prof. C. D. Forde,
498, 673.

ARMITAGE, F. P., Education in
Leicester, Appdx. 80.

ARMSTRONG, A. L., Excavations at
Creswell Crags, 523*.

ARMSTRONG, Dr. E. F., Organisation
as a technical problem, 506*,
614.

ARNOLD, R. N., Embrittling of steels,
516, 614.

Aromatic hydrocarbons, interatomic
distances, by Dr. J. M. Robertson,
468, 612.

Ascophanus aurora (Crouan) Boud.,
by Prof. Dame H. Gwynne-
Vaughan and Mrs. H.S. William-
son, 553, 617.

AsuBy, Prof. A. W., Efficiency in
agriculture and social results, 572,
6r8.

AsHByY, Dr. E., Genetics, 492*.

Assam, Megalithic work in, by Dr.
J. H. Hutton, 525*, 675.

Astpury, W. T., Structure of proto-
plasm, 490*.

X-ray interpretation of pro-
perties of hair, feathers, etc., 428,
6I0.

AstTILL, Ald. P. F., Grazing in Mid-
lands, 574, 618,

Atomic transmutation, discussion by
Rt. Hon. Lord Rutherford, Dr.
J. D. Cockcroft and Dr. E. T. S.
Walton, Dr. M. L. Oliphant,
P. I. Dee, 431, 610, 671.

AtTTeErR, H. F., Legal aspect of river
pollution, 513, 674.

Auroral spectrum and upper at-
mosphere, hy Prof. L. Vegard,
427, OIT

Auxin a and b, by Prof. Kégl, 466*,
600.

Auxin in plants, by Prof. F. A. F.C.
Went, 555, 617.

INDEX

AVELING, Prof. F., Status of psy-
chology as empirical science, 171,
542*.

Azande, bride-wealth among, by

Prof. E. E. Evans-Pritchard,
529*, 615.
BappacE, Dr. D. W., Cremona

transformations, 457.

BAILy, Prof. F. G., Amateur meteor-
ologist, 599*.

Batcuin, N. M., Psychological
approach to market research, 548,

r6.

BALL, Prof. N. G., Effect of nocturnal
illumination on opening of flower-
buds, 551, 626.

Barnes, Dr. B., British aquatic
fungi, 553, 626.

Barnes, Mrs. N. M., Function. of
psychologist in administrative
scheme, 549.

BaRRACLOUGH, F., Reliability of en-
trance examinations, 567, 617.
BarRTLETT, Prof. F. C., on Training

in psychology, 308.

BaRTLETT, R. J., ‘ Constant’ errors
in sensory comparisons, 544.

Disorientation and vertigo, 539.

Be-type spectra, periodic changes,
by Dr. W.J.S. Lockyer, 459, 6717.

BEADLE, L. C., Osmotic regulation
in Gunda‘ulve, 490*, 672.

BEDFORD, Dr.T., Nose-opening rays,
533, 615.

BEETLESTONE, A., Production of high
voltages, 452, 611.

Bennettitales, reproductive organs
of early, by Dr. T. M. Harris,
550*.

Berberis Darwinii, Berberine in
metabolism of, by Dr. B. T.
Cromwell, 551, 617.

BERGMANN, Prof. M., Chemistry of
skin and catechol tannins, 471,
6IT.

BERNAL, Dr. J. D.,
distances, 469*.

Best, A. C., Temperature gradients
near ground, 462, 611.

BippER, Miss A. M., Alimentary
canal of Cephalopoda, 488.

Bipp_er, Dr. G. P., Energy of flagel-
late cells, 486.

Interatomic

INDEX

BitHaM, E. G., British Rainfall
Organization, 373.

Climate

Appdx. 40.

J. Haworth, 514*, 614.

BuackaBy, J. H., Drainage ma-
chinery, 573, 618.

BLACKBURN, Dr. K. B., Synthesis of
species, 492.

BuackETT, P.M.S., Positive electron,
433-

Biackwoop, Dr. J., Nutritional
aspect of milk supplies, 577*, 618.

Brake, A. B., Trade associations and
combinations, 507.

Biocu, O., Infra-red photography,
429, 610.
Blood, carbon dioxide transport in,
by Dr. F, J. W. Roughton, 533.
Blood distribution during mental
work, by M. F. Lowe, 544.

Blood groups as index to racial
characteristics, by Prof. R. R.
Gates, 522, 615.

Bonp, Col. C. J., Hormones and
genetics, 492, 612.

Leucocytic and _ erythrocytic
activity, 533.

Bonp, J. R., Education for agri-
culture, 566*.

Boot and shoe industry, education
for, by H. Salt, 564, 678.

Boreholes, water-levels, by
Dixon, 418.

Borer, O., Great Ouse Catchment
Board, 400.

Borings, pumping tests at new, by
R. C. S. Walters, 410.

Botany in adult education, by Prof.
W. B. Brierley, 569, 617.

Botany in courses of biology, report
on, 557*.

Bouton, Prof. W. S., Red sedi-
mentary rocks, 482.

St. George’s Land, 477.

Bowen, E..G., Hill forts and valley-
ward movements of population in
Wales, 525.

Bowen, E. J., Forces between atoms
in molecules, 469.

BrapD.ey, H., Water absorption by
leather, etc., 451.

Testing of flexible

materials, 451, 6II.

Ha J.

sheet

of Leicestershire, |
| Bripces, A., Economic aspects of
Bio-aeration or activated sludge, by

103

Bride-wealth among Azande, by
Prof. E. E. Evans-Pritchard, 529*,
6I5.

grassland, 575, 618.

BRIERLEY, Prof. W. B., Zoology and
botany in adult education, 569,
617.

Britain, colonisation, by Dr. C.
Fox, 526, 615.

British Isles, system of forestry for,
by Maj. Hon. R. Coke, 558, 6177.

British Rainfall Organization, by
E. G. Bilham, 373.

British Somaliland, report on, 298.

BrRocKINGTON, W. A., Education for
industry, 566*.

Bronze Age implements, report on,
300.

Brown, T. B., Transition from Neo-
lithic to Bronze Age of W. Asia,
527":

Brown, Dr. W., Personal influence,
542, 616.

Validity of methods of corre-
lation, 545, 616.

Bryan, Dr. P. W., Education for in-
dustries of East Midlands, 564*.

—— Land utilisation in Leicester,
495*.

—— Leicester,
Appdx. 3.
BucuHaNnaNn, Sir G., Economic posi-

tion of Burma, 503.

Butt, Dr. H. O., Conditioned
responses in fishes, 491*.

Burcu, C. R., Oil condensation
pumps, 451, 671.

Burkitt, M. C., on Derbyshire caves,
299.

Burma, economic position, by Sir
G. Buchanan, 503.

Burn, Prof. J. H., Chemical control
of circulation, 534, 615.

Business administrator and entre-
preneur, types and supply price,
by Prof. P. S. Florence, 505, 673.

Business and administration, train-
ing for, discussion by Prin. H.
Stewart, T. Kingdom, E. I.
Lewis, F. W. Lawe, G.' C.
Wickins, Prin. J. C. Smail, 562,
617, 618.

Business recovery, by E. L. Har-
greaves, 505.

regional __ setting,

104

BUTENANDT, Dr. A., Relations of
sex hormones to sterols and bile
acids, 467, 612.

Calamoichthys, anatomy, by G. L.
Purser, 488*.

Campanuloidez, floral morphology
of, by F. F. Hyde, 554, 617.

CAMPBELL, Dr. H., Man’s evolution
from primitive primate, 522.

Canada, gold production, by H. C.
Cooke and W. A. Johnston, 485.

Canal projects, by W. Maughan,
516*, 614.

Canals, by 'T. S. Hawkins, 409.

Capon, R. S., Reduction of aircraft
noise, 511, 614.

Carbon dioxide transport in blood,
by Dr. F. J. W. Roughton, 533.

Carboniferous’ shore-line in S
Wales, by Dr. T. N. George, 478.

CaRDINALL, A. W., Superstitious
beliefs in Gold Coast, 523, 615.

Carotenoids and flavines, by Prof.
R. Kuhn, 464.

Catchment Boards, by Capt. J. C. A.
Roseveare, 397-

Catechol tannins and chemistry of
skin, by Prof. M. Bergmann, 471,
Orr.

CaTTELL, Dr. R. B., Friends and
enemies, g, p, c and w values, 540,
616.

Celtic weather prophecy, by K. H.
Jackson, 517, 615.

Celts, origin, by Prof. J. Pokorny,
517, 615.

Cephalopoda, alimentary canal, by
Miss A. M. Bidder, 488.

CHAMBERLAIN, J., Education for
hosiery industry, 565, 617.

Industries of Leicester, Appdx.

60.

Mechanisation of knitting, 510,
614.

CuHaTTaway, Miss M. M., Develop-
ment of rays of Sterculiacez, 552,

617.

Chemical aspects of life, by Sir F. G.
Hopkins, 1.

Chemistry and agriculture, by Dr. A.
Lauder, 243, 571*.

Chemistry in adult education, by
Dr. A. Ferguson, 569*, 617.

INDEX

Child, development of language in,
by Prof. C. W. Valentine, 537,
616.

CuILDE, Prof. V. G., Painted pot-
teries from India and East Iran,
527, 615.

CuurcH, Maj. A. G., Television,
451*, 620.

Circulation, chemical control, dis-
cussion by Sir H. H. Dale, Prof.
J. H. Burn, Dr. A. N. Drury,
Dr. J. H. Gaddum, Dr. W. Feld-
berg, Prof. R. J. S. McDowall,
534, 615.

CLaRKE, Dr. L. J., on General science
in schools, 312, 566*.

Classification of communities by
occupations, by Dr. E. H. Sel-
wood, 499.

Cloud evolution, by Prof. F. Linke,
460*.

CriouceH, Lt.-Col. A. B., Preparation
of maps and illustrations, 497,
613.

Coal, microspores, by Dr. A. Rais-
trick, 480.

Coal, plant structures in, by Prof. G.
Hickling and C. E. Marshall, 481.

Coalfields of Midland province, by
Prof. W. G. Fearnsides, 57, 476*.

CoBBoLp, Dr. E. S., Comley Quarry,

473-

CocxcrorFtT, Dr. J. D., High voltage
D.C. generator, 452, 6IT.

—— Transmutation of elements,
432, 610.

Coxe, Maj. Hon. R., System of
forestry for British Isles, 558, 617.

Colorado River, native warfare, by
Prof. C. D. Forde, 519, 675.

Colour-vision, criticism of Roaf’s
theory, by Dr. F. W. Edridge-
Green, 530, 616.

Colouring matters, natural, by Prof.
R. Robinson, 45, 464*.

Colouring matters, natural, discus-
sion by Prof. R. Kuhn, Dr. R. P.
Linstead, Dr. N. V. Sidgwick,
464; 612.

Colours, advancing and retiring, by
Prof. H. Hartridge, 537.

Comley Quarry, by Dr.
Cobbold, 473.

Compton, water level at, by D. H.
Thomson, 417.

E.nnS.

INDEX

Condensation of water in atmo-
sphere, discussion by Dr. G. C.

Simpson, H. L. Green, Prof. J.J. |

Nolan and J. P. Ryan, L. H. G. |

Dines, 463.

Condensations of matter in expand- |

Ci OF

ing universe, by Dr.
McVittie, 443, 6r0.

Congresbury, land tenure at, by

Prof. W. W. Jervis and S. J. Jones, |

526.
Conjugate points, large: loci, by
J. H. C. Whitehead, 458.

Cooke, H. C., Gold production of |

Canada, 485.

Copyright and patent law, by Prof.
A. Plant, 504, 673.

CORNEWALL-WALKER, A. E., Rain-
fall, rest levels and pumping levels,
420.

CornisH, Dr. V., Science in adult
education, 569*, 617.

Visualisation of landscape, 495.

Correlation, value of methods, dis-
cussion by Prof. C. Spearman,
Dr. W. Brown, Dr. S. Dawson,
Dr. J. Wishart, Dr. S. S. Wilks,
Dr. J. O. Irwin, Prof. H. T. H.
Piaggio, 459*, 545, 616.

Corresponding Societies, conference of
delegates, 589.

Cosmic ray measurements, by Prof.
E. Regener, 430*, 610.

Council, report 1932-3, xix.

Council and Officers, v.

Cramp, Prof. W., Axial spin of
magnetic field, 453, OIT.

CrEED, Dr. R. S., Disorientation and
vertigo, 540%, 616.

Cremona transformations, by Dr.
D. W. Babbage, 457.

Creswell Crags, excavations at, by
A. L. Armstrong, 523*.

Cretaceous and Tertiary rocks, report
on, 271.

Crew, Prof. F. A. E., Genetics, 492*.

McDougall’s Lamarckian ex-
periment, 542*.

CROMWELL, Dr. B. T., Berberine in
metabolism of Berberis Darwinii,
551, 617.

CRrowDEN, G. P., Value of physiology
to industry, 508, 614.

CuNNINGHAM, Dr. B., Foreign water
organisations, 371.

105

CUNNINGHAM, J. T., Genetics, 492*.

Life and _ reproduction of
Lepidosiren, 488, 612.

Cyclone formation, influence of
stratosphere, by Prof. F. Linke,

430.

| D.C. generator, high voltage, by

Dr. J. D. Cockcroft, 452, 6717.

Dairy industry and milk supplies,
by B. Davies, 577*, 678.

Date, Miss A. B., Tests and exam-
inations of University women
students, 568, 617.

Date, Sir H. H., Chemical control
of circulation, 534.

Da.uimore, W., Trees and country-
side, 558.

DANNREUTHER, Capt. T., Amateur
meteorologist, 599*.

Darsy, Dr. H. C., Geographical
conceptions of medieval bishop,
500.

Davies, B., Dairy industry and milk
supplies, 577*, 628.

Davies, L. J., Hot cathode gas dis-
charge tubes, 451.

Daviges, O., Sotiel Coronada, 527,

6I5.
Davies, W., Biotic factor of grazing,
575, 6r8.

Dawson, Dr. S., Validity of methods
of correlation, 545*, 616.

Deacon, G. E. R., Hydrology of
southern oceans, 489, 673.

DEBENHAM, Prof. F., Polar year,
499*.

Deeg, P. I., Transmutation of ele-
ments, 432, 610.

Delegates, Conference of, 589.

Department store, University men
in, by F. W. Lawe, 563, 617.

DE PauLa, F. R. M., Finance and
accountancy in large business
combines, 507, 614.

Derbyshire caves, report on, 299.

| DescH, Dr. C. H., on Sumerian

copper, 302.

Science teaching in adult edu-
cation, 564*.

DE SITTER, Prof. W., Expanding

_ universe, 449*.

Development boards, by Prof. H. M.
Hallsworth, 505*.

106

Diatomic rotator, by Dr. L. Simons
and E. H. Smart, 431*, 670, 6z17.

Dickinson, R. E., Metropolitan
regions of U.S.A., 502, 613. _—.

Dickson, Sq.-Ldr. E. D., Dis-
orientation and vertigo, 539*.

Dinss, L. H. G., Supersaturation of
water in free atmosphere, 464.

Disintegration of elements, by Dr.
M. L. Oliphant, 432, 6r0.

Disorientation and vertigo, discus-
sion by Dr. J. T. MacCurdy,
FL.-Lt. J. A. G. Haslam, Dr. T. G.
Maitland, Sq.-Ldr. E. D. Dick-
son, R. J. Bartlett, Dr. R. S.
Creed, Sq.-Ldr. G. H. Reid,
530%, 538, 616.

Dissection of large numbers, by
Dr. E. H. Linfoot, 454.

Distribution, organisation of eco-
nomic, discussion by Mrs. E. M.
Wood, L. Neal, G. I. Akeroyd,
509, 6©4.

Dixon, E. E. L., St. George’s Land,

477.

Dixon, F. J., Water levels in wells,
etc., 418.

Dixon, Prof. S. M., Gauging River
Severn, 424.

Dosson, A. T. A., Law of land
drainage, 572, 618.

Dopps, Prof. E. C., Synthetic
cestrogenic compounds, 468, 612.

Dotiar, A. T. J., Dike-swarm of
Lundy, 481, 612.

—— Lundy communities, 518, 675.

Dominion universities, report on
geography in, 275.

Douctas, Vice-Adml. Sir H. P., on
Inland Water Survey, 358.

Doy .g, Prof. J., Heterospory, 550*.

Drainage, land, by Capt. J. C. A.
Roseveare, 398.

Drainage, land, discussion by A. T.
A. Dobson, W. Haile, H. H.
Nicholson, Dr. H. Janert, J. H.
Blackaby, 572, 618.

Drever, Prof. J., Comparative reli-
ability of examinations and tests,
567, 617.

Drury, Dr. A. N., Chemical control
of circulation, 535.

Durton, A. F., Inheritance of
acquired characters, 522.

Nose-opening rays, 533, 616.

INDEX

Du-PLat-Taytor, M., Sea defence
and land reclamation, 516, 674.
pu VaL, Dr. P., Multiple planes,

457, OIT.
Dymonp, T.5S., Fauna and flora of
rivers, 599*.

Earth Mother cult in N.E. York-
shire, by Mrs. H. W. Elgee, 518.
Earth pressures, report on, 297, 517*.

Earthquakes, high focus, by E.
Tillotson, 460.
East African culture, Indonesian

contact, by J. Hornell, 521, 675.

Eastwoop, T., St. George’s Land,
479, 612.

Economic progress and science, by
Sir J. Stamp, 578.

EDDINGTON, Sir A. S., Expanding
universe, 434, 610.

EDRIDGE-GREEN, Dr. F. W., Criti-
cism of Roaf’s theory of colour
vision, 530, 616.

Education, development of national
system, by J. L. Holland, 210,
569*.

Education for industries of East
Midlands, discussion by Dr. P.
W. Bryan, H. Salt, J. Chamber-
lain, Dr. H. Schofield, J. R. Bond,
W. A. Brockington, 564, 617,
6r8,

Epwarps, K. C., Luxemburg iron
industry, 501, 673.

Einstein’s gravitational equations,
non-static solutions, by Dr. G. C.
McVittie, 459, 677.

Electrical switch equipment, testing,
by W. Wilson, 512, 615.

Electrical terms and definitions, report
on, 296, 517*.

Electricity stations, by H. Nimmo,
404.

Electrostatic generation of high
voltage for nuclear research, by
Dr. R. J. van de Graaff, 427*.

Electrostatics, engineering possi-
bilities, by Dr. R. J. van de Graaff,
453.

EuceEe, Mrs. H. W., Earth Mother
cult in N.E. Yorkshire, 518.

Empire, mapping, by Col. M. N.
Macleod, 496. 7

Empire soil resources, report on, 296.

INDEX

Employment by Civil Service, com-
panies and ‘ family ’ firms, psycho-
logical effect, by Mrs. W. Raphael,
548.

ENFIELD, R. R., Objective in agri-
culture, 571.

Entrepreneur and business adminis-
trator, types and supply price, by
Prof. P. S. Florence, 505, 613.

Erythrocytic and leucocytic activity,
by Col. C. J. Bond, 533.

Eskimos of Labrador, by Prof. V.
Suk, 520.

Ether-drift experiment, by Prof.
D.C. Miller, 451*, 6z0.

Evolution, genetics in, by Dr. C. C.
Hurst, 491*, 673.

Evolution, man’s, from primitive
primate, by Dr. H. Campbell, 522.

EvANS-PRITCHARD, Prof. E. E.,
Bride-wealth among Azande,
529*, 615.

Examinations and_ psychological
tests, predictive value, discussion
by Prof. C. W. Valentine, Dr.
D. W. Oates, F. Barraclough, F.
Sandon, Prof. J. Drever, Miss
A. B. Dale, E. Farmer, 545*, 566,
617, 618,

Expanding universe, discussion by
Sir A. S. Eddington, Prof. E. A.
Milne, Dr. G. C. McVittie, Dr.
W. H. McCrea, Abbé Lemaitre,
Prof. W. de Sitter, 434, 610.

Factor and noegenetic theories, by
F. C. Thomas, 541.

Factory equipment, psycho-physio-
logical requirements, discussion
by Sir H. Fowler, G. P. Crowden,
Dr. G. H. Miles, 508, 6r4.

FAIRGRIEVE, J., Amateur meteor-
ologist, 599.

Fairies, distribution of belief in, by
R. U. Sayce, 526*.

Farmer, E., Examinations and psy-
chological tests, 568*, 617.

Fawcett, Prof. C. B., on Geography
in Dominion universities, 275.

FEARNSIDES, Prof. W. G., Correla-
tion of structures in coalfields of
Midland province, 57, 4.76*.

FELDBERG, Dr. W., Chemical control
of circulation, 535*, 616.

107

FELL, Dr. H. B., Ossification, 531.

FENELON, Dr. K. G., Technological
and economic progress, 504*.

FERGUSON, Dr. A., Chemistry and
physics in adult education, 569*,
617.

on Quantitative estimates of
sensory events, 271.

Fibre chemistry and X-ray analysis,
by Dr. J. B. Speakman, 428, 6z1.

Fibre structure in teeth, by J.
Thewlis, 429, 6rI.

Fibres, X-ray analysis, discussion
by W. T. Astbury, Dr. R. D.
Preston, Dr. J. B. Speakman, J.
Thewlis, 428, 550*, 6r0, 6rr.

Field names, by Dr. A. H. Smith,
570*.

Fiji, decaying arts and crafts, by
G. K. Roth, 528, 675.

Film in engineering, discussion by
H. E. Wimperis, Sir H. Fowler,
W. Wilson, A. Rodger, 511, 675.

Finance and accountancy in large
business combines, by F. R. M.
de Paula, 507, 614.

FirtH, A. S., Science teaching in
adult education, 564*.

FisHerR, Prof. R. A., Genetical
system for ever-sporting stocks,
550, 617.

Fisheries, prediction of North Sea
cod, by M. Graham, 492, 673.
Fishes, change in form with in-
creasing age, by E. Ford, 493.
Fishes, conditioned responses in, by

Dr. H. O. Bull, 491*.

Flagellate cells, energy, by Dr. G. P.
Bidder, 486.

Flavines and carotenoids, by Prof.
R. Kuhn, 464.

Flickering fields, binocular vision,
by Miss M. D. Vernon, 548, 6126.

Flora, problems of British, by Prof.
J. R. Matthews, 557*, 617.

FLORENCE, Prof. P. S., Types and
supply price of entrepreneur and
business administrator, 505, 613.

Flower-buds, effect of nocturnal
illumination on opening of, by
Prof. N. G. Ball, 551, 676.

Forces between atoms in molecules,
by E. J. Bowen, 469.

Forp, E., Change in form with in-
creasing age in fishes, 493.

108

ForbeE, Prof. C. D., Native warfare
on Lower Colorado River, 519,
615.

Variations of native economy
in arid regions, 498, 613.

Forest, good, and thinnings, by H.
Mundt, 559, 677.

Forestry, public opinion on, by
W. A. Robertson, 561, 617.

Forestry, system for British Isles, by
Maj. Hon. R. Coke, 558, 677.

Forestry and sport, by Hon. N. A.
Orde-Powlett, 559, 617.

Fortes, Dr. M., Kinship and family
in West Africa, 521.

Fourier and Hankel transforms, by
Dr. A. C. Offord, 455, 6r7.

Fow.er, Sir H., Overseas motor
unit, 512.

Psycho-physiological require-

ments of modern factory equip-

ment, 508*.

on Stresses in
materials, 296.

Fox, Dr. C., Colonisation of Britain,
526, 615.

FRANKLIN, C. H. H., Orbits of
spherically free pendulum, 450,
6I0.

FREUDENBERG, Prof. K., Tannins
and proteins, 470, 612.

Friends and enemies, g, p, c and w
values, by Dr. R. B. Cattell, 540,
616.

Fungi, British aquatic, by Dr. B.
Barnes, 553, 616.

overstrained

Gappum, Dr. J. H., Chemical con-
trol of circulation, 535.

Gace, F. H., Brightness in visual
sensations, 541.

Galt, Sir E. A., Races and languages
of India, 499, 673.

Gambia Valley, stone circles, by
Sir R. Palmer, 524, 615.

Garn_Rr, J. H., West Riding of York-
shire Rivers Board, 401.

Garrop, Miss D. A. E., Excavation
of Mugharet el-Tabun, 527*.

Gaters, Prof. R. R., Blood groups
as index of racial characteristics,
522, 615.

General nature of gene con-

cept, 491*, 673.

INDEX

Gelatin-tannin reaction, by F. C.
Thompson, 472, 612.

Gene concept, by Prof. R. R. Gates,
491*, 613.

General science in schools, report on,
312, 566*.

General science in schools, dis-
cussion by Dr. L. J. Clarke, Dr.
E. L. Hirst, G. W. Olive, Sir F. G.
Hopkins, Dr. W. W. Vaughan,
566*.

General Treasurer’s Account, 1932-3,
XXIV.

Genetical system for ever-sporting
stocks, by Prof. R. A. Fisher, 550,
617.

Genetics, discussion by Prof. J. S.
Huxley, Prof. R. R. Gates, Dr.
C. C. Hurst, Dr. K. B. Blackburn,
Dr. I. Manton, Col. C. J. Bond,
Prof. F. A. E. Crew, Dr. E. Ashby,
J. T. Cunningham, Mrs. C. B.S.
Hodson, 491, 555*, 612, 613.

Genetics of intellect, by Dr. C. C.
Hurst, 543, 676.

Geographical conceptions of medi-
eval bishop, by Dr. H. C. Darby,
500.

Geography, economic, of early
Stuart England, by Prof. E. G. R.
Taylor, 501.

Geography as mental equipment, by
Rt. Hon. Lord Meston, 93, 499*.

Geography in adult education, by
Prof. W. J. Pugh, 568*, 678.

Geography in Dominion universities,
report on, 275.

Geology in adult education, by Prof.
W. J. Pugh, 568*, 678.

GeorcE, Dr. T. N., Carboniferous
shore-line in S. Wales, 478.

GILBERT, E. W., Human geography
of Mallorca, 497, 623.

Gimson, M., Water supply of
Leicestershire, 494, 673.

GLASSPOOLE, J., Bibliography of in-
land water, 367.

GoppEN, W., Nutritional aspect of
milk supplies, 5'77*, 628.

Gold Coast, superstitious beliefs in,
by A. W. Cardinall, 523, 675.
Gold standard, by Prof. J. H. Jones,

109, 503*.

GoLpTHoRPE, Miss R. M., Distri-

bution of practice periods, 540*.

INDEX

Goob ET, B. L., Production of high
voltages, 452, OIT.

Gorpbon, Prof. W.'T’., on Cretaceous
and Tertiary rocks, 271.

Red sedimentary rocks, 482.

GouLDBOURN, J., Shoe manufactur-
ing machinery, 515, 614.

GraHaM, A., Instability of air layers;
460.

GraHAM, M., Prediction of North
Sea cod fisheries, 492, 613.

Gray, Dr. J., Mechanical view of
life, 81, 486*.

Grazing problems, discussion by
Ald. P. F. Astill, M. G. Jones, W.
Davies, A. Bridges, 574, 618.

Great Ouse Catchment Board, by
O. Borer, 400.

Greaves, W. M. H., Stellar colour
temperatures, 459*.

GREEN, F. H. W., Rainfall in Kenya
and Uganda, 497.

GreEN, H. G., Pascal’s Theorem in
n dimensions, 458, 617.

Green, H. L., Particles in aerosols,

463.

Grecory, H. H., Geology of Lei-
cester district, 476*.

Geology of Leicester, Appdx. 17.

Grecory, Sir R., Science in adult
education, 568, 617.

GriFFiTHs, G. J., Gauging River
Thames, 425.

—— Thames Conservancy, 398.

Gunda ulve, osmotic regulation in,
by L. C. Beadle, 490*, 612.

GwyNneE-VaucGuaNn, Prof. Dame H.,
Development of Ascophanus
aurora (Crouan) Boud., 553, 617.

Hackxinc, T., Leicestershire farming,
Appdx. 48.

Happon, Dr. A. C., on British
Somaliland, 298.

Haire, W. H., Law of land drain-
age, 572*.

Trent Catchment Board, 399.

Hatcrow, W. T., Hydro-electric
companies, 403.

Hattsworty, Prof. H. M., Work of
development boards, 505*.

Hankel and Fourier transforms, by
Dr. A. C. Offord, 455, 671.

109

Harcreaves, E. L., Problem of
business recovery, 505.

Harris, J. E., Structure of proto-
plasm, 490*.

Harris, Dr. L. J., Vitamin action
and bone formation, 532, 616.
Harris, Dr. T. M., Reproductive

organs of early Bennettitales,
50%.
Harrop, R. F., Technological and
economic progress, 504*.
HartrRIDGE, Prof. H., Advancing and
retiring colours, 537.
—— Competition reaction time, 536.

| —— Resonance theory of hearing,

536.

—— Skin resistance, 536.

HasiaM, FI.-Lt. J. A. G., Dis-
orientation and vertigo, 539.

Has.Lewoon, G. A. D., CEstrin, 466,
612,

Hawkins, T. S., Canals, 409.

Haworth, J., Bio-aeration or acti-
vated sludge, 514*, 614.

Hearing, resonance theory, by Prof.
H. Hartridge, 536.

Henperson, H. C. K., Downland
agriculture of E. Sussex, 501.

HENDERSON, Sir J. B., on Electrical
terms and definitions, 296.

HeERON-ALLEN, E., Diffusion and
extension phenomena in living
protoplasm, 486*, 673.

Heterospory, by Prof. J. Doyle,
550°.

HETHERINGTON, E. F., Gauging
River Severn at Ironbridge, 406.
HIcKk.inG, Prof. G., Plant structure

in coal, 481.

Red sedimentary rocks, 482.

Hickson, G. C., Science teaching in
adult education, 564*.

High voltages and high vacua, dis-
cussion by C. R. Burch, B. L.
Goodlet and A. Beetlestone, Dr.
T. E. Allibone, Dr. J. D. Cock-
croft, Dr. R. J. van de Graaff, 451,
oI.

Hitz, Sir A., on Transplant experi-
ments, 310.

Hill forts and valleyward movements
of population in Wales, by E. G.
Bowen, 525.

HrnsHELwoop, C. N., Interatomic
distances, 470.

Z2

110

Hinton, M. A. C., Musk rat,
488.

Hirst, Dr. E. L., Teaching of

general science, 566*.

Hopce, W. V. D., Abelian integrals,
456, O11.

Hopson, Mrs. C. B. S., Genetics,
492*.

Ho pen, Prof. H. S., New pterido-
sperm stem from Shore, 550.

Ho.ianp, J. L., Development of
national system of education, 219,
569%.

Hopkins, Sir F. G., Some chemical
aspects of life, 1.

—— Teaching of general science,
566*.

Hormones, discussion by Prof. F.
Kégl, G. A. D. Haslewood, Dr.
A. Butenandt, Prof. E. C. Dodds,
466, 612.

Hormones, plant growth, by Prof. F.
Kégl, 466*, 600.

Hormones and genetics, by Col.
C. J. Bond, 492, 612.

Horne.., J., Indonesian contact
with East African culture, 521,
615.

Horton, C., Motor Boat Association,
402.

Horwoop, A. R., Flora of Leicester-
shire, Appdx. 25.

Hosiery industry, education for, by
J. Chamberlain, 565, 617.

Hot cathode gas discharge tubes, by
L. J. Davies, 451.

Howrie, R. J., Science teaching in
adult education, 564*.
Hull, pollution of river,

Sheppard, 596.

Human geography of tropical Africa!
report on, 274.

Humpureys, Dr. F. E., Tanning
properties of tan liquors and ex-
tracts, 472, 612.

Hunt, Dr. E. H., Rafai fakirs of
Hyderabad, 523*.

Hunter, Dr. D., Ossification, 532,
616.

Horst, Dr. C. C., Genetics of intel-
lect, 543, 616.

Significance of genetics in
evolution, 491, 613.

Hutton, Dr. J. H., Megalithic work
in Assam, 525, 615.

by T.

INDEX

Huxtey, Prof. J. S., Physiological
genetics, 491*.

Hype, F. F., Floral morphology of
Campanuloidee, 554, 617.

Hyderabad, Rafai fakirs, by Dr.
E. H. Hunt, 523*.

Hydro-electric companies, by W. 'T.
Halcrow, 403.

Igneous rocks of Leicestershire, by
F. Jones, 476.

India, races and languages, by Sir
E. A. Gait, 499, 673.

Indonesian contact with East African
culture, by J. Hornell, 521, 675.
Infra-red photography, by O. Bloch,

429, 610.
Inland water, bibliography, by J.
Glasspoole, 367.
Inland water survey, report on, 358.
Insect outbreaks in Britain, pre-

diction, by Dr. S. MacLagan,
490*, 613.

Insect parasites, by Dr. G. Salt,
486.

Insects, distribution by air currents,
by P. S. Milne, 489.

Insects, water in physiology of ex-
cretion, by Dr. V. B. Wiggles-
worth, 486, 673.

Intellect, genetics of, by Dr. C. C.
Hurst, 543, 626.

Interatomic distances and forces in
molecules, discussion by Dr. N.V.
Sidgwick, Prof. Lennard-Jones,
Dr. J. M. Robertson, Dr. J. D.
Bernal, E. J. Bowen, C. N. Hin-
shelwood, 468, 672.

Invertebrates, nerves and nerve-nets,
by C. F. A. Pantin, 491.

Inverted bundle system, by Miss
L. M. Wicks, 557.

Irwin, Dr. J. O., Validity of methods
of correlation, 547, 616.

Ivens, J. P., Industries of Leicester,
Appdx. 60.

Jackson, K. H., Weather prophecy,
Celtic, 517, 615.

Janert, Dr. H., Drainage investiga-
tions, 573.

Jasper Park, biology and fisheries,
by Dr. C. H. O° Donoghue, 493.

INDEX

JENKIN, Prof. C. F., on Earth pres-
sures, 297.

Jervis, Prof. W. W., Land tenure at
Congresbury, Somerset, 526.

Joun, D., Plankton in southern
oceans, 490.

Jounston, W. A., Gold production
of Canada, 485.

Jongs, F., Petrology of igneous rocks
of Leicestershire, 476.

Jones, Prof. J. H., Gold standard,
109, 503.*

Jones, Miss J. K., Village survey,
571.

Jones, Prof. Ll. R., Rainfall in
Kenya and Uganda, 497.

Jones, M. G., Grazing and effect on
sward, 574, 618.

Jones, Rev. P., Amateur meteoro-
logist, 599*.

Jones, S. J., Land tenure at Congres-
bury, Somerset, 526.

Jones, Dr. W. R., Silicosis, 479,
612,

Kay, Dr. H. D., Milk production
and distribution, 577*, 618.

Ossification, 532, 616.

Keay, W., Raw Dykes, Leicester,
518.

KeitH, Sir A., on Kent’s Cavern,
301.

Kent’s Cavern, report on, 301.

Kenya and Uganda, rainfall, by
Prof. Ll. R. Jones and F. H. W.
Green, 497.

Kerguelen Archipelago, floras, by
Prof. A. C. Seward, 549, 617.

KersHaw, L. W., Industries of
Leicester, Appdx. 60.

Kikuyu marriage customs, by Dr.
L. S. B. Leakey, 521*.

Kincpom, T., Secondary school
training for business, 562.

Kirkapy, J. F., Longitudinal pro-
files of southern English rivers,

485.
Kleinia articulata, report on, 311.
Knitting, mechanisation, by J.

Chamberlain, 510, 614.

Kéct, Prof. F., Plant growth hor-
mones, 466*, 600.

Kuun, Prof. R., Carotenoids and
flavines, 464.

IItl

Labrador, Eskimos of, by Prof. V.
Suk, 520.

Lady Manners School, agriculture
research, by A. S. McWilliam,
570, 618,

Landscape, visualisation, by Dr. V.
Cornish, 495.

Land utilisation in S.W. London
basin, by Dr. L. D. Stamp and
E. C. Willatts, 500.

Lauper, Dr. A., Chemistry and agri-
culture, 243, 571*.

Lawe, F. W., University men in
department store, 563, 617.

LAXTON, open-field parish, by C. S.
Orwin, 574, 618.

Leakey, Dr. L. S. B., Excavations
at Apis Rock, 528*.
—— Kikuyu marriage

21%:

Rift Valley in Kenya, 484.

Leather, absorption of water, by H.
Bradley, 451.

Leather manufacture, physical prob-.
lems, by Dr. C. H. Spiers, 451*,
6II.

Lee, H. W., Photographic lenses at
Leicester, 430, 610.

Leicester, development of photo-
graphic lenses, by W. Taylor and
H. W. Lee, 430, 610, 627.

Leicester, education in, by F. P.
Armitage, Appdx. 80.

Leicester, geology, by H. H. Gregory,
Appdx. 17.

Leicester, growth of population, by
Miss G. M. Sarson, 494.

Leicester, industries, by L. W. Ker-
shaw, F. R. Antcliff, J. Chamber-
lain, J. P. Ivens, F. W. Roberts,
Appdx. 60.

Leicester, land utilisation, by Dr.
P. W. Bryan, 495*.

Leicester, municipal activities, by
H. A. Pritchard, Appdx. 72.

Leicester, Raw Dykes, by W. Keay,
518.

Leicester, regional setting, by Dr.
P. W. Bryan, Appdx. 3.

Leicester and district, scientific survey,
Appdx. 3.

Leicester and Leicestershire, men of
science, by F. B. Lott, Appdx. 84.
Leicester district, geology, by H. H.

Gregory, 476*.

customs,

112

Leicester district, regional planning,
by H. H. Peach, 495, 673.

Leicester meeting, narrative, xvii.

Leicestershire, climate, by E. G.
Bilham, Appdx. 40.

Leicestershire, farming, by 'T. Hack-
ing, Appdx. 48.

Leicestershire, flora, by A. R. Hor-
wood, Appdx. 25.

Leicestershire, petrology of igneous
rocks, by F. Jones, 476.

Leicestershire, water supply, by M.
Gimson, 494, 673.

Leicestershire, zoology, by Dr. E. E.
Lowe, W. E. Mayes, R. Wag-
staffe, S. O. Taylor, Appdx. 33.

Leicestershire igneous rocks, Tri-
assic and Pleistocene surfaces, by
Dr. F. Raw, 484.

LEMAITRE, L’Abbé, Cosmical sig-
nificance of clusters of nebule, 448.

LENNARD-JONES, Prof. J. E., Inter-
atomic distances, 468*.

LeonarD, Dr. A. G. G., Natural
purification of sewage, 513, 614.
Lepidosiren, life and reproduction
of, by J. T. Cunningham, 488,

612,

Leucocytic and erythrocytic activity,
by Col. C. J. Bond, 533.

Levels, rest and pumping, and rain-
fall, by A. E. Cornewall-Walker,
420.

Lewis, E. I., Requirements of busi-
ness career, 562, 618.

Life, chemical aspects, by Sir F. G.
Hopkins, 1.

Life, mechanical view, by Dr. J.
Gray, 81, 486*.

Light, influence on permeability of
plant cell, by Prof. G. Senn, 557*.

Linroot, Dr. E. H., Dissection of
large numbers, 454.

Linke, Prof. F., Cloud evolution,
460*.

Influence of stratosphere on
cyclone formation, 430.

LinsteaD, Dr. R. P.,
cyanines, 465, 612.

Luioyp, Dr. D. J., Chemistry of skin,
470, 612. -

—— Structure of protoplasm, 490*.

Luoyp, Prof. F. E., Is Roridula car-
nivorous ?, 552.

Traps of Utricularia, 183, 554*.

Phthalo-

INDEX

Lockyer, Dr. W. J. S., Periodic
changes in Be-type spectra, 459,
61T.

Lone, A. P., Utilisation of thinnings,
559, 617.

Longitudinal profiles of southern
English rivers, by Dr. S. W. Wool-
dridge and J. F. Kirkaldy, 485.

Lon Mor Experimental Station,
peat planting, by J. A. B. Mac-
donald, 560.

Lott, F. B., Scientific men of
Leicester and Leicestershire, Appdx.

Loughborough, training of engineers
at, by Dr. H. Schofield, 565.

LoweE, Dr. E.E., Zoology of Leicester-
shire, Appdx. 33.

Lowe, M. F., Blood distribution
during mental work, 544.

Lundy, communities of, by A. T. J.
Dollar, 518, 675.

Lundy, dike-swarm, by A. T. J.
Dollar, 481, 672.

Lupton, H. R., Sewage machinery,
514, 614.

Luxemburg iron industry, by K. C.
Edwards, sor, 673.

McCiean, Capt.
gauging, 421.
Surface water, 383.
McCrea, Dr. W. H., Milne’s theory
and general relativity, 445, 6r0.
Solar chromosphere and cor-
ona, 459.

MacCurpy, Dr. J. T., Disorienta-
tion and vertigo, 538.

MAcDONALD, J., Effects of thinnings
in coniferous plantations, 559*.

Macpona.Lp, J. A. B., Peat planting
at Lon Mor Experimental Station,
560.

McDouca.i’s Lamarckian experi-
ment, by Prof. F. A. E. Crew, 542.

McDowa tt, Prof. R. J. S., Chemical
control of circulation, 535.

McKay, A. M., Embrittling of
steels, 516, 624.

MacxiE, Prof. 'T. J., Milk supplies
and public health, 576.

MacLacan, Dr. S., Prediction of |
insect outbreaks in Britain, 490%,
613.

W. N., River

INDEX

Mac.eop, Col. M. N., Mapping of
Empire, 496.

MeVirttiz, Dr. G. C., Condensa-
tions of matter in an expanding
universe, 443, 610.

Non-static solutions of
Einstein’s gravitational equations,
459, OI.

McWiuiam, A. S., Agriculture

research at Lady Manners School,
570, 678,

Magnetic field, axial spin, by Prof.
W. Cramp, 453, 611.

Maiden Island, Crinanite dike, by
Dr. F. Walker, 481.

Mair, Dr. L., Growth of econo-
mic individualism among African
peoples, 521.

MaitLanp, Dr. P., Chemistry of
Quebracho tannin, 471, 612.

Maitianp, Dr. T. G., Disorienta-
tion and vertigo, 539.

Mallorca, human geography,
E. W. Gilbert, 497, 673.

Manton, Dr. I., Analysis of species,
492*, 613.

Maps and illustrations, preparation,
by Lt.-Col. A. B. Clough, 497,
673.

Margidunum, by Dr.
519%.

Market research, psychological ap-
proach, by N. M. Balchin, 548,
616.

Marsna., C. E., Plant structure in
coal, 481.

Maartin, Miss M. T., Suzeda mari-
tima and S. fruticosa, 552.

Masters, Miss H., Science teaching
in adult education, 564*.

Mathematical tables, report on, 269.

Matruews, Prof. J. R., Problems
of British flora, 557*, 617.

Maucuan, W., Canal projects, 516*,
614.

Mayss, W. E., Zoology of Leicester-
shire, Appdx. 33.

Mechanical ability, report on, 305.

Mechanical engineering, experi-
epee; by R. W. Allen, 129,
510%,

Mechanical view iof life, by Dr. J.
Gray, 81, 486*.

Megalithic work in em
Dr. J. H. Hutton, 525*, 675.

by

F. Oswald,

by

113

Mental work, blood distribution, by
M. F. Lowe, 544.

MestTon, Rt. Hon. Lorp, Geography
as mental equipment, 93, 499*.

Meteorologist, amateur, discussion
by J. Fairgrieve, Dr. G. C.
Simpson, Prof. F. G. Baily, Capt.
T. Dannreuther, Rev. P. Jones,
T. Sheppard, 599.

Midlands, grazing, by Ald. P. F.
Astill, 574, 618.

Muss, Dr. G. H., Human factor in
relation to design of factory equip-
ment and machinery, 508.

Milk production and distribution,
discussion by Prof. T. J. Mackie,
W. Godden and Dr. J. Black-
wood, Dr. N. C. Wright, B.
Davies, Prof. G. S. Wilson, Dr.
H. D. Kay, Miss O. Nethersole,
576, 618.

Miter, Prof. D. C., Ether-drift
experiment, 451*, 670.

Mine, Prof. E. A., Expanding
universe, 436, 610.

MILng, P. S., Distribution of insects
in atmosphere, 489.

Milne’s theory and general relativity,
by Dr. W.-H. McCrea, 445, 610.

Mines, Safety Research Board, by
Prof. J. F. Thorpe, 584.

Monocotyledon shoot, by Miss L. I.
Scott and Prof. J. H. Priestley,
552".

Motion study of small assembly and
machine work, by Miss A. G.
Shaw, 540, 616.

Motor Boat Association,
Horton, 402.

Motor unit, overseas, by Sir H.
Fowler, 512.

Mountsorrel igneous complex, by
J. H. Taylor, 484.

Mugharet el-Tabun, excavation of,
by Miss D. A. E. Garrod, 527*.
Multiple planes, by Dr. P. du Val,

457, OIL.

byraic,

| Munpt, H., Good forest and thin-

nings, 559, 617.

Music, primitive, in S. Sudan, by
Dr. A. N. Tucker, 529.

Musical research, anthropological
aspects, by Dr. S. F. Nadel, 529,

615.
Musk rat, by M. A. C. Hinton, 488.

114

Mycorrhiza and forestry, by Dr.
M. C. Rayner, 560, 617.

Myers, Dr. C. S., on Mechanical
ability, 305.

Myres, Prof. J. L., on Bronze Age
implements, 300.

Science in adult education,
569, 618.

——on Science teaching in adult
education, 330, 564*.

NabeEL, Dr. S. F., Anthropological
aspects of musical research, 529,
615.

Narcosis and mental function, by
Dr. J. H. Quastel, 543.

National system of education, develop-
ment, by J. L. Holland, 219,
569%.

Native warfare on Lower Colorado
River, by Prof. C. D. Forde, 519,
615.

NEAL, L., Organisation of economic
distribution, 509, 614.

NEAVERSON, Dr. E., St. George’s
Land, 478.

Nebulz, cosmical significance of
clusters, by l’Abbé Lemaitre, 448.

Neolithic Period to Bronze Age in
W. Asia, by T. B. Brown, 527*.

Nerve-cells, activity, by Prof. E. D.
Adrian, 163, 533*.

Nerves and nerve-nets in inverte-
brates, by C. F. A. Pantin, 491.
NETHERSOLE, Miss O., Milk pro-
duction and distribution, 577*.
NEVILLE, Prof. E. H., on Mathe-

matical tables, 269.

NicuHotson, H. H., Field drains on
farms, 572.

Drainage investigations, 572.

Niemen River, by Miss H. G.
Wanklyn, 502.

Nimmo, H., Electricity stations, 404.

Low river flows, 408.

Nose, Miss M., Typhula trifolii
Rostrup, 553.

‘Noegenetic and factor theories, by
F. C. Thomas, 541.

Noise, reduction of aircraft, by
R.S. Capon, 511, 674.

Notan, Prof. J. J., Discharge from
raindrop in intense electric field,

463.

INDEX

North Sea, prediction of cod fish-
eries, by M. Graham, 492, 673.
Nose-opening rays, by Dr. T. Bed-
ford and A. F. Dufton, 533, 675.

Oates, Dr. D. W., Factors in
scholastic ability, 566, 678.

Occupations, classification of com-
munities by, by Dr. E. H. Sel-
wood, 499.

O’DonocuuE, Dr. C. H., Biology
and fisheries of Jasper Park, 493.

(Estrin, by G. A. D. Haslewood,
466, 612.

(Estrogenic compounds, synthetic,
by Prof. E. C. Dodds, 468, 6r2.

Officers and Council, v.

OrrorD, Dr. A. C., Fourier and
Hankel transforms, 455, 627.

OurPHANT, Dr. M. L., Disintegra-
tion of elements, 432, 6I0.

OuivE, G. W., Teaching of general
science, 566*.

OrDE-POWLETT, Hon.N.A., Forestry
and sport, 559, 617.

Organisation as technical problem,
discussion by Dr. E. F. Armstrong,
Maj. L. Urwick, A. B. Blake, 506,
64.

Orton, Prof. J. H., on Sex physio-
logy, 272.

Orwin, C. S., Open-field parish of
Laxton, 574, 618.

Ossification, discussion by Prof. R.
Robison, Dr. H. B. Fell, Dr.
H. D. Kay, Dr. L. J. Harris, Dr.
D. Hunter, 531, 616.

OswaLp, Dr. F., Margidunum,
519*.

Ovary, acarpous nature of inferior,
by Prof. J. McL. Thompson, 554,
617.

PALMER, Sir R., Stone circles in
Gambia valley, 524, 615.
PANTIN, C. F. A., Nerves and nerve-
nets in Invertebrates, 401.
ParkKER, Dr. A., Water pollution, 410.
Pascal’s theorem in 7 dimensions, by
H. G. Green, 458, 617.
Pasteurisation, implications of com-
pulsory, by Dr. N. C. Wright, ©
577, O18.

INDEX

Patent and copyright law, by Prof.
A. Plant, 504, 673.

PeacH, H. H., Regional planning
and Leicester district, 495, 673.
Peake, H. J. E., on Sumerian copper,

302.

Peat planting at Lon Mor Experi- |

mental Station,
Macdonald, 560.
Peers, Prof. R., Science teaching in
adult education, 564*.
Pendulum, spherically free, by C.
H. H. Franklin, 450, 620.
PENTELOw, F. T. K., Fauna and
flora of rivers, 599*.
Personal influence, by
Brown, 542, 616.
Personal relations and small group, |
by Dr. G. G. N. Wright, 547, 616.
Personality and temperament, by
Dr. P. E. Vernon, 541, 616.

Dr. W.

by J. A. B.|

Puiiuires, Dr. H., Vegetable tanning

process, 471, 612.
Photographic lenses at Leicester, by

W. Taylor and H. W. Lee, 430, |

610, 611.

Phthalocyanines, by
Linstead, 465, 612.

Physics in adult education, by Dr.
A. Ferguson, 569*, 617.

Physiology, value to industry, by
G. P. Crowden, 508, 674.

Praccio, Prof. H. T. H., Validity of
methods of correlation, 547, 616.

Plankton, behaviour in relation to
conditions, by F. S. Russell, 490,
613.

Plankton, distribution in southern
oceans, by G. E. R. Deacon and
Dilwyn John, 489, 673.

Pant, Prof. A., patent and copy-
right law, 504, 613.

Plant growth hormones, by Prof. F.
Kégl, 466*, 600.

Pokorny, Prof. J., Origin of Celts,
517, 615.

Polar year, by Prof. F. Debenham,
499*.

Positive electron, by
Blackett, 433.

Post Office counter staff, by G. C.
Wickins, 563, 678.

Potteries, painted, from India and
East Iran, by Prof. V. G. Childe,
527, 615.

Dra Res P.

PAIMEWS.

115

PouLTon, Prof. E. B., on Zoological
bibliography, 273.

Practice periods, distribution, by
Miss R. M. Goldthorpe, 540*.
Pratt, Lt.-Col. E., Propagation and

growth of Salix ccerulea, 558, 617.

President, installation, xvi.

PRESTON, Dr. R. D., Cell wall of
Valonia, 428, 6r0.

PRIESTLEY, Prof. J. H., Monocotyle-
don shoot, 552*.

PRITCHARD, H. A., Municipal activi-
ties of Leicester, Appdx. 72.

Protoplasm, diffusion and extension
phenomena in living, by E.
Heron-Allen, 486*, 673.

Protoplasm, structure, discussion by
J. E., Harris.) Dew Ds aje- Lloyd,
W. T. Astbury, 490%.

Psychological tests, by A. Rodger,
Ghee

Psychological tests and examina-
tions, predictive value, discussion
by Prof. C. W. Valentine, Dr.
D. W. Oates, F. Barraclough,
F. Sandon, Prof. J. Drever, Miss
A. B. Dale, E. Farmer, 545*, 566,
617, 618,

Psychologist, function in adminis-
trative scheme, by Mrs. N. M.
Barnes, 549.

Psychology, report on training in, 308.
Psychology, status as empirical science,
by Prof. F. Aveling, 171, 542*.
Psycho-physiological requirements
of modern factory equipment, dis-
cussion by Sir H. Fowler, G. P.
Crowden, Dr. G. H. Miles, 508,

6r4.

Public expenditure and _ public
works, by J. Sykes, 505.

Publication, reference to, 610.

Pucu, Prof. W. J., Geography and
geology in adult education, 568*,
618,

Pumps, oil condensation, by C. R.
Burch, 451, 677.

Purser, G. L., Anatomy of Calamo-
ichthys, 488*.

QuasTEL, Dr. J. H., Narcosis and
mental function, 543.

Quebracho tannin, chemistry, by
Dr. P. Maitland, 471, 612.

116

Racial characteristics, blood groups
as index, by Prof. R. R. Gates,
522, 615.

Rafai fakirs of Hyderabad, by Dr.
E. H. Hunt, 523*.

Racuan, Rt. Hon. Lorp, What is
tradition ?, 145, 518*.

Raindrop, discharge in intense
electric field, by Prof. J. J. Nolan
and J. P. Ryan, 463.

Rainfall, rest and pumping levels, by
A. E. Cornewall-Walker, 420.

Raistrick, Dr. A., Developed Tar-
denoisian sites in N.E. England,
519.

Microspores of coal, 480.

RANDALL, J. T., Spectroscopy in
industry, 451*, 611.

RapHaEL, Mrs. W., Employment by
Civil Service, companies and
‘family ’ firms, 548.

Rats, learning of, by Prof. E. C.
Tolman, 545*, 626.

Rattray, Dr. R. S., Present ten-
dencies of African Colonial
Governments, 524, 615.

Raw, Dr. F., Triassic and Pleisto-
cene surfaces on Leicestershire
igneous rocks, 484.

Raw Dykes, Leicester, by W. Keay,
518.

Rayner, Dr. M. C., Mycorrhiza and
forestry, 560, 617.

Reaction time, competition, by Prof.
H. Hartridge, 536.

Reclamation of land and_ sea
defences, by M. Du-Plat-Taylor,
516, 614.

Red sedimentary rocks, discussion
by Prof. G. Hickling, Prof. W. S.
Boulton, Prof. W. T. Gordon,
F. W. Shotton, Dr. B. Smith,
Dr. H. C. Versey, Prof. D. M.S.
Watson, 482.

REGENER, Prof. E., Cosmic ray
measurements, 430*, 620.

Regression, phenomenal, by Dr.
R. H. Thouless, 542, 676.

Rep, Sq.-Ldr. G. H., Disorienta-
tion and vertigo, 540*.

Relativity and Milne’s theory, by
Dr. W. H. McCrea, 445, 620.
Research, centralisation and co-ordina-
tion, by Dr. R. E. M. Wheeler,

589.

INDEX

Research Committees, xxxviii.

Resolutions and recommendations,
xliv.

Rift Valley, age, by Dr. L. S. B.
Leakey, 484.

River gauging, by Capt. W. N.
McClean, 421.

River pollution, legal aspect, by
H. F. Atter, 513, 674.

Rivers, changes in flora and fauna,
discussion by J. W. Walton,
F. T. K. Pentelow, J. Adams,
T. S. Dymond, H. E. Salmon,
Dr. J. F. Tocher, 599*.

Rivers, low flows, by H. Nimmo,
408.

Road and rail, division of function,
by G. Walker, 506, 673.

Roperts, F. W., Industries of
Leicester, Appdx. 60.

RoBERTSON, Dr. J. M., Interatomic
distances in aromatic hydro-
carbons, 468, 612.

ROBERTSON, W. A., Public opinion
of forestry, 561, 617.

RoBINSON, Prof. R., Natural colour-
ing matters and analogues, 45,
464*.

RosBIson, Prof. R., Ossification,
531, 616.

Rosson, Dr. G. C., Limitations of
adaptability in animal kingdom,
487.

Zoological surveys, 596.

Rosy, F. H., Manchester Statistical
Society, 589*.

Ropcer, A., Psychological tests,
512.

Temperament and vocational
psychologist, 540, 616.

Roesuck, A., Rook in rural economy
of Midlands, 487, 673.

Roxes, T., Gauging River Aire,
407.

Rook in rural economy of Midlands,
by A. Roebuck, 487, 673.

Roridula, is it carnivorous ?, by
Prof. F. E. Lloyd, 552.

ROSEVEARE, Capt. J. C. A., Catch-
ment boards, 397.

Land drainage, 398.

Rotu, G. K., Decaying arts and
crafts of Fiji, 528, 675.

RoucuTon, Dr. F. J. W., Carbon
dioxide transport in blood, 533.

INDEX

ROWLAND, Rev. J. P., Wensleydale
earthquake, 461.

Roxsy, Prof. P. M., on Human
geography of tropical Africa, 274.

RussELL, F. S., Marine plankton
animals, 490, 673.

RussELL, Sir J., on Empire soil re-
sources, 296.

RUTHERFORD, Rt. Hon. Lorp, Atomic
transmutation, 431, 610.

Ryan, J. P., Discharge from rain-
drop in intense electric field, 463.

Safety in Mines Research Board, by
Prof. J. F. Thorpe, 584.

Saint George’s Land, discussion by
Prof. W. S. Boulton, E. E. L.
Dixon, Dr. T. N. George, Dr.
E. Neaverson, T. Eastwood, 477,
612.

Salix ccerulea, propagation and
growth, by Lt.-Col. E. Pratt,

558, 617.

SaLmon, H. E., Fauna and flora of |

rivers, 599*.

SaLT, A., Accountancy in scientific
management, 507*.

Sat, Dr. G., Insect parasites, 486.

SaLT, H., Education for boot and
shoe industry, 564, 628.

SANDON, F., School examinations
and psychological tests, 567, 618.

Sarson, Miss G. M., Growth of
population in Leicester, 494.

Sayce, R. U., Distribution of belief
in fairies, 526*.

ScHorieLD, Dr. H., Engineering
training at Loughborough, 565.
Scholastic ability, factors, by Dr.

D. W. Oates, 566, 678.

School research work, discussion
by Dr. A. H. Smith, Dr. L. D.
Stamp, A. S. McWilliam, Miss
J. K. Jones, 570, 678.

Science and economic progress, by
Sir J. Stamp, 578.

Science in adult education, sym-
posium by Sir R. Gregory, Prof.
W. J. Pugh, Prof. W. B. Brierley,
Dr. A. Ferguson, Prof. J. L.
Myres, Dr. V. Cornish, Sir J.
Stamp, 568, 617, 618.

Science teaching in adult education,
report on, 330, 564*.

117

Science teaching in adult education,
discussion by Prof. J. L. Myres,
DraiGeH.-Desch; At SioPicth;
Miss H. Masters, R. J. Howrie,
Prof. R. Peers, G. C. Hickson,
564*.

Scolt Head Island, by J. A. Steers,
496, 613.

Scott, Miss L. I., Monocotyledon
shoot, 552*.

Sea defences and land reclamation,
by M. Du-Plat-Taylor, 516, 674.

Seasonal weather and its prediction,
by Sir G. T. Walker, 25, 430*.

Sectional Officers, ix.

Seedling anatomy, significance, by
Dr. E. N. M. Thomas, 553*.

Seismological investigations, report
on, 265.

SELwoop, Dr. E. H., Classification
of communities by occupations,
499.

SENN, Prof. G., Influence of light
on permeability of plant cell,
557%.

Sensory comparisons, ‘ constant’
errors, by R. J. Bartlett, 544.

Sensory events, report on quantitative
estimates of, 271.

Seto, Dr. G., Clinical aspects of
stuttering, 545.

Severn, gauging at Bewdley, by Prof.
S. M. Dixon, 424.

Severn, gauging at Ironbridge, by
E. F. Hetherington, 406.

Sewage treatment and disposal, dis-
cussion by J. D. Watson, H. F.
Atter, Prof. W. E. Adeney and
Dry vA... ‘Ge Ge beonardiasy:
Haworth, F. C. Vokes, H. R.
Lupton, 513, 614, 615.

Sewarp, Prof. A. C., Floras of
Kerguelen Archipelago, 549, 617.

Sex hormones, relation to sterols
and bile acids, by Dr. A. Bute-
nandt, 467, 612.

Sex physiology, report on, 272.

Suaw, Miss A. G., Motion study of
small assembly and machine work,
540*, 616.

SHEPPARD, T’., Amateur meteor-
ologist, 599*.

Pollution of River Hull, 596.

Shoe manufacturing machinery, by
J. Gouldbourn, 515, 614.

118

Shore, new pteridosperm stem from,
by Prof. H. S. Holden, 550.

SHOTTON, F. W., Red sedimentary
rocks, 483.

Shropshire,
472.

Sipewick, Dr. N. V., Interatomic
distances, 468*.

Natural colouring matters, 466.

ey by Dr. W. R. Jones, 479,

men ,

Simons, Dr. L., Diatomic rotator,
431*, 650.

Simpson, Dr. G. C.,
meteorologist, 599.

Condensation of water in at-
mosphere, 463.

Skin, chemistry, by Dr. D. J. Lloyd,

geological excursion,

Amateur

470, 612.

Skin, chemistry, and -catechol
tannins, by Prof. M. Bergmann,
471, OIT.

Skin resistance, by Prof. H. Hart-
ridge, 536.

Sludge, treatment and utilisation, by
F. C. Vokes, 514, 614.

SmalL, Prin. J. C., Training for
business and administration, 564*.

Smart, E. H., Diatomic rotator,

7. ee Nini a ON 5 a

Smitu, Dr. A. H., Field names,
570%.

SmitTH, Dr. B., Red sedimentary
rocks, 483.

Underground water, 413.

SmitH, C. C., Water supply authori-
ties’ records, 396.

Soil resources, Empire, report on,
296.

Solar chromosphere and corona, by
Dr. W. H. McCrea, 4509.

Sone Coronada, by O. Davies, 527,

ioe

South Arabian Desert, first crossing,
by B. Thomas, 519*.

Southern oceans, hydrology, by
G. E. R. Deacon, 489, 673.

Southern oceans, plankton, by D.
John, 490.

SpPaRSHOTT, Miss E. N., Tuberisa-
tion, 556.

SPEAKMAN, Dr. J. B., Fibre chem-
istry and X-ray analysis, 428, 611.

SPEARMAN, Prof. C., Determination
of unitary traits, 547.

INDEX

SPEARMAN, Prof. C., Theory of two
factors, 545, 616.

Species, analysis of, by Dr. I.
Manton, 492*, 673.

Species, synthesis of, by Dr. K. B.
Blackburn, 492.

Spectroscopy in industry, by J. T.
Randall, 451*, 6r17.

Spigrs, Dr. C. H., Physical problems
of leather manufacture, 451*, 677.

Stamp, Sir J., Must science ruin
economic progress ?, 5°78.

Science in adult education,

. 569*.

Stamp, Dr. L. D., Changes in utili-
sation of land in S.W. London
basin, 500.

Types of local survey, 570.

STANFORD, F. O., Water supply
authorities, 391.

Steels, embrittling, by A. M. McKay
and R. N. Arnold, 516, 6r4.

Steers, J. A., Scolt Head Island,
496, 673.

Stellar colour temperatures, by W.
M. H. Greaves, 459.

Stellar spectra, line intensities, by
A. D. Thackeray, 459.

Sterculiaceez, development of rays,
by Miss M. M. Chattaway, 552,
617.

STEwakrT, Prin. H., University train-
ing for business, 562.

Stigma, nature and origin, by Dr.
H.H. Thomas, 550, 677.

Stocks, genetical system for ever-
sporting, by Prof. R. A. Fisher,
550, 617.

Stone circles in Gambia Valley, by
Sir R. Palmer, 524, 675.

Stratosphere, influence on cyclone
formation, by Prof. F. Linke, 430.

Stresses in overstrained materials,
report on, 296, 517*.

Stuttering, clinical aspects, by Dr.
G. Seth, 545.

Suzeda maritima and S. fruticosa, by
Miss M. T. Martin, 552.

Sudan, S., primitive music, by Dr.
A. N. Tucker, 529.

Suez Canal dues and inter-continental
trade, by Sir A. Wilson, 504, 673.

Sux, Prof. V., Eskimos of Labrador,
520.

Sumerian copper, report on, 302.

INDEX

Supersaturation of water in free
atmosphere, by L. H. G. Dines,
464.

Superstitious beliefs in Gold Coast,
by A. W. Cardinall, 523, 675.

Survey, types of local, by Dr. L. D.
Stamp, 570.

Survey, village, by Miss J. K. Jones,

571.
Sykes, J., Public expenditure and
public works, 505.

Talking film in industry, by H.
Warren, 451*.

Tan liquors and extracts, tanning
properties, by Dr. F. E. Hum-
phreys, 472, 612.

Tanning process, chemistry of, dis-
cussion by Dr. D. Jordan Lloyd,
Prof. K. Freudenberg, Dr. P.
Maitland, Prof. M. Bergmann,
Dr. H. Phillips, F. C. Thompson,
Dr. F. E. Humphreys, 470, 611,
612.

Tannins, behaviour to proteins, by
Prof. K. Freudenberg, 470, 612.
Tardenoisian sites, developed, in

N.E. England, by Dr. A. Raistrick,

519.

Taytor, Prof. E. G. R., Economic
geography of early Stuart England,
501.

Tay or, J. H., Mountsorrel igneous
complex, 484.

Tay or, S. O., Zoology of Leicester-
shire, Appdx. 33.

Taytor, W., Features of Taylor,
Taylor & Hobson works, 510*, 614.

Photographic lenses at Leices-
ter, 430, 6IT.

Taylor, Taylor & Hobson works,
by W. Taylor, 510*, 614.

Teachers, research work by, discus-
sion by Dr. A. H. Smith, Dr.
L. D. Stamp, A. S. McWilliam,
Miss J. K. Jones, 570, 628.

Technological and economic pro-
gress, by R. F. Harrod, Prof.
J. A. S. Watson, Dr. K. G.
Fenelon, 504*.

Teeth, fibre structure, by J. Thewlis,
429, OII.

Television, by Maj. A. G. Church,
451*, 610.

119

Temperament and personality, by
Dr. P. E. Vernon, 541, 616.

Temperament and vocational psy-
chologist, by A. Rodger, 540, 616.

Temperature gradients near ground,
by A. C. Best, 462, 6r7.

Tertiary and Cretaceous rocks, report
on, 271.

Testing flexible sheet materials, by
H. Bradley, 451*, 671.

Testudinaria elephantipes, by Miss
E. N. Sparshott, 556.

Tetrad theory, sampling error, by
Dr. J. Wishart, 546, 676.

Tuackeray, A. D., Line intensities
in stellar spectra, 459.

Thames, gauging, by G. J. Griffiths,
425.

Thames Conservancy, by
Griffiths, 398.

THEWLIS, J., Fibre structure in teeth,
429, OIL.

Thinnings, effects in coniferous
plantations, by J. Macdonald,
559%.

Thinnings, utilisation, by A. P.
Long, 559*, 617.

Thinnings and good forest, by H.
Mundt, 559, 617.

Tuopay, Prof. D., on Kleinia articu-
lata, 311.

Tuomas, B., First crossing of South
Arabian Desert,.519*.

Tuomas, Dr. E. N. M., significance
of seedling anatomy, 553*.

Tuomas, F.C., Factor and noegenetic
theories, 541.

Tuomas, Dr. H. H., Nature and
origin of stigma, 550, 6177.

Tuompson, F. C., Gelatin-tannin
reaction, 472, 612.

Tuompson, Prof. J. McL., Acarpous
nature of inferior ovary, 554, 617.

Tuomson, D. H., Water level at
Compton, 417.

TuorPE, Prof. J. F., Safety in Mines
Research Board, 584.

Tuou.ess, Dr. R. H., Phenomenal
regression, 542, 616.

TILLotson, E., High focus earth-
quakes, 460.

Tocuer, Dr. J. F., Fauna and flora
of rivers, 599*.

Toitman, Prof. E. C., Learning of
rats, 545*, 616.

Givy.

I20

Trade associations and combina-
tions, by A. B. Blake, 507.

Tradition, what is?, by Rt. Hon.
Lord Raglan, 145, 518*.

Training in psychology, report on, 308.

Traits, determination of unitary, by
Prof. C. Spearman, 547.

Traits, mutual independence of
several sets, by Dr. S. S. Wilks,
546, 616.

Transmutation, atomic, discussion
by Rt. Hon. Lord Rutherford.
Dr. J..D. Cockcroft and Dr. E.
T.S. Walton, Dr. M. L. Oliphant,
P. I. Dee, 431, 610, 6117.

Transplant experiments, report on, 310.

Trees and countryside, by W. Dalli-
more, 558.

Trent Catchment Board, by W. H.
Haile, 399.

Tuberisation, by Miss E. N. Spar-
shott, 556.

Tucker, Dr. A. N., Primitive music
in S. Sudan, 529.

Two-factor theory, by Prof. C.
Spearman, 545, 616.

Typhula trifolii Rostrup, by Miss M.
Noble, 553.

U.S.A., metropolitan regions, by
R. E. Dickinson, 502, 673.

Uganda and Kenya, rainfall, by |

Prof. Ll. R. Jones and F. H. W.
Green, 497.

ULLyorTT, P., Vertical movements of
Zooplankton, 490*.

Unemployment, engineering works |
as cure, by Prof. M. Walker, 515, |

615.
Ur, archaic period, by Dr. C. L.
Woolley, 528*.
Urwick, Maj. L., Organisation as a
technical problem, 506, 614.
- Utricularia, entrance mechanisms of
traps, by Prof. F. E. Lloyd, 183,
554*.

Vacuum tubes, high voltage, by Dr.
T. E. Allibone, 452.

VALENTINE, Prof. C. W., Develop-
ment of language in child, 537, 626.

Unreliability of entrance exam-

inations, 566*, 678.

INDEX

Valonia, cell wall, by Dr. R. D.
Preston, 428, 610.

VAN DE GraarrF, Dr. R. J., Electro-
static generation of high voltage
for nuclear research, 427*.

Engineering possibilities of
electrostatics, 453.

VaucuHaNn, Dr. W. W., Teaching of
general science, 566*.

VeEGARD, Prof. L., Auroral spectrum
and upper atmosphere, 427, 6IT.

Vegetable tanning process, by Dr.
H. Phillips, 471, 612.

VERNON, Miss M. D., Binocular
vision of flickering fields, 548, 676.

VERNON, Dr. P. E., Temperament
and personality, 541, 626.

VersEY, Dr. H. C., Red sedimentary
rocks, 483.

Vertebrates, origin of land-living, by
Prof. D. M. S. Watson, 488*,
613.

Vertigo and disorientation, discus-
sion by Dr. J. T. MacCurdy,
Fl.-Lt. J. A.G. Haslam, Dr. T. G.
Maitland, Sq.-Ldr. E. D. Dick-
son, R. J. Bartlett, Dr. R. S.
Creed, Sq.-Ldr. G. H. Reid, 530*,
538, 616.

Visual sensations,quantitative bright-
ness, by F. H. Gage, 541.

Vitamin action and bone formation,
by Dr. L. J. Harris, 532, 616.

VoKEs, F. C., Treatment and utilisa-
tion of sludge, 514, 614.

WacstTartfFeE, R., Zoology of Leicester-
shire, Appdx. 33.

Wales, hill forts and valleyward
movements of population, by
E. G. Bowen, 525.

Watker, Dr. F., Crinanite dike of
Maiden Island, 481.

WatkerR, G., Division of function
between road and rail, 506, 613.
WALKER, Sir G. T., Seasonal weather

and its prediction, 25, 430*.

WALKER; Prof. M., Engineering
works as cure for unemployment,
515, 615.

Watters, R. C. S., Pumping tests at
new borings, 419.

—— Gauging chalk wells over long °
periods, 419.

INDEX

Watton, Dr. E. T. S., Transmuta-
tion of elements, 432, 6ZT.

Watton, J. W., Hythe canal fish,

*

WANKLYN, Miss H. G., Niemen
River, 502.

Warren, H., Talking film in in-
dustry, 451*.

Water, surface,
McClean, 383.

Water, underground, by
Smith, 413.

Water organisations, foreign, by Dr.
B. Cunningham, 371.

Water pollution and gauging, by Dr.
A. Parker, 410.

Water supply authorities, by F. O.
Stanford, 391.

Water supply authorities’ records, by
C. C. Smith, 396.

Watson, Prof. D. M. S., Origin of
land-living vertebrates, 488*, 673.

Red sedimentary rocks, 484.

Watson, Prof. J. A. S., Techno-
logical and economic progress,
504*.

Watson, J. D., Sewage treatment
and disposal, 513, 615.

Weather, prediction of seasonal, by
Sir G. T. Walker, 25, 430*.

Weather prophecy, Celtic, by K. H.
Jackson, 517, 615.

Wells, chalk, gauging over long periods,
by R. C. S. Walters, 419.

Wells, water levels, by F.J. Dixon, 418.

Wensleydale earthquake, by Rev.
J. P. Rowland, 461.

WENT, Prof. F. A. F. C., Growth-
substance (Auxin) in plants, 555,
617.

WENTWORTH-SHEILDS,
Earth pressures, 297.

WHEELER, Dr. R. E. M., Centralisa-
tion and co-ordination of research,
589.

Wuiper Le, Dr. F. J. W., on Seismo-
logical investigations, 265.

WuiteEHeaD, J. H. C., Calculus of
variations of large: loci of con-
jugate points, 458.

Wicxkins, G. C., Post office counter
staff, 563, 628.

Wicks, Miss L. M., Inverted bundle
system, 557.

by Capt. W. N.
Dra B.

EF. E., on

I2I

WIGGLEsSWorTH, Dr. V. B., Water
in physiology of excretion in
insects, 486, 673.

Witks, Dr. S. S., Mutual inde-
pendence of several sets of traits,
546, 616.

Wittatts, E. C., Changes in utilisa-
tion of land in S.W. London
basin, 500.

Wirtuiamson, Mrs. H. S., Develop-
ment of As scophanus aurora
(Crouan) Boud., 553, 617.

WILSON, Sir A., Suez Canal dues
and inter-continental trade, 504,
613.

Witson, Prof. G. S., Necessity for
safe milk supply, 577, 618.

Witson, W., ‘Testing electrical
switch equipment, 512, 615.

Wimperis, H. E., Film in engineer-
rhover, Iito ie

Aeronautical research, 511.

WisHart, Dr. J., Sampling error in
tetrad theory, 546, 616.

Woop, Mrs. E. M., Organisation of
economic distribution, 509*.

Wootprince, Dr. S. W., Longitu-
dinal profiles of southern English
rivers, 485.

WoolttEy Dro Cae. ie
archaic period, 528*.

WricuT, Dr. G. G. N., Personal
relations and small group, 547, 616.

Wricut, Dr. N. C., Implications of
compulsory pasteurisation, 577,
678,

the

X-ray analysis of fibres, discussion
by W. T. Astbury, Dr. R. D.
Preston, Dr. J. B. Speakman, J.
Thewlis, 428, 550*, 610, 611.

Yorkshire, West Riding, Rivers Board,
by J. H. Garner, 401.

Zoological bibliography, report on,
Wee

Zoological surveys, by Dr.
Robson, 596.

Zoology in adult pauiation: by Prof.
W. B. Brierley, 569, 617.

Zooplankton, vertical movements,
by P. Ullyott, 490*.

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