PROCEEDINGS

OP THE

ROYAL SOCIETY OF LONDON,

From March 3, 1898, to June 16, 1898.

VOL. LXIII.

LONDON:
HARRISON AND SONS, ST. MARTIN'S LANE,

in ©rbitrarg to |IJ« ^aj«stu.
MDCCCXCVIII.

LONDON :
HAEBISON AND SONS, PBINTEBS IN OBDINABY TO HEE MAJESTY,

ST. MAETIN'S IANE.

CONTENTS.

VOL. LXIII.

No. 389.

Meeting of March 3, 1898, and List of Candidates for Election 1

List of Papers read 2

On the Depletion of the Endosperm of Hordeum vulgare during Germi-
nation. By Horace T. Brown, F.E.S., and F. Escombe, B.Sc,, F.L.S.
(Plate 1) S

No. 390.
Meeting of March 10, 1898, and List of Papers read ...; 25

On the Modifications of the Spectra of Iron and other Substances
radiating in a strong Magnetic Field. By Thomas Preston, M.A.
Communicated by Professor Geo. Francis FitzGerald, F.E.S 2(>

Note on the Connection between the Faraday Eotation of Plane of
Polarisation and the Zeeman Change of Frequency of Light Vibra-
tions in a Magnetic Field. By Geo. Fras. FitzGerald, F.E.S.,

F.T.C.D ;. ; 31

On Artificial Temporary Colour-blindness, with an Examination of the
Colour Sensations of 109 Persons. By George J. Burch, M.A.
Communicated by Professor Gotch, F.E.S 35

On the Connection between the Electrical Properties and the Chemical
Composition of different kinds of Glass. By Professor Andrew Gray,
LL.D., F.E.S., and Professor J. J. Dobbie, M.A., D.Sc 38

On the Magnetic Deformation of Nickel. By E. Taylor Jones, D.Sc.
Communicated by Professor Andrew Gray, F.E.S 44

Upon the Structure and Development of the Enamel of Elasmobranch
Fishes. By Charles S. Tomes, M.A., F.E.S 54

On Apogamy and the Development of Sporangia upon Fern Prothalli.
By William H. Lang, M.B., B.Sc., Lecturer in Botany, Queen
Margaret College, and " G. A. Clark " Scholar, Glasgow University.
Communicated by Professor F. O. Bower, Sc.D., F.E.S 56

Experimental Observations on the Early Degenerative Changes in the
Sensory End Organs of Muscles. By F. E. Batten, M.D. Commu-
nicated by Professor Victor Horsley, F.E.S 61

IV

No. 391.

Page
Meeting of March 17, 1898, Croonian Lecture, &c 63

Meeting of March 24, 1898, Bakerian Lecture, &c 63

On the Relation between the Diurnal Range of Magnetic Declination
and Horizontal Force and the Period of Solar Spot Frequency. By
William Ellis, F.R.S., formerly of the Royal Observatory, Green-
wich , 64

On the Relative Retardation between the Components of a Stream of
Light produced by the Passage of the Stream through a Crystalline
Plate cut in any direction with respect to the Faces of the Crystal.
By James Walker, M.A. Communicated by Professor R. B. Clifton,
F.R.S 79

An Extension of Maxwell's Electro-magnetic Theory of Light to in-
clude Dispersion, Metallic Reflection, and Allied Phenomena. By
Edwin Edser, A.R.C.S. Communicated by Captain W. de W. Abney,
C.B., F.R.S 91

CROONIAN LECTURE. — The Nature and Significance of Functional Meta-
bolism in the Plant (Das Wesen und die Bedeutung des Betriebsstof-
wechsels in der Pflanze). By Wilhelm Pfeffer, Sc.D. (Cantab.), of the
University of Leipzig, For. Mem. R.S 93

BAKERIAN IJECTTJRE. — Further Experiments on the Action exerted by
certain Metals and other Bodies on a Photographic Plate. By W. J.
Russell, Ph.D., V.P.R.S 102

No. 392.

On Contact Electricity of Metals. By J. Erskine-Murray, D.Sc.,
F.R.S.E., Heriot-Watt College. Communicated by Lord Kelvin,
G.C.V.O., F.R.S 113

No. 393.

the Rotation of Plane of Polarisation of Eleciric Waves by a Twisted
Structure. By Jagadis Chunder Bose, M.A., D.Sc., Professor of
Physical Science, Presidency College, Calcutta. Communicated by
Lord Rayleigh, F.R.S 146

On the Production of a " Dark Cross " in the Field of Electro-magnetic
Radiation. By Jagadis Chunder Bose, M.A., D.Sc., Professor of
Physical Science, Presidency College, Calcutta. Communicated by
Lord Rayleigh, F.R.S 152

The Relations between Marine Animal and Vegetable Life. By H. M.
Vernon, M.A., M.B. Communicated by Professor Burdon Sander-
son, F.R.S 155

No. 394.

Report of the Kew Observatory Committee- for the Year ending
December 31, 1897 161

Page

On the Calculation of the Coefficient of Mutual Induction of a Circle
and a Coaxial Helix, and of the Electromagnetic Force between a
Helical Current and a Uniform Coaxial Circular Cylindrical Current
Sheet. By Professor J. Viriamu Jones, F.E.S 192

Meeting of March 31, 1898 205

No. 395.

Meeting of April 28, 1898, and List of Papers read 206

On the Meteorological Observatories of the Azores. By H.S.H. Prince
Albert I of Monaco. Communicated by J. Y. Buchanan, F.RS 206

A Compensated Interference Dilatometer. By A. E. Tutton, Assoc.
E.C.S. Communicated by Captain Abney, C.B., F.RS. 208

Meeting of May 5, 1898, and List of Papers read 212

Observations on the Action of Anaesthetics on Vegetable and Animal
Protoplasm. By J. B. Farmer, M.A., and A. D. Waller, M.D.,
F.E.S 213

On certain Structures formed in the Drying of a Fluid "with Particles
in Suspension. By Catherine A. Eaisin, B.Sc. Communicated by
Professor T. G. Bonney, F.E.S. (Plate 2) 217

The Eelations between the Hybrid and Parent Forms of Echinoid
Larvae. By H. M. Vernon, M.A., M.B. Communicated by Pro-
fessor E. Eay Lankester, F.E.S 228

No. 396.
Meeting of May 12, 1898, and List of Papers read 231

A Calorimeter for the Human Body. By William Marcet, M.D.,

F.E.S 232

An Experimental Enquiry into the Heat" given out by the Human
Body. By W. Marcet, M.D., F.E.S., and E. B. Floris, F.C.S 242

Preliminary Note on the Liquefaction of Hydrogen and HeHum. By
James Dewar, M.A., LL.D., F.E.S., Fullerian Professor of Chemistry
in the Eoyal Institution , 256

Effects of Prolonged Heating on the Magnetic Properties of Iron. By
S. E. Eoget, B.A. Communicated by Professor Ewing, F.E.S 258

On the Connection of Algebraic Functions with Automorphic
Functions. By E. T. Whitaker, B.A., Fellow of Trinity College,
Cambridge. Communicated by Professor A. E. Forsyth, Sc.D.,
F.RS I 267

A Study of the Phyto-Plankton of the Atlantic. By George Murray,
F.E.S., Keeper of Botany, British Museum, and V. H. Blackmail,
B.A., F.L.S., Hutchinson Student, St. John's College, Cambridge, and
Assistant, Department of Botany, British Museum 269

VI

No. 397.

Page

Meeting of May 26, 1898, and List of Papers read 270

On the Intimate Structure of Crystals. Part I. Crystals of the Cubic
System with Cubic Cleavage. By W. J. Sollas, LL.D., D.Sc., F.E.S.,
Professor of Geology in the University of Oxford 270

On the Intimate Structure of Crystals. Part IT. Crystals of the Cubic
System with Cubic Cleavage. Haloid Compounds of Silver. By W.
J. Sollas, LL.D., D.Sc., F.E.S., Professor of Geology in the University
of Oxford 286

On the Intimate Structure of Crystals. Part III. Crystals of the
Cubic System with Cubic Cleavage. By W. J. Sollas, LL.D., D.Sc.,
F.E.S., Professor of Geology in the University of Oxford 296

The Electrical Eesponse of Nerve to a Single Stimulus investigated
with the Capillary Electrometer. Preliminary Communication. By
F. Gotch, M.A., F.R.S., Professor of Physiology, University of
Oxford, and G. J. Burch, M.A. (Oxon.) 300

No. 398.

On the Magnetic Susceptibility of Liquid Oxygen. By J. A. Fleming,
M.A., D.Sc., F.E.S., Prof essor of Electrical Engineering in University
College, London, and James Dewar, M.A., LL.D., F.E.S., Fullerian
Professor of Chemistry in the Eoyal Institution, London, &c 311

Aluminium as an Electrode in Cells for Direct and Alternate Currents.
By E. Wilson. Communicated by Dr. J. Hopkinson, F.E.S 329

Contributions to the Study of " Flicker." By T. C. Porter, Eton College.
Communicated by Lord Eayleigh, F.E.S 347

On the Kathode Fall of Potential in Gases. By J. W. Capstick, M.A.,
D.Sc., Fellow of Trinity College, Cambridge. Communicated by
Professor J. J. Thomson, F.E.S 356

Note on the Complete Scheme of Electrodynamic Equations of a Moving
Material Medium, and on Electrostriction. By Joseph Larmor,
F.E.S., Fellow of St. John's College, Cambridge 365

No. 399.

Annual Meeting for the Election of Fellows 373

Meeting of June 9, 1898, and List of Papers read 373

An Extension of Maxwell's Electro-magnetic Theory of Light to include
Dispersion, Metallic Eeflection, and Allied Phenomena. By Edwin
Edser, A.E.C.S. Communicated by Captain W. de W. Abney, C.B.,
F.E.S 374

A Photographic Investigation of the Absorption Spectra of Chlorophyll
and its Derivatives in the Violet and Ultra-violet Eegion of the
Spectrum. By C. A. Schunck. Communicated by Dr. E. Schunck,
F.E.S. (Plates 3, 4, 5) 389

VI 1

Page

On Photographic Evidence of the Objective Eeality of Combination
Tones. By K. W. Forsyth, A.K.C.S., and R J. Sowter, A.RC.S.
Communicated by Professor Eiicker, Sec.E.S. (Plates 6, 7) 396

On the Cytological Features of Fertilisation and Related Phenomena in
Pinus silvestri*, L. By Vernon H. Blackman, B. A., F.L.S., Hutchin-
son Student, St. John's College, Cambridge, and Assistant, Depart-
ment of Botany, British Museum. Communicated by Francis Darwin,
F.E.S : 400

Experiments on Aneroid Barometers at Kew Observatory and their
Discussion. By C. Chree, Sc.D., LL.D., F.R.S., Superintendent 401

On the Heat dissipated by a Platinum Surface at High Temperatures.
By J. E. Petavel, 1851 Exhibition Scholar. Communicated by Lord
Eayleigh, F.E.S. 403

On a New Constituent of Atmospheric Air. By William Eamsay,
F.E.S., and Morris W. Travers 405

On the Position of Helium, Argon, and Krypton in the Scheme of
Elements. By Sir William Crookes, F.E.S 408

No. 400.

Meeting of June 16, 1898, and List of Papers read 412

Observations on Stomata. By Francis Darwin, F.E.S 413

Mathematical Contributions to the Theory of Evolution. V. On the
Eeconstruction of the Stature of Prehistoric Eaces. By Karl
Pearson, F.E.S., University College, London 417

The Nature of the Antagonism between Toxins and Antitoxins. By
C. J. Martin, M.B., D.Sc., Lond., Acting Professor of Physiology,
and Thomas Cherry, M.D., M.S., Melb., Demonstrator and Assistant
Lecturer in Pathology in the University of Melbourne. Communi-
cated by D. Halliburton, F.E.S 420

On the Source of the Eontgen Bays in Focus Tubes. By Alan A.
Campbell Swinton. Communicated by Lord Kelvin, F.E.S... 432

On the Companions of Argon. By William Eamsay, F.E.S., and Morris
W. Travers 437

Summary of the Principal Eesults obtained in a Study of the Develop-
ment of the Tuatara (Spkenodon punctatum). By Arthur Dendy,
D.Sc., Professor of Bioloary in the Canterbury College, University of
New Zealand. Communicated by Professor G. B. Howes, F.E.S 440

The Stomodfeum, Mesenterial Filaments, and Endoderm of Xenia. By
J. H. Ashworth, B.Sc., Demonstrator in Zoology, Owens College,
Manchester. Communicated by Professor Hickson, F.E.S 443

On Surfusion in Metals ?nd Alloys. By W. C. Eoberts- Austen, C.B.,
D.C.L., F.E.S. (Plates 8, 9) 447

Experimental Investigations on the Oscillations of Balances. By D.
Mendeleeff, For. Mem. E.S 454

Vlll

Page

On the Determination of the Magnetic Susceptibility of Rocks. By
A. W. Riicker, Sec.R.S., and W. H. White, A.R.C.S 460

On the Detection and Localisation of Phosphorus in Animal and
Vegetable Tissues. By A. B. Macallum, Associate-Professor of
Physiology, University of Toronto. Communicated by Professor
Sherrington, F.R.S 467

Falmouth Magnetic Observatory. Note „.. 480

Obituary Notices : —

Prof. Hubert A. Newton i

Sir Richard Quain vi

James Joseph Sylvester (with Portrait) ix

Alfred Louis Olivier Le Grand Des Cloizeaux xxv

John Carrick Moore xxix

Baron Ferdinand von Mueller xxxii

Index xxxvii

Erratum xliii

PROCEEDINGS

OF

THE ROYAL SOCIETY

March 3, 1898.

SIR JOHN EVANS, K.C.B., D.C.L., Treasurer and Vice-President,

in the Chair.

In pursuance of the Statutes, the names of the Candidates for
election into the Society were read, as follows : —

Allen, Alfred Henry, F.C.S.

Baker, H. Brereton, M.A.

Baker, Henry Frederick, M.A.

Barrett, Professor W. F., F.R.S.E.

Binnie, Sir Alexander Richardson,
M.Inst.C.E.

Bovey, Professor Henry T., M.A.

Bridge, Professor Thomas William,
M.A.

Brown, Professor Ernest William.

Bruce, Surgeon-MajorDavid, M.B.

Buchan, Dr. Alexander, M.A.

Burch, George James, M.A.

Callaway, Charles, D.Sc.

Oardew, Major Philip, R.E.

Corfield, William Henry, M.D.

Crookshank, Professor Edgar
March, M.B.

David, Professor T. W. Edge-
worth, B.A.

Dixon, Professor Alfred Cardew,
M.A.

Dixon, Professor Augustus Ed-
ward, M.D.

Gamble, James Sykes, M.A.
VOL. LXIII.

Gray, Professor Thomas, B.Sc.

Haddon, Alfred Cort, M.A.

Hamilton, Professor David James,
M.D.

Harmer, Sidney Frederic, M.A.

Head, Henry, M.D.

Hiern, William Philip, M.A.

Kanthack, Professor Alfredo A.,
M.D.

Lansdell, Rev. Henry, D.D.

Lewes, Professor Vivian B.,
F.C.S.

Lewis, W. Bevan, M.R.C.S.

Lister, Arthur, F.L.S.

Lister, Joseph Jackson, M.A.

MacArthur, John Stewart, F.C.S.

MacGregor, Professor James Gor-
don, D.Sc.

McMahon, Lieutenant - General
Charles Alexander.

Mallock, Henry Reginald Arn-
ulph.

Mance, Sir Henry C., C.T.E.

Mansergh, James, M.Inst.C.E.

Marsh, James Ernest, M.A.
B

List of Papers read.

Matthej, Edward, F.C.S.

Mill, Hugh Robert, D.Sc.

Morgan, Professor Conwy Lloyd,
F.G.S.

Muir, Thomas, M.A.

Muirhead, Alexander, D.Sc.

Notter, Surgeon-Lieut. -Col.
James Lane.

Oliver, Major-Gen. John Ryder,
R.A.

Osier, Professor William, M.D.

Parsons, Hon. Charles A., M.A.

Perkin, Arthur George.

Preston, Professor Thomas, M.A.

Rambaut, Arthur A., M.A.

Reid, Clement, F.G.S.

Reid, Professor Edward Way-
mouth, M.B.

Salomons, Sir David, Bart., M.A.

Scott, Alexander, M.A.

Seward, Albert Charles, M.A.

Shenstone, William Ashwell,
F.I.C.

Smith, Professor William Robert,
M.D.

Smithells, Professor Arthur,

F.C.S.
Spencer, Professor W. Baldwin,

B.A.

Starling, Ernest Henry, M.D.
Stockman, Professor Ralph, M.D.
Swinton, Alan Archibald C ,

Assoc. M.Inst.C.E.
Symington, Professor Johnston,

M.D.
Tanner, Professor Henry William

Lloyd, M.A.
Taylor, Henry Martyn.
Thomas, Michael Rogers Oldfield,

F.Z.S.

Threlfall, Professor Richard.
Tutton, Alfred E., F.C.S.
Walker, Professor James, D.Sc.
Waterhouse, Colonel James.
White, William Hale, M.D.
Whymper, Edward, F.R.G.S.
Wimshurst, James.
Windle, Bertram Coghill Allen,

M.D.
Woodhead, German Sims, M.D.

The following Papers were read : —

I. " The Relationship of Variations of the Ground- water Level to
the Incidence of Malarial Fevers in Chotta Nagpur, Bengal."
By Dr. L. ROGEES. Communicated by Dr. LAUDER BRUNTON,
F.R.S.

II. " On the Depletion of the Endosperm of TTordeum vulgare during
Germination." By H. T. BROWN, F.R.S. , and F. ESCOMBE.

III. "On Apogamy and the Development of Sporangia upon Fern

Protballi." By W. H. LANG. Communicated by Professor
BOWER, F.R.S.

IV. " Experimental Observations on the Early Degenerative Changes

in the Sensory End-organs of Muscles." By Dr. F. E.
BATTEN. Communicated by Professor V. HORSLEY, F.R.S.

Depletion of Endosperm of Hordeum vulgare. 3

<; On the Depletion of the Endosperm of Hordeum vulgare
during Germination." By HORACE T. BROWN, F.R.S., and
F. ESCOMBE, B.Sc., F.L.S. Received December 11, 1897,—
Read March 3, 1898.

[PLATE 1.]

In an account given by one of us in 1890 of the results of an
investigation of the histological and physiological changes which
take place in the seeds of the Grasses during germination,* a pro-
minent position was given to a discussion of the relations existing
between the endosperm and embryo, and to the part played by each
in the preparation of the reserve materials of the seed for the
nutrition of the young plant. This branch of the inquiry was
much facilitated by the discovery that the embryo, when separated
from the other parts of the seed, is capable of an independent
existence, providing it is supplied with a suitable artificial nutri-
ment in the form of certain carbohydrates, its own store of pro-
teids being sufficient to supply the nitrogen requisite for the
production of young plants of a considerable size.

The carbohydrates most favourable to rapid growth in such cases
are sucrose, dextrose, and maltose ; but it was also found that the
embryo, when deprived of such readily assimilable material, acquires
the power of dissolving solid starch to a very notable extent, a
function which was subsequently localised in the columnar epithe-
lium of the scutellum.

The endosperm itself was also subjected to examination with a
view to determine if it possesses any power of acting on the reserve
materials contained within its cells, and of bringing about any
self-depletion which is independent of the influence of the embryo.

This question was attacked in two different ways. In the first
place, endosperms, after being degermed, were placed under favour-
able conditions for the full play of any metabolic activity which
might be possessed by any portion of their tissue, every facility
being afforded for the rapid outward diffusion of the products of
change ; and, secondly, advantage was taken of a fact which had
previously been established, that an embryo may be transferred
from one endosperm to another without materially affecting its
power of subsequent growth ; thus affording an opportunity of
subjecting an endosperm to such treatment as may reasonably be
supposed capable of destroying any residual vitality in its cells,
and of then observing how this affects the subsequent development
of a fresh embryo " grafted " upon it.

For the full details of these experiments we must refer to the

* Brown and Morris, ' Chem. Soc. Journ.,' vol. 57, p. 458.

B 2

4 Messrs. Brown and Escombe. On the Depletion of the

original paper, and here merely quote the general conclusions which
were drawn from them.

Although the peripheral layer of the endosperm, the so-called
"aleurone-layer," or " Kleberschicht," undoubtedly consists of living
cells, no evidence could be obtained of the existence of any
residual vitality in the amyliferous cells, which constitute by far the
greater portion of the endosperm.

No changes were observed in the isolated endosperms in the
direction of self-depletion which were comparable in intensity with
those produced when the embryo was attached ; and when those
changes did occur they were always preceded by an invasion of
bacteria and moulds in the culture-medium, the disintegration and
dissolution of the endosperm-contents in such cases proceeding in
such a manner as to suggest that they were conditioned entirely
by the organisms.

When living embryos were " grafted " on endosperms which had
remained in alcohol for six months, and in which it was then
reasonable to suppose that any residual vitality had been effectually
destroyed, all the usual phenomena incident to normal germination
were observable in those endosperms. Hence it was concluded that
the idea of any co-operation on the part of the endosperm-cells was
superfluous, and that the determining factor in the normal endo-
spermous changes is the embryo itself, which, by independent ex-
periment, had been shown to possess the power of dissolving
starch and of initiating those phenomena of cytohydro lysis which
are amongst the earliest exhibited in natural germination. Accord-
ing to this view the endosperm of Hordeum, and probably of all the
Grasses, is, as far as its starch- containing cells are concerned, a dead
storehouse of reserve material, whose stores can be converted to the
use of the plant by the action of the embryo only, and that this,
for a limited period of its existence, lives a truly saprophytic
life.

These conclusions are in accord with the views of Van Tieghem,
that, whilst an endosperm, such as that of Ricinus, containing oil
and aleurone as reserve materials, is endowed with a vital activity
of its own, by virtue of which it is capable of digesting the reserve
material in preparation for the embryo, the endosperm of Eeeds,
whose reserve materials, on the other hand, consist of starch and
cellulose, remains passive during germination, the digestion of its
reserves being in this case effected by the embryo.

Two years after the appearance of the above-mentioned paper,
Proffer gave a brief description of some work by B. Hansteen,
' tj ber die Ursachen der Entleerung der Reservestoffe aus Samen,'*

* 'Ber. der Itouigl. Sachs. Gesellscli. d. Wissenschaften zu Leipzig,' 1893,.
p. 421.

Endosperm of Hordeum vulgare during Germination. 5

which was followed the year afterwards by a more detailed paper
on the same subject by Hansteen himself.*

Hansteen strenuously opposes Van Tieghem's division of endo-
sperms into "active" and "inactive," and asserts that the latter
was led into error on this point by not taking precautions to put
his endosperms under conditions favourable for the rapid removal of
the products of change. Although reference is made to the Brown
and Morris paper of 1890, the author does not appear to have made
himself thoroughly acquainted either with the details of the experi-
ments described or with the conclusions drawn from them.

Hansteen's principal experiments were made with the seeds of Zea
Mays and Hordeum vulgare, but he also made observations on the
mucilaginous endosperm of Tetragonolobus purpureus, and the cotyle-
dons of Lupinus luteus and Helianthus annuus. For our present pur-
poses it is only necessary to consider the experiments on barley and
maize. The seed was, in the first instance, soaked in water for two
days, and the embryos, including the scutellum, were removed. To
the isolated endosperms there was then applied a mixture of plaster
of Paris and water, so as to form a small plaster column, which
occupied the original position of the embryo.

The little plaster columns, with the endosperms attached, were
then put into glass dishes containing a sufficient amount of water
to reach half-way up the columns. In order to avoid the disturbing
influence of micro-organisms the seeds were placed for two hours in
a 1 per cent, solution of copper sulphate ; all the materials and
vessels used were carefully sterilised, and the experiments were
performed under strict antiseptic conditions in a cultivation chamber
so arranged as only to admit germ-free air. The author states that
he has been able in this manner to maintain his cultures sterile for
at least a month. When there was a sufficient amonnt of water in
the culture- dishes, and the conditions were thus favourable for a
rapid outward diffusion of the products of change, Hansteen found
that, within from ten to thirteen days of commencing the experi-
ment, the isolated endosperms of both maize and barley had given
rise to a very considerable self-digestion of the cell-contents. In
the immediate neighbourhood of the plaster the cells had quite lost
their starch, whilst the starch-granules, even at a distance, were
more or less corroded, and the partially depleted endosperm had
become soft and disintegrated. ]n the case of barley these visible
changes were very strongly marked indeed, and simultaneously with
them sugar could be detected in the water into which the small
plaster columns dipped.

In those experiments in which the amount of water had been
much reduced, but very little starch-erosion took place at the point
* ' Flora,' vol. 70, 1894, p. 410.

6 Messrs. Brown and Escombe. On the Depletion of the

of contact with the plaster, a fact which the author attributes to the
accumulation within the endosperm of an excess of soluble products,
which thus exercise an unfavourable influence on the continuous
chemical change of the solid reserve substances.

In view of Haberlandt's assertion that the cells of the " Kleber-
schioht " have a distinct diastase-secreting function, Hansteen
experimented in a similar manner with endosperms which had been
deprived of this layer, and he found the same indications of self-
depletion as before. He therefore concluded that the dissolution
and depletion which he had observed are due to a special activity of
the inner starch-bearing cells of the endosperm. The question is
then discussed whether, during germination, the embryo does or
does not secrete an enzyme, and the conclusions arrived at are in
accord with those of Brown and Morris, and Griiss, that such a secre-
tion does take place. Hansteen, again agreeing with the former
observers, regards this secretion of diastase as conditioned by the
falling off in the supply of readily soluble carbohydrates; whether,
however, the diastase so produced plays an important part in normal
depletion, or whether the asserted self-depletive power of the endo-
sperm-cells is sufficient, in normal germination, to account for all the
observed results, the author leaves an open question.

In a long memoir entitled " Beitrage zur Physiologic der Kei-
mung,"* J. Griiss discusses the question of the appearance of fer-
ments in the endosperms of maize and barley after excising the
embryos and filing off the " Kleberschicht " (" aleurone-layer ").
From experiments made by burying fragments of such endosperms
for a few days in sterilised moist sand, he concludes that the starch-
bearing cells have the power of producing spontaneously within
themselves a diastase, the presence of which he determined, in the
first place microscopically by the extremely doubtful guaiacum-reac-
tion, and secondly by the increased action of the endosperm-tissue
on thin starch-paste.

The most recent contribution to the subject is a paper, taking the
form of a preliminary communication, by K. Puriewitsch, "Ueber
die selbstthatige Entleerung der Reservestoffbehalter,"t followed since
by a more detailed paper, entitled " Physiologische TJntersuchurigen
iiber die Entleerung der Reservestoffbehalter."^ Making use in the
main of Hansteen's method of experiment, Puriewitsch examined,
amongst other seeds, the isolated endosperms of Zea Mays, Triticum
sativum, Hordeum distichon, Secale cereale, and Oriza sativa, and he
extended his observations to the cotyledons, bulbs, rhizomes, and
roots of various other plants, a list of which is given in his paper.

* ' Landwirtschaft. Jahrbiicher,' 1896, p. 385.
f ' Ber.-Deut. Bot. Gesell.,' vol. 14, 1896, p. 207.
J ' Pringsheim's Jabrb.,' vol. 31, 1897, p. 1.

Endosperm of Hordeum vulgare during Germination. 7

In the case of maize he found the first indications of action in the
cells lying next the scutellum, and this gradually extended along the
periphery of the endosperm until, within fourteen or fifteen days,,
this was completely emptied of its contents, with the exception of a
few cells in the central portions. He states that this action is not
due to any direct influence of the plaster, as suggested by Griiss,.
since it takes place also in contact with water only. In the coty-
ledons of Lupinus the depletion takes place even with greater
rapidity than in normal germination, and no difference is observed
whether the cut surface in contact with the water or gypsum, as the
case may be, is on the side adjacent or opposite to the axial organs.
With the isolated endosperms of maize and wheat, on the other
hand, Puriewitsch states that the case is different, since self-deple-
tion proceeds much more rapidly through the surface originally in
contact with the scutellum than it does from the opposite side. The
author also found that the depletion of the endosperm is much
retarded in the case of maize and wheat by the presence iii the
water of 2 per cent, of dextrose or glycerine, or by 3 per cent, of
cane sugar, and that it is completely arrested by 1*5 per cent, of
sodium chloride or potassium nitrate. The results on the whole are
regarded as contradicting the conclusions of Brown and Morris that
the endosperm is merely an inactive storehouse of reserve material,
and Puriewitsch considers that this is further borne out by the
behaviour of isolated endosperms in an atmosphere of water and by
the action of anesthetics such as ether and chloroform. Under these
latter conditions, he states that the endosperms of maize and wheat
remain unchanged, but that the depletive action recommences as
soon as the disturbing influences are removed. Attempts were
made, by applying food material in the form of weak sugar solu-
tions, to induce a re-deposition of reserve material in the self-de-
pleted tissue. These attempts were wholly unsuccessful in the case
of maize and wheat, but the emptied cotyledons of Lupinus albus and
Phaseohis multiftcrus, the bulbs of Hyacinthus orientalis, and the
rhizomes of Curcuma amada and Iris germanica were all capable of
re-forming starch within their cells.

It will be noticed that in the recent work of Hansteen, Pfeffer,
Griiss, and Puriewitsch, there is a general agreement that the amyli-
ferous cells of the endosperm of the Grasses have a definite power of
digesting their reserve materials, this power being entirely inde-
pendent of any influence of the embryo, and the only necessary con*
dition for its exhibition being that the products of metabolism shall
not be allowed to accumulate within the endosperm. The conclusion
is, in fact, that the starch-bearing endosperm-cells are still living
units, just as are the cells of the cotyledons of Lupinus, Phaseolus, and
Ricinus, which are admitted on all hands to have self-depletive power.

Messrs. Brown and Escombe. On the Depletion of the

As these conclusions are in many respects opposed to those arrived
at by one of us a .few years ago, we have considered it necessary to
institute a further series of experiments, and to re-examine the
whole question of the mutual dependence of the embryo and endo-
sperm. In doing this we have endeavoured to free our minds of any
bias which might, even unconsciously, have been given by our
previous experiments, and to subject those experiments to the
strictest possible criticism.

Broadly speaking, the question resolves itself into a consideration
of the various causes at work in bringing about the solution of the
reserve material of the seed in preparation for its absorption by the
scutellum of the young plant, and the due apportionment of this
work to (1) the embryo itself, (2) the amyliferous cells, and to (3)
the peripheral cells of the endosperm, the so-called " aleurone-layer "
or " Kleberschicht."

In addition to this, we have to take into account the possibility of
eome of the changes being brought about by enzymes pre-existent in
the amyliferous cells, which may be altogether independent of the
present life of the cytoplasm. We have, further, to determine the
part played by micro-organisms accidentally brought into action
during the experiments, and to eliminate the changes due to their
influence alone.

In work of this character we can only attain to results of any
value by a great multiplication of experiments made in such a
manner as to admit of the close and frequent comparison of different
series performed under every conceivable variation of conditions.

All our new work was conducted on barley only, and the results
are based on very many hundreds of experiments, extending over a
period of more than twelve months, during which time various
possible sources of error were gradually excluded.

As long as we confine our attention to intact seeds the disturbing
influence of micro-organisms is but small, but the case is different
when the seed envelopes have to be cut through and the embryo
removed, the endosperm, thus bared and deprived of its protective
coatings, being then open to the attack of bacteria and moulds,
which thrive in the culture-medium employed, and by their action
induce changes in the contents and cell-membranes of the endosperm-
cells which it is almost impossible to distinguish from those initiated
by the cells themselves, supposing them to be living and active
units.

At the outset of the investigation we spent a considerable time in
endeavouring to find some antiseptic agent possessed of such a differ-
ential action as to inhibit, or at any rate to materially retard, the
growth of micro-organisms, whilst not interfering with the normal
growth of vegetable organs. Many various reagents were tried,

Endosperm of Hordeum vulgare during Germination. 9

commencing with extremely dilute solutions, which were gradually
increased in strength until their influence on the germinative power
of the seed was just perceptible. The germicidal effect of such a
solution was then tested on degermed grains in water-culture. At
one time extremely dilute solutions of formaldehyde and of acid
potassium fluoride offered some hope of success in this direction, but
neither of these substances on further investigation gave a sufficient
differential action to be of any practical use.

In the experiments of 1890 (Brown and Morris, loc. cit.) the dis-
turbing effect of micro-organisms was minimised by restricting the
time of the experiment as far as possible, and by sterilising the
culture-media, and we have seen that Hansteen relied on killing the
adherent germs with a solution of copper sulphate, and on the
employment of strict antiseptic methods, even to the extent of carry-
ing out all the operations in a germ-free atmosphere.

We have made experiments in order to see how far such a treat-
ment with copper sulphate effects sterilisation of the integuments,
the grain after such treatment being incubated in contact with vege-
table infusions. The results have clearly shown us that although
such a procedure may retard the subsequent development of Bac-
teriacece and moulds, it is impossible by means of it to ensure a com-
plete destruction of all the germs adherent to the palese, unless the
treatment is sufficiently prolonged to destroy, or at any rate to mate-
rially reduce, the germinative power of the embryo.

Since any process which will affect the .vitality of the embryo
cannot be without some similar influence on the endosperm, there is
thus introduced an element of uncertainty into all subsequent pro-
cesses wrhich maybe devised for determining whether the amyliferous
cells are living or dead.

Extreme refinements for avoiding air-sown organisms are obviously
of little efficacy when complete initial sterilisation of the exterior of
the grain cannot be ensured. Nevertheless, many of our experiments
have been carried on with precautions of this kind, but have not
yielded better results than those made in covered dishes with sterili-
sation of the culture-media and apparatus.

In all experiments with endospermous seeds deprived of their
embryos both Hansteen and Pfeffer have, very properly, laid great
stress on the necessity for providing for a rapid removal of any
possible products of change in the isolated endosperm as fast as they
are formed, but these observers have apparently entirely overlooked
the fact that this was fully insisted upon and provided for in the
earlier experiments described by one of us in 1890.* The plan
adopted was to insert the proximal ends of the degermed grains
into small holes made in a thin mica plate, which was then floated
* ' Chem. Soc. Journ.,' 1890, Trans., p. -i8l.

] 0 Messrs. Brown and Escombe. On the Depletion of the

on water in such a manner as to just immerse that portion of the
endosperm which had been in contact with the embryo.

This method really affords much greater i'aciliiies for outward
diffusion from the endosperm than does Hansteen's plan of fixing the
degermed seeds on small columns of plaster partially immersed in
water, and it is also free from the objection of any possible disturb-
ing influence due to the solubility of the plaster. Moreover, the
mica-raft method is easier of manipulation, and whilst giving per-
haps better facilities for sterilisation, also allows the detection of the
very first appearance of micro-organisms.

The barley used in our experiments was Hordeum vulgare (var.
distichon), derived from two sources. One, with which most of the
work was done, was a well-matured Chilian barley, of the Chevalier
type, the other an English Chevalier barley grown on light land in
Northamptonshire, both samples being well matured and well har-
vested.

It will be convenient in the first place to consider the visible
changes which can be induced in the endosperm when this is com-
pletely deprived of its embryo, and is put under such conditions as
to ensure the speedy removal of any soluble and diffusible products
which may result from any self-digestive processes initiated by any
portion of the endosperm tissue.

Some of our experiments on this point were made in the following
manner : —

The grain was, in the first place, steeped from one to two houra
in a 1 per cent, solution of copper sulphate, and after being
washed with sterilised water was steeped, also in sterilised water, for
a period of from twenty-four to forty- eight hours. From the corns
selected for experiment the palese and embryos were then removed
with antiseptic precautions, this process being conducted in a glass-
fronted sterile operating chamber, furnished with " sleeves." The
degermation was performed with a small scalpel, taking care to
thoroughly remove all traces of the scutellum, and to lay bare the
" depleted layer " of the endosperm.*

The isolated endosperms were then put in position in small holes
made in a very thin mica-raft which was floated on sterilised water
in a Petri's dish, or in a glass vessel of somewhat similar construction.

* The nature and origin of this " depleted layer " can only be understood by fol-
lowing the developmental history of the endosperm and embryo, and this has been
so fully described in Ihe Brown and Morris paper of 1890 (loc. cit.) that it requires-
but a passing notice here. The "depleted layer" is made up of several thicknesses
of cell-membrane, which originally formed part of the amyliferous cells of the
young immature endosperm. During the later stages of development of the grain,,
and some time before maturation, the contents of these cells are used up for the
nutrition of the young embryo, but the cell-membranes persist and become squeezed
together by the gradual encroachment of the scutellum.

Endosperm of Hordeum vulgare during Germination. 11

In those cases where comparisons had to be made between endo-
sperms treated in different ways the mica-rafts were made to carry
twelve corns, the two series of six each being placed on either side of
the raft. In this manner there was an exactly equal chance of the two-
sets being infected to the same extent by extraneous organisms, an
important condition, which often enabled us in a long series of
experiments to differentiate changes due to the influence of organ-
isms from those due to other causes. Latterly we found these
extreme antiseptic precautions unnecessary for the reasons already
given, and we also found it undesirable to previously steep the grain
before degermation, since the embryo may readily begin to func-
tion slightly during the softening process, especially when the
temperature is high. In such cases there is a danger of the projec-
tion of a small quantity of enzymes from the embryo into the
proximal portions of the endosperm, and these enzymes, after de-
germation of the grain and the floating of the endosperms on the
rafts, may give rise to certain changes in the endosperm which may
be \\rongly attributed to a self -digestive power of the endosperm-
cells themselves, whereas they have a different origin altogether.

It is true- that this source of error may be minimised by reducing
the period of steeping, and by keeping the temperature of the water
low ; but it is much more satisfactory to degerm. the grain whilst still
in its dry resting condition, a process which does not present any
difficulty. It must, however, be performed with the aid of a lens, sa
as to ensure the complete removal of the scutellum and the whole of
its limiting epithelial layer.

If endosperms thus treated are soaked in water for from twenty-
four to forty-eight hours, and are then transferred to the perforated
mica- rafts in such a manner as to immerse the whole of the depleted
layer, we observe the following changes to take place.

Within two or three days from the commencement of the experi-
ment the peripheral, tripartite layer of the endosperm, the so-called
" aleurone-layer " (" Kleberschicht "), shows an increasing tendency
to separate from the adjacent amyliferous cells. This is noticeable
in the first instance at the proximal end of the endosperm, on the
dorsal side,* where the " aleurone-layer " is intersected by the
" depleted layer," and whilst it is to some extent traceable for some
distance round the periphery towards the ventral fold, it extends
much more rapidly in a distal direction along the dorsal side.
Where there is this megascopic indication of the separation of the
** aleurone-layer," it is always found that the amyliferous cells,
immediately underlying, f show indications of change. In the first

* The dorsal side is that immediately opposite the ventral suture. The terms
proximal and distal are used with reference to the position of the embryo.

f The outermost layer of ihe amyliferous poi'tion of the endosperm consists of

12 Messrs. Brown and Escombe. On the Depletion of the

place, the cell-contents become hyaline in appearance, owing to the
protoplasmic matrix losing its granularity and acquiring a refrac-
tive power approximating to that of the embedded starch-granules.
Later on these hyaline portions imbibe water and swell up enor-
mously, ultimately becoming very elastic and ductile, and capable of
extension into sticky, stringy masses, very similar in appearance to
the gluten of the wheat-endosperm. We shall in future refer to this
change as " gluteii-forination." At the same time the cell-membrane
•of the peripheral starch-cells swells up considerably, and as the
action progresses the cell-walls undergo disintegration, with all the
indications of cytohydrolysis as described by Brown and Morris.

It is to this cytohydrolysis that the separation of the "aleuroiie-.
layer" is due, and the disintegration due to this cause proceeds
centripetally into the endosperm and extends round the periphery
nearly to the ventral fold, whilst it advances more rapidly in a
distal direction on the dorsal side. The extent to which this cyto-
hydrolysis has proceeded is always evidenced megascopically by the
reduction of the endosperm-contents to a " mealy " consistency, but
even after the lapse of seven or eight days the actual amount of
depletion is small, as long as micro-organisms are absent, or present
only in comparatively small numbers. If, however, as is frequently
the case, masses of Bacteriacece in the zooglcea-state attach them-
selves to the mutilated surface of the endosperm, a very distinct
removal of some of the endosperm-contents may take place.

The erosion of the starch-granules is generally not very pronounced
under these conditions, but when it does occur it always commences
••at the same point as the cytohydrolysis, that is, on the dorsal side,
at the angle of intersection of the " aleurone-layer " and the
''depleted layer," and extends distally just as does the cytohydro -
lyfcic action.

The starch-erosion produced in this manner under the "aleurone-
layer" is, in the main, very different in character from that observed
immediately under the scutellum of a grain germinating normally
with its embryo attached. Whilst in the latter case the action com-
mences by the formation of numerous minute " pits," this pre-
liminary pitting is rarely observable in the eroded granules lying
under the "aleurone-layer," which show the production of large
rifts, and a general concentric dissolution of the various layers. We
shall in future refer to these different modes of attack on the starch-
cells differing in general appearance from the more deeply seated cells. They are
smaller, are packed with far smaller starch-granules, and the proportion of starch -
granules to proteinic contents is less. These peripheral cells constitute the youngest
part of the starchy endosperm, and may be regarded as haying been arrested in
their development by the falling off in the supply of formative material at the
j)criod of maturation.

Endosperm of Hordeum vulgare during Germination. 13

granule as " sub-alenronic " and " sub-scutellar " respectively; for
although occasional instances may occur where one form of attack
merges insensibly into the other, yet, looked at generally, they differ
so much from each other as to suggest that the transforming agents
are essentially different.

The accompanying photographs (Plate 1) illustrate these differ-
ences far better than can any mere description.

It appears to us that the phenomena which are observed when the
endosperms of Hordeum are deprived of their embryos, and are
treated in the manner we have described, must be attributable to one
or more of the following causes : —

1. They may be the result of micro-organisms originating in the
culture-medium, and gradually invading the endosperm- tissues,,
which undergo progressive alteration either by the direct action of
the organisms or in .virtue of their secreted enzymes projected into,
the endosperm.

2. The phenomena may be due to residual enzymes, cjtohydro-
lytic, amylohydrolytic, and proteohydrolytic, left in the endosperm at
the time of maturation and desiccation of the grain.

3. They may be due to the revival of metabolic activity of still
living cells of the endosperm when these are placed under favourable
conditions of moisture and temperature, and facilities are afforded for
the removal of the products of change. If this is the correct solution?
the active cells may be those of (a) the " aleurone-layer," or (6) the
amyliferous portions of the endosperm.

We must now consider these three possibilities in detail.

We have already stated that, no matter how careful we may be in
sterilising the apparatus and culture-medium, the appearance of
micro-organisms is only a question of time, unless we employ anti-
septic methods of so drastic a nature as to seriously imperil the
vitality of the endosperm-tissue, a course which would render it
impossible to get the answer we require as to the respective parts
played by organisms and by autonomous changes in the endosperm-
cells themselves. We can, however, arrive at certain conclusions by
making a large number of experiments and by confining our observa-
tions to the period prior to the appearance of organisms, a period
which, under favourable circumstances, may extend to about eight
days. When this is done we find that the changes originating in the
first place under the "aleurone-layer" of the degermed seeds so far
precede in point of time the appearance and multiplication of the
Bacteriacece- and moulds as to render it in the highest degree improb-
able that the two sets of phenomena are causally related to each
other.

A much more satisfactory proof of the truth of this proposition
may be obtained in an entirely different manner. Endosperms of

14 Messrs. Brown and Escombe. On the Depletion of the

which have been degermed in the dry state are, in the
first place, steeped in a saturated aqueous solution of chloroform
for twenty-four hours. After having freed fche endosperms from
adherent moisture, they are warmed gently for a few hours in a flask
connected with a water-pump, and are then steeped for a further
period of twenty-four hours in I'unning water, every trace of chloro-
form being thus removed. The endosperms are then floated in the
usual manner on a mica-raft, alongside other degermed endosperms
which have been merely steeped in water for forty-eight hours. The
two sets of endosperms are thus under exactly similar conditions as
regards their liability to attack by micro-organisms, and if the
described " sub-aleuronic " changes of the endosperm are due solely
to the direct or indirect influence of extraneous organisms the same
results ought to be given by the two series, whereas, if the vitality of
any portions of the endosperm is a determining factor, evidence of
this ought to be forthcoming, since one set of endosperms has been
under conditions which would completely arrest the vital functions
of any of their component cells.*

When such an experiment is performed we find very considerable
differences between the two sets of endosperms at all stages. Whilst
the series merely steeped in water go through the ordinary cycle
previously described in detail, the series made up of the chloroformed
endosperms show no internal changes for a considerable period of
time. In the latter case the " aleurone-layer," which so speedily
separates under ordinary conditions, retains its unbroken continuity
with the subjacent amyliferous cells, which in their turn preserve
their cell-walls and cell-contents intact. Until the growth of micro-
organisms has progressed to a very considerable extent the endosperm-
contents of the chloroformed grains show no megascopic or micro-
scopic change, except in the direction of a more hyaline appearance
of the contents of the starch -cells, a change which is apparently the
first stage of the "gluten-formation," to which reference was made in
an earlier part of the paper. There is neither cytohydrolysis nor
amylohydrolysis apparent in the tissues until the micro-organisms
which have attached themselves in a zoogloea state to the outside of
the " depleted layer" have attained to a very luxuriant growth, and
even then the tissue-changes differ in some important particulars
from those produced in a "living" endosperm. It is in fact possible,

* In our earlier experiments it was assumed that a treatment with chloroform-
water, sufficient to destroy the vitality of the embryo, would also be sufficient to
kill the aleurone-cells. This, however, is not the case, the embryo being much
more sensitive to the chloroform than the peripheral cells of the endosperm. We
have satisfied ourselves, however, that a twenty-lour hours' steeping of the dry
endosperms in chloroform-water at a temperature not less than 15° C. will perma-
nently destroy the functionating power of all the cells of the grain.

Endosperm of Hordeum vulgare during Germination. 15

"by such comparative experiments, to differentiate with certainty the
modifying action of micro-organisms from the autonomous action of
ihe endosperm-cells themselves.

The action due to extraneous organisms always commences at the
surface of the "depleted layer," the cell-membranes of which this is
made up being softened, swollen, and ultimately disintegrated. This
-cytohydrolytic action then gradually extends to the membranes of
the amyliferous cells, and the proteid contents of the cells are also
involved in the change, which ultimately permeates the whole of the
endosperm.

There is, however, a striking difference between the mode of pro-
gression of this bacterial action from that observed in " living "
•degermed endosperms. In this latter case, as we have already
noted, the action is essentially centripetal, commencing under the
'' aleurone-layer " on the dorsal side, where this layer is intersected
by the " depleted layer," and extending peripherally and axially, but
more rapidly on the dorsal side. In the degermed "dead" endo-
sperms, on the other hand, there is no differential progression of this
kind, since the action, whilst progressing in an axial direction, does
not extend more rapidly along the peripheral than the central parts,
and does not show the slightest tendency to more rapid extension 011
the dorsal side, a tendency which is so strongly marked in "living"
degermed endosperms in water-culture, or in intact grains of barley
undergoing ordinary germination. It is only when the disintegra-
tion of the endosperm-contents under the action of micro-organisms
has proceeded to a very considerable extent that any notable amount
of erosion of the starch-granules is observable. This sometimes does
not occur for many days, a fact probably due to the bacteria not
secreting any special starch-dissolving enzyme as long as they are
well supplied with readily assimilable food material from other
sources.

So far the conclusions are altogether opposed to the view that the
normal phenomena of endosperm solution and depletion, as they
occur in degermed endosperms in water-culture, can be explained by
the action of extraneous micro-organisms. It is true that, under
certain circumstances, the mixed growths of Bacteriacece which attach
themselves to the mutilated surface of the endosperm can induce
changes in the subjacent tissues by the projection into them of
certain enzymes, the products of their growth, but this action can,
with due care, be clearly differentiated from the normal action,
which is of quite a different character, and must be in some way self-
induced by the endosperm-cells themselves.

Before considering how far the normal changes are dependent on
the vitality of any particular portion of the endosperm, we must
inquire if the phenomena are in any way due to enzymes pre-existent

16 Messrs. Brown and Escombc. On the Depletion of the

in the endosperm-cells, and this inquiry is the more necessary since
we know that even the distal portions of the endosperms of the
barley-grain contain a certain amount of a feeble diastase, and in
most cases also a distinct amount of a cytobydrolytic enzyme.*

In the first place we satisfied ourselves that both the amylohydro-
lytic and cytohydrolytic enzymes of barley are not appreciably
weakened in their respective actions by a saturated aqueous solution
of chloroform. f A number of grains of barley were degermed,
and, after being softened by a sufficiently long steep in chloroform-
water, were placed in the usual manner on a mica-raft, which was
floated on water kept fully saturated with chloroform during the whole
of the experiment. Under these conditions bacterial growth was.
quite inhibited, as was also any autonomous action due to the endo-
sperm-cells, but the pre-existent enzymes, on the other hand, were
allowed full play to produce any alterations of which they were
capable.

Not even the feeblest action of any kind could ever be detected
in the endosperm-tissue placed under these conditions, even after
the lapse of several weeks, and we must therefore regard such
experiments as fatal to the view that pre-existent enzymes exercise
any appreciable influence in bringing about the well-marked and
definite changes in the endosperm such as we have described.

We are thus led to what appears to be the only conceivable expla-
nation remaining, — that the phenomena are dependent on the meta-
bolic activity of some portion of the endosperm itself; and if this is
the case, it follows that during normal germination the endosperm is
not wholly passive, but takes some share with the embryo in prepar-
ing the reserve materials for the use of the young plant.

It now remains to ascertain how far it is possible to localise the
particular part of the endosperm-tissue which is active in producing
these changes, an inquiry which resolves itself into an examination
of the respective functions of the '; alenrone-layer " and amyliferous
cells respectively.

The observations of Tangl,^ and more recently those of Haber-
landt, have shown that each of the " aleurone-cells " possesses proto-
plasm with the usual reticulation of fine strands, enclosing a well-
d^fined nucleus, and presenting all the usual cytological evidences
of activity. As far as we are aware, no one who has ever carefully

* ' Chem. Soc. Journ.,' 1890, p. 507 ; ibid., 1892, p. 362.

f These facts were determined by estimating the diastatic and cytohydrolytic
powers respectively of extracts of the grain made under similar conditions, in the
one case with water only, and in the other with a saturated aqueous solution of
chloroform. The determinations of diastatic activity were made by Lintner's method,
and those of the cytohydrolytic by the times necessary to produce visible action on
the cell-membranes of thin sections of the grain immersed in the two liquids.

J ' Sitzungsber. d. Wiener Akad.,' vol. 102, 1885.

Endosperm of Hordeum vulgare during Germination. 17

examined these cells during the germinative period has ever doubted
that they are actually living units.*

The cytological evidence as to the state of the amyliferous cells
is not so clear, and we have been unable to find any record of a
systematic examination of the appearances presented by their proto-
plasmic contents.

The difficulties of examination are, of course, much greater here
than they are in the case of the " aleurone-cells," owing to the
tightly packed starch-grains, which must be removed by some method
incapable of acting on the other cell-contents, which they completely
obscure. The ordinary reagents which are used for this purpose,
such as acids and alkalis, are quite inadmissible, and although much
better results are obtained with cold water extracts of malt, or of
animal pancreas, acting for some time at 40 — 50° C., there are objec-
tions to both of these agents. The malt extract often possesses some
cytohydrolytic power, which acts on the more delicate portions of
the cell-membrane, and destroys the coherence of the tissue, and
even when this objection is removed by previously heating the malt
extract to 60 — 65° C. for some time, malt-proteids are often preci-
pitated iii a finely granular form within the sections, and confuse the
results.

An extract of animal pancreas is a very good solvent, for starch,
but since this possesses slight proteohydrolytic power in feebly acid
solutions, there is a danger of solution of the protoplasmic matrix
along with the starch ; and, moreover, when " liquor pancreaticus "
(Benger) is used, there is considerable precipitation at 40 — 46° C.

No such objections, however, apply to the use of diluted and
filtered mixedf human saliva. With the addition of a little thymol,
to prevent putrefaction, this agent may be allowed to act on the
very thinnest sections of seeds at a temperature of 46° C. (the
optimum temperature for ptyalin) for many hours, without any
change in the sections other than the dissolution of the starch. The
starch-granules dissolve very completely, leaving sharply marked
lacunae in the protoplasm, which can then be stained in any desired
manner.

In staining, we have used a mixture of iodine-green and fuchsine.
With this reagent the nucleus is stained green, and is strongly con-
trasted with the cytoplasm which takes up the red stain.

* Tangl also observed the continuity of the protoplasm in the " aleurone-layer,"
a continuity effected by means of fine threads passing through pores in the thick
walls of contiguous cells. Walter Gardiner (' Koy. Soc. Proc.,' vol. 52, 1897,
p. 100) has confirmed this, and informs us that he has also proved the existence of
continuity in the cytoplasm of the amyliferous cells.

t By this is meant ordinary human saliva, consisting of the mixed secretions of
the three seti of salivary glands,

VOL. Hill, C

18 Messrs. Brown and Escombe. On the Depletion of the

When sections of the starch-bearing portions of the mature
endosperm are thus treated, it is seen that the nucleus is either
extremely deformed, or. indeed, in manv cases even completely dis-
integrated. That these appearances are not in any way due to the
treatment to which the sections have been subjected is clearly shown
by an examination of sections made from the endosperms of barley,
taken from the fields at different stages of development, when starch
is still being actively deposited within the cells. In the early stages
of development the saliva-treatment gives sections in which normal
and well-defined nuclei exist, but as the grain approaches maturity
there is a corresponding senescence of the nucleus, resulting in the
appearances just described.

It is interesting to trace the progress of this nuclear senescence,
which first commences in the more deeply seated and older cells of
the endosperm, gradually extending towards the periphery as the
period of maturation approaches.

Just before complete ripening, the only well-formed nuclei which can
be recognised are those of the last row of starch-bearing cells imme-
diately under the " aleurone-layer." Ultimately, unless some
unfavourable circumstances arise to prevent complete maturation,
these nuclei to a great extent share the fate of those of the more
deeply seated cells, but they are generally deformed to a less
degree.

We shall at a future time have more to say on this question as
regards other seeds and its connection with the particular nature of
the reserve products. The point to which we now particularly wish
to draw attention is that the cytological observations indicate the
existence of a very marked difference between the nuclei of the
" aleurone-cells " and those of the amyliferous cells. There can be
no doubt about the functionating power of the former, whereas it
seems difficult to admit that the starch-bearing cells can exercise
their full powers as living units after complete maturation, although
the destruction of their nuclei may not preclude all possibilities in
this direction.

Nothing short of actual trial, however, can determine whether the
starch-containing cells of the endosperm retain sufficient vitality to
have any action on their own cell-membrane or cell-contents, and,
with this object in view, we have conducted a number of experi-
ments on large fragments of endosperm deprived completely of their
adherent " aleurone-layer " after being steeped for twenty- four hours,
and placed under the usual favourable conditions for the rapid out-
ward diffusion of any products of change. For purposes of com-
parison we also employed other similar fragments which had been
treated with chloroform-water for a sufficiently long period to effec-
tually destroy any residual vitality, the chloroform being removed

Endosperm of Hordeum vulgare during Germination. 19

in the same manner as desct ibed previously when treating of the in-
tact endosperm.

The results were in no sense doubtful. No visible changes of any
kind took place until micro-organisms had established themselves,
when dissolution of the cell-membrane commenced. Moreover,
there was the strictest possible parallelism, at all stages, between
the " dead " and the " living" endospermous fragments, using these
terms to express the state, at the commencement of the experiments,
of those fragments which had or had not been previously put under
conditions for extinguishing any residual vitality which, their cells
possessed. In this respect our later experiments have fully borne
out the statement of one of us in 1890* that the starch-containing
portions of the endosperm are una,ble to originate any visible changes
in the reserves which they contain.

Thus we must conclude that it is to the influence of the "aleurone-
layer," and the " aleurone- layer " only, that we must look for those
well-marked changes which undoubtedly take place in the endo-
sperm when this is separated from its embryo and placed under
favourable conditions.

This is a conclusion differing materially from that of the 1890
paper referred to above, which concludes with the following
passage : " As far as the evidence goes at present, we are certainly
not justified even in suspecting that the cells of the * aleurone-layer '
are glandular in the same sense as are the epithelial cells of the
scutellum, and until evidence of a far more convincing nature is
forthcoming we must adhere to the opinion that the diastase " (and,
we might have added, the cytase also) " accumulated in the germi-
nating seeds of the Grasses owes its origin exclusively to the
secretory glandular cells forming this scutellar epithelium, and that
the aleurone-cells belong solely to the reserve-system of the seed."

This opinion was justified by the known facts of seven years ago,
but certainly requires modification in the light of our more recent
experiments. It seems, in fact, quite impossible to understand the
results of these later experiments, if we deny the power of the
"aleurone-layer" to produce a considerable amount of cytohydro-
lytic action on the cell-membrane, and even a certain amount of
action on the starch itself. The relative share in the modification of
the endosperm-reserves which falls to the scutellum and the
" aleurone-layer " respectively in normal germination we shall con-
sider presently, but it is in the first place necessary to criticise an
important experiment of the 1890 paper, which at the time seemed
absolutely conclusive against the view that the "aleurone-layer"
has any power of modifying the endosperm-contents. Whilst in-
vestigating the best conditions for the development of excised
* Brown and Morris, loc. cit.

20 Messrs. Brown arid Escombe. On the Depletion of the

embryos on artificial nutrients, it was found, as we have already
stated, that it is possible to u graft " the embryo from one grain on
to the endosperm of another, and to obtain such close apposition of
the two surfaces, by means of binding with a loop of thin silver or
platinum wire, that the "graft" develops into a young plant almost
as readily as if it were still nursed by its own endosperm. This fact
afforded an opportunity of more closely studying the relative parts
played by the embryo and endosperm in producing the initial
changes in the reserve materials ; for it is evident that if a clegermed
endosperm is subjected to some process which will with certainty
kill its tissue, and a living embryo " grafted " on this endosperm
will bring about in the reserve substances of the latter all the
changes incidental to normal germination, then the whole idea of
residual vitality in the endosperm-cells being a necessary condition
of germination would become superfluous. Experiments in this
direction were in the first place made by treating grains of barley
with chloroform- vapour for twenty-four hours, a course of treatment
Avhich we now know must have been insufficient to have killed the
resting protoplasts ; it is, therefore, not to be wondered at that
embryos " grafted " on endosperms so treated should have grown
perfectly. In a further set of experiments, also described in the
1890 paper, grains of barley were soaked in absolute alcohol for six
months, and after drying off the alcohol, soaking well in water,
and degerming, fresh embryos applied to the endosperms were
found to produce in them all the ordinary visible signs which
accompany germination. This experiment was deemed to con-
clusively prove that the degradation of the reserve products is con-
ditioned by the embryo itself, and that the endosperm-cells do not
take part in it.

We have now, however, every reason to believe that the " aleu-
rone-layer " was not killed by this drastic treatment with alcohol,
for we have found that these cells are much more resistant to in-
jurious influences than the tissue of the embryo itself, and we have
seen cases in which even the embryo will sprout after the grain has
been immersed in alcohol for about four months.*

We have recently found, in repeating and varying these experi-
ments, that when the grain is immersed in a dry state in chloroform-
water (i.e., a saturated aqueous solution) a few hours suffice to

* Giglioli (' Nature,' Tol. 52, 1895, p. 541) found that seeds of Medicago sativa
retained their vitality after submersion in absolute alcohol for more than sixteen
years. Ewart ('Liverpool Biolog. Soc. Trans.,' vol. 8, 1894, p. 207) also states that
the resistance of seeds to absolute alcohol is very considerable, and that those of
Hordeum, although killed very quickly by alcohol of 50 per cent., require submersion
in absolute alcohol for seven weeks before all germinating power is lost. It will be
seen, from what has been said above in the text, that the embryos of some grains of
Hordeum may be made to grow after a much longer submersion than this.

Endosperm of Hordeurn vulgare during Germination. 21

destroy the vitality of the germ, but that at least twenty-four hours'
immersion is required to permanently destroy the vitality of the
" aleurone-layer," and that if this is not perfectly effected, subse-
quent " grafting " experiments may suggest entirely erroneous con-
clusions.

In the following remarks we shall refer to those endosperms which
have been thus treated with chloroform -water as "dead," whilst
those which have been merely soaked in water after degermation
we shall regard as " living."

When "graftings " of embryos are made on living and dead endo-
sperms respectively, and these are placed under favourable conditions
for germination, very strongly marked differences are observable within
a few days, both in the rapidity of growth and general appearance
of the two sets of embryos, and in the nature and extent of the
concurrent changes in the endosperms.

On the " living " endosperm the axial organs of the young
plant develop freely, healthy rootlets are protruded, and the freely
growing plumula has all the appearances of turgidity and firmness
incidental to good nutrition. Simultaneously with this development
cytohydrolysis commences under the " aleurone-layer," and, whilst
attacking the " depleted layer," progresses peripherally and distally
along the usual path in the endosperm. At the same time a distinct
and sometimes considerable amount of starch-erosion is noticeable
in the amyliferous cells immediately in contact with the " aleurone-
layer " of the proximal end of the grain, but this is entirely of a
" sub-aleuronic '' type (see antea), whilst the starch -erosion which
has taken place immediately under the scutellum of the " grafted "
embryo is wholly of the " pitted " or " sub-scutellar " type.

The phenomena presented by the "grafting" on the "dead"
endosperms are, on the other hand, of a very different character.
Here the embryo is evidently under much less favourable conditions
for healthy growth, since the young plant is much smaller, the
tissues of its axial organs are flaccid, and there is very poor root-
development. At the same time it is also clear that the embryo is
deriving some nutriment from the dead endosperm and is increasing
in weight, a fact which can readily be proved by a comparison with
the development of excised embryos in water- culture on a porous tile.

The internal changes which the dead endosperm itself undergoes
when in contact with the living embryo are very instructive, and a
careful study of them enables us, with certainty, to distinguish and
delimit the autonomous changes of the endosperm from those induced
by the embryo itself. Even after eight or ten days the dead endo-
sperms under these conditions exhibit no softening or cytohvdrolvsis
of the tissues immediately underlying the " aleurone-lajer," and
this layer remains firmly attached to the subjacent amyliferous cells.

22 Messrs. Brown and Escombe. On the Depletion of the

We can in this case only detect a small amount of disintegration
immediately under the " grafted " embryo, and even after eight or
ten days this is not found to proceed for more than 0'5 to 1 mm. from
the " depleted layer." There is a partial but very incomplete cyto-
hydrolysis of the cell-membranes constituting the " depleted layer,"
and a similar imperfect action can be traced microscopically in the
amyliferous cells as far as the disintegration has proceeded. The
starch-grains of the amyliferous cells immediately underlying the
" depleted layer " show unmistakable signs of attack by normal sub-
scutellar u pitting " without any admixture of that particular form of
erosion which is characteristic of the action of the " aleurone-layer."

There can be no doubt that we here have further proof that the
embryo, by means of the secretion of enzymes from its scutellar
epithelium, is able to attack starch, and to assimilate the products of
its hydrolysis. Abundant proof of this fact was brought forward in
the 1890 paper, in which were described many experiments on the
artificial nutrition of excised embryos, and this fact has been amply
confirmed by Griiss in a series of very careful experiments he has
recently described.*

It will be remembered that when embryos were cultivated on
gelatine in which starch-granules had been suspended, it was found
that a secretion of diastatic enzyme took place from the epithelial
cells of the scutellum, which manifested itself by erosion of the
starch, and that this erosion gradually extended to a relatively con-
siderable depth in the gelatine medium. That this action does not
proceed with the same rapidity in " dead " endosperms, on which
embryos have been grafted, is due to a great extent to the fact that
in this latter case the starch-grains are locked up in cell-membranes
which retard the diffusion of the highly colloidal diastase. Until
these cell-membranes are broken down we have not the most favour-
able conditions for a rapid formation of soluble nutriment from the
reserve materials, especially as the amyliferous cells appear to be
devoid of any power of initiating such changes autonomously. One
of us was originally of the opiuionf that the necessary cytohydrolytic
function resided in the embryo itself, and that it was manifested by
the same epithelial cells as those which produce a very active form
of diastase, but our more recent experiments have clearly shown that
this power of the embryo was much overrated, and that the greater
part of the cytohydrolytic process preliminary to the amylohydro-
lytic is due to the cells of the " aleurone-layer," the treatment to
which the grain was subjected in 1890 not having been sufficient to
completely destroy the vitality of these cells.

This layer is the only part of the endosperm which can be recog-

* ' Pring8heim's Jahrb.,' vol. 30, 1897, p. 645.
f Loc. cit., 1890.

Endosperm of Hordeum vulgare during Germination. 2;\

nised as taking part in the preparation of the food-material for the
embryo, since no evidence can be obtained of any changes being
initiated by the starch-containing cells themselves ; in fact, the
highly disintegrated appearance of the nuclei of these cells would in
itself suggest they had ceased to function.

If we were to limit ourselves to the observations on degermed
endosperms in water-culture, we should conclude that the diastatic
function of the "aleurone-layer " is very small indeed, and this is
also apparently confirmed by the impossibility of demonstrating the
existence of such a function in the " aleurone-layer" when we employ
the methods which have been so successful in this direction in the
case of preparations of the scutellum.

When the integuments with tho " aleurone-layer " attached are
perfectly freed from the starch-containing cells, and are placed face
downwards on starch-gelatine, we have never been able to obtain
any evidence of action.- on the starch, and even when the preparation
was made so as to include a layer of the amyliferous cells, which were
kept moist on gelatine, no influence was exerted on the contained
starch. Under these circumstances, however, there is an entire
absence of cytohydrolytic as well as of amylohydrolytic action, and
since the former is so well marked in degermed endosperms in
water-culture, we can only conclude that the separated " aleurone-
layer" for some reason or other will not exercise its normal function
in the same manner as the scutellar epithelium placed under similar
conditions.

It is also to be remembered that in those cases where the endo-
sperm is in actual contact with the embryo, either as in natural
germination, or as in the " grafting " experiments, the special
changes induced by the "alenronic" layer proceed much more
rapidly than in isolated endosperms in water-culture, and this accele-
rated action is much more evident in the case of the diastatic than
of the cytohydrolytic action,

It would appear, therefore, that although one of the principal func-
tions of the " aleurone-cells " is to break down the cell-membrane of
the amyliferous endosperm, these cells also share with the scutellum
the power of eroding starch-granules.

Owing to the different method of attack on the starch, it now
becomes possible, for the first time, to discriminate one form of action
from the other, but it is very difficult to apportion the part played by
scutellum and " aleurone-layer " respectively, for the amount of
action of either depends not only on the enzymic intensity for
equal areas of the two tissues, but also on the total areas facing
the endosperm-contents in each case.

Since the total area of the " aleurone-layer " is considerably
greater than that of the scutellar epithelium, the influence of the

24 Depletion of Endosperm of Hordeum vulgare.

former may be as great or even greater than that of the scutellum
in the early stages of germination, even if its specific enzymic in-
tensity is very much less.

There is another probable function of the " aleurone-layer " which
may indirectly be of great value to the seed. These cells, which
undoubtedly contain living elements, constitute the outermost peri-
pheral layer of an otherwise dead endosperm, which, were it not for
this protective sheathing of living cells, would be much more liable
to the attacks of any of the micro-organisms of the soil which suc-
ceeded in penetrating the seed-envelopes. It is a noteworthy fact
that the " aleuronic " cells are much more fully developed over
those parts of the seed which may be regarded as devoid of life, and
become very much more attenuated where they come into proximity
with the embryo whose cells, owing to their activity, do not require
an equal amount of protection. In the case of barley the threefold
layer of " aleurone-cells " lying within the pericarp and testa con-
stitutes a triple line of defence, which must be of some value in
protecting the amyliferous cells against the hordes of external
organisms when the grain is placed under the natural conditions
suitable for germination.

We must express our great thanks to Mr. W. T. Thiselton Dyer
and Dr. D. H. Scott for the opportunities they have afforded us for
carrying out this research at the Jodrell Laboratory.

Addendum.

Since writing the above we have for the first time seen the full
and expanded account which Puriewitsch has given of his work in
Pringsheim's « Jahrbuch,' vol. 31, 1897, p. 1.

His observations on the self-depletion of the endosperm of the
Graminece take account only of the erosion and dissolution of the
reserve starch. He does not call attention to the equally im-
portant and necessary antecedent phenomena of cytohydrolysis,
which admit of a determination of the " aleuronic " or peripheral
origin of the autonomous changes and their mode of progression in
the endosperm. Puriewitsch, in fact, regards every cell of the
endosperm as capable of functioning as a depletive agent, whereas
our own work points strongly to the conclusion that when an endo-
sperm is deprived of its embryo the subsequent chemical changes
within it are initiated by the " aleurone-layer " only.

It is correctly stated that such action commences near the scutellar
surface, and extends peripherally under the " aleurone-layer " ; but
the author explains this by the observations of Brown and Morris,
and Griiss,* that the proximal half of the endosperm contains more

* The recent experiments of Griiss iu this direction were made on maize, not or»
barley,

BROWN AND ESTOMHK.

ROY. Soc. PROP., VOL. 03, PLATK 1

Fia. 1.

FIG. 2.

• Fia. 3.

Proceedings and List of Papers read. 25

diastase than the distal. This cannot be the true explanation, since
we find that the pre-existent enzymes of the endosperm practically
play no part in the self-depletion.

DESCRIPTION OF PLATE 1.

FlG. 1. — Examples of " sub-scutellar " starch- erosion, showing incipient and
advanced forms. Two granules, the one in the centre of the field, the
other on the right, show incipient " sub-aleuronic " erosion.

FIG. 2. — Examples of " sub-aleuronic " starch-erosion in incipient stages.

FIG. 3. — Examples of "sub-aleuronic" starch-erosion in more advanced stages.

(For the production of these photographs we are indebted to Mr. Albert Norman.)

March 10, 1898.

Sir JOHN EVANS, K.C.B., D.C.L., LL.D., Treasurer, in the Chair.
The following Papers were read : —

I. " On the Rotation of Plane of Polarisation of Electric Waves by
a Twisted Structure." By Professor J. C. BOSE. Commu-
nicated by LORD RAYLEIGH, F.R.S.

II. " On the Production of a " Dark Cross " in the Field of Electro-
magnetic Radiation." By Professor J. C. BOSE. Communi-
cated by LORD RAYLEIGH, F.R.S.

III. "An Extension of Maxwell's Electro-magnetic Theory of Light

to include Dispersion, Metallic Reflection, and allied Pheno-
mena." By EDWIN EUSER, A.R.C.S. Communicated by
Captain ABNEY, F.R.S.

IV. " On the Relative Retardation between the Components of a

Stream of Light produced by the Passage of the Stream
through a Crystalline Plate cut in any Direction with
respect to the Faces of the Crystal." By JAMES WALKER,
M.A. Communicated by Professor CLIFTON, F.R.S.

V. " On the Relation between the Diurnal Range of Magnetic
Declination and Horizontal Force and the Period of Solar
Spot Frequency." By W. ELLIS, F.R.S.

VOL. LXIII.

26 Mr. T. Preston. On the Modifications of the Spectra of Iron

" On the Modifications of the Spectra of Iron and other
Substances radiating in a strong Magnetic Field." By
THOMAS PRESTON, M.A. Communicated by Professor GEO.
FRANCIS FITZGERALD, F.R.S. Received January 11, —
Read January 20, 1898.

Soon after Professor Zeeman announced his important discovery
that the spectral lines become sensibly'altered in appearance and con-
stitution when the source of light is placed in a strong magnetic field,
I determined to examine if the spectra of different substances are
equally or similarly affected, and also if the various lines in the
spectrum of a single substance are equally or differently affected by
the action of the magnetic field. The investigation of these matters
was undertaken also with the ulterior object of determining if the
phenomenon, for the discovery of which we have to thank Professor
Zeeman, could be made to afford any new information, concerning
the corresponding sets of lines in homologous spectra or in the
spectra of substances belonging to the same group of chemical
elements — in fact, to determine if any new information could be
gleaned concerning those atomic or molecular vibrations which give
rise to the light emitted by incandescent matter, and thence to
approach more closely to a knowledge of the ultimate constitution of
atomic and molecular structures.

For the purpose of this inquiry I availed myself gladly of the
opportunity afforded me of using the excellent Rowland's concave
grating mounted in the physical laboratory of the Royal University
of Ireland. This instrument is of the usual type, having a radius of
21'5 feet, and ruled with about 14,438 lines to the inch. It is fitted
with a camera box which takes a photographic plate 20 inches long and
2J inches broad, so that a length of the spectrum equal to 19 inches
can be photographed at a single exposure. As a consequence I
naturally decided to study the effect of the magnetic field on the
spectral lines by photography, rather than by eye observation, for the
latter, besides being applicable to the visible part alone, is more
liable to lend itself to the personal bias or the previously formed
opinions of the observer. The photographic plate, on the other
hand, does not lend itself to the imagination of the observer, but
gives a faithful record of the phenomena as they actually exist in
the image focussed upon it ; besides it enables one to compare the
effects produced on a large number of lines under identical circum-
stances, a point of great importance.

In the case of a phenomenon which exhibits itself as a very small
effect, and one which it is difficult to obtain and observe, it is natural

and other Substances radiating in a strong Magnetic Field. 27

that some doubt should exist at first as to what it is that actually is
presented to the observer ; and that discrepancies should occur in the
statements of different observers regarding the phenomenon now
under consideration is not surprising. Thus while Zeeman dis-
tinctly states that he obtained a tripling of the spectral lines when
the source of light is viewed across the lines of magnetic force, and
a doubling when it is viewed along the lines of force; yet these
effects were obtained only after the theory of the phenomena pointed
in this direction, and other reliable observers investigating the same
lines have given expression to the opinion that when viewed across
the lines of force a doubling (like a reversal) or a broadening com-
bined with a doubling occurred. So far as I am aware most
observers have failed to obtain distinct triplets when the light is
viewed across the lines of force, that is, they have not succeeded in
separating the constituents sufficiently to enable them to decide what
the exact composition of the modified spectral line is. By placing a
nicol's prism in the path of the light it has been determined that
the central part of the modified line is plane polarised, and that the
edges are also plane polarised, but in a plane at right angles to the
plane of polarisation of the middle part. Thus with the nicol in one
position the middle may be cut out, leaving the two border lines, and
with the nicol turned through a right angle the two border lines may
be removed, leaving the middle portion alone. It is to be remarked,,
however, that observations of this nature, although they are in
accordance with the supposition that the modified line is a triplet,
yet they do not absolutely prove tripling pure and simple. For this
purpose it is necessary to obtain a magnetic field strong enough to
separate completely the constituent parts of the modified line, so that
each can be observed separately, without the complications attending
the overlapping of the others.

By way of illustration and explanation of the foregoing remarks it
should be mentioned here that the observations which I have made
in a general survey of the spectra of several substances indicate the
existence of four types of effect,* which, although they easily har-
monise as particular cases of one 'general type of effect, yet deserve
to be noted, inasmuch as they are the results actually presented to
observation. Thus when the source of light is viewed across the
lines of magnetic force some of the spectral lines are resolved into
sharp triplets, in which the constituent lines are distinctly separated
by clear spaces on the photographic plate. In these the middle line
of the triplet is stronger than the side lines, and agrees with the
expectation that it should contain as much light as the two side lines
combined. On the other hand, some lines are not resolved inta

* These matters are treated in fuller detail in a paper communicated to the
Eoyal Dublin Society in December, 1896.

1) 2

28 Mr. T. Preston. On the Modifications of the Spectra of Iron

distinct triplets, but into what one may provisionally term " quartets."
In these the two side lines contain nearly all the light, while the two
middle lines are weak, but still very distinctly marked. It may be
that these arise from a partial reversal of the middle line of the
triplet, and that they would consequently show as triplets but for
such reversal. The middle line, of course, is the one which would
naturally suffer reversal in the layers of colder vapour, as it belongs
to the period of vibration which is uninfluenced by the magnetic
field — yet the appearance of the weak middle pair is not that which
one usually observes in the cases of reversal, nor in any case do the
photographs of the line free from the magnetic field show any sign
of reversal.

It is interesting to notice in passing that the lines to which
attention has been chiefly directed by other observers, namely, the
D godium lines and the blue line of cadmium of wave-length 4800,
belong to this latter class, and no doubt the difficulty of deciding as to
what really takes place, and the difference of opinion which has existed
are to be attributed to this cause. These lines do not resolve themselves
into sharp triplets, and if one wishes to observe a distinct and well-
defined triplet the violet line of cadmium 4678 or the violet line of zinc
4680 should be chosen. Further, some lines show as doublets, or,
if we wish to state it so, as triplets from which the middle line has
completely disappeared — the source of light being still viewed across
the lines of force. Whether this is due to complete absorption of the
middle line in the outside vapour of the spark, or not, remains for
further investigation. The observation of it, however, led me to the
subject of this communication, namely, the investigation of the
spectrum of iron. Finally, there are spectral lines which are only
slightly broadened, and others which are scarcely affected by the
magnetic field, even when this is strong enough to resolve other lines
of the same substance into triplets, of which the side lines are more
than half a millimetre apart, and visibly resolved on the photographic
plate to the naked eye.

Viewed from the theoretical standpoint, we have no reason to
demand that all, or indeed necessarily any, of the spectral lines
should be resolved into sharp triplets when the source of light is
viewed across the. lines of magnetic force. For, in order that a
spectral line should exhibit itself as a characteristic triplet under
the influence of the magnetic field, it is necessary that the freedom
of vibration should be equal in all directions, and in this case the
intensity of each rectangular component will be the same. Hence
the middle line of the triplet will contain as much light as the two
side lines taken together. . If, however, the vibrations are not equally
free in all directions the foregoing result will not hold, and it
becomes possible to have a triplet with a weak middle line or with-

and other Substances radiating in a strong Magnetic Field. 29

out a middle line, in which case it shows as a doublet. For example,
if the vibration is restricted to one plane, and if this plane sets itself
at right angles to the lines of magnetic force under the influence of
the magnetic field, then the component of the vibration in the direc-
tion of the lines of force will be zero, and the middle line will vanish
from the triplet. If, on the other hand, the whole vibration should
set itself parallel to the lines of force, then the side lines of the
triplet would vanish, or, in other words, the spectral line would be
unaffected by the magnetic field. It is clear, therefore, that the
study of the way in which the spectral lines are affected by the mag-
netic field is likely to throw light on the character of the molecular
vibrations.

The substance which one would expect to present peculiarities in
this way is iron, which, if it retains any of its magnetic properties at
the high temperature of spark produced between the terminals of
an induction coil, should exhibit some characteristic behaviour in the
magnetic field. I was led to expect, indeed, that many, if not all, of
the iron lines would be resolved into doublets rather than triplets
when the spark is viewed across the field. I found it no easy matter,
however, with the magnetic field at my disposal to resolve the iron
lines into anything ; in the first place, because the effect is much
smaller (about one-half) for iron than for the 4678 line of cadmium
or zinc, and, in the second place, because it is not possible to work
with the pole pieces of the magnet so close together when the spark
is passed from a solution of a salt as when it is passed between small
metal electrodes. But in the case of a highly magnetic substance
like iron the metal becomes almost unmanageable in a powerful mag-
netic field, and so it happened that in my first attempts I was not
successful in resolving the iron lines into either doublets or triplets ;
yet even at this stage I observed two or three lines converted into
what I considered doublets. Finally, I succeeded in resolving the
vast majority of the lines of iron by enclosing pieces of iron wire in
small glass tubes so that the ends of the wire protruded slightly from
the glass where the spark occurred. The pole pieces were then
pushed up to touch the glass jackets, and the spark was thus obtained
in a very strong field, in fact in a field strong enough to resolve the
majority of the iron lines into distinct triplets, showing that these
vibrations possess freedom in the magnetic field (at the temperature
of the spark) ; but, in addition to this, other lines are observed as
distinct doublets, and the appearance of these doublets is not that
usually associated with a reversal. In addition there are other lines
in the spectrum of iron which are scarcely affected, if at all.

It is important to remark that these differences of effect by the
same magnetic field on the different lines of the spectrum of the same
substance are not shown in any particular ascending or descending

30 On the Spectra of Iron, $•£., radiating in a Magnetic Field.

order in the spectrum. They may all exist in a single group of lines
of nearly the same wave-length, and the magnitude of effect, even in
the case of the lines which triple, cannot at present be stated to
follow any law. Such a law, if one exists, can be discovered only by
a complete survey of the spectra of various substances with a very
powerful magnetic field capable of wide limits of variation. Such a
field I hope to possess in an electromagnet which is being built for
the purposes of further inquiry in this direction.

In the meantime it may be taken as thoroughly determined that it
is untrue to assume that there is any such law as that the effect is
uniform for the various spectral lines of any substance, or that the
effect varies as the wave-length or as the square of the wave-length.
No doubt it may be possible in the future to divide the spectral
lines into groups such that the members of each group are similarly
affected ; and it may be that a certain homology may be found to
exist between tLe groups of one substance and those of other sub-
stances, and hence the effect produced by the magnetic field may be
brought into line with those chemical and physical properties of the
elements which have already thrown them into periodic groups.

I am at present very hopeful that some law will be obtained in
this department for the phenomena attending the action of a mag-
netic field on the radiation from a source placed in it, for the results
which I have already obtained show certain correspondences in the
effects produced on the spectra of allied elements as well as certain
recurrences of the same effect in the spectrum of the same substance.

The amount of ground so far covered has not, however, been suffi-
cient, nor indeed has my magnetic field been sufficiently strong, to
enable me to lay hold of any general principle controlling the
observed effects ; nevertheless a useful purpose will be served in pub-
lishing this preliminary statement, as it will, at least to some extent,
clear the ground for those who are at present considering the pheno-
mena from a purely theoretical standpoint, and it may also to some
extent serve a perhaps equally useful purpose in diverting a useless
expenditure of energy on the part of those who may be engaged in
formulating the laws of the phenomena without sufficient knowledge
of the facts.

In conclusion I may mention that the spectral lines of air and
hydrogen are rendered diffuse by the action of the magnetic field.
The broadening here is not of the character exhibited by spectral
lines of metals in which the lines remain sharp though easily broadened,
but it is more of the character of a broadening produced by increase
of pressure of the gas.

I may also add that the magnetic effect does not appear to be in
any way parallel with the pressure effect, that is, the displacement of
the lines caused by increase of pressure in the gas surrounding the

Light Vibrations in a Magnetic Field. 31

source of light, which has been recently investigated by Messrs.
Humphreys and Mohler.

The photographs referred to in this communication were taken
with a spark source of light placed between the pole pieces of a good
electromagnet of the ordinary U-shape, for the use of which I am
indebted to the kindness of the Bight Rev. Monsignor Molloy. With
this magnet I was able to obtain a field of about 25,000 C.Gr.S. units,
and this separated the side lines of the triplets in the violet line 4678
of cadmium to a distance of 0*56 mm. apart. The same separation
takes place in the triplet given by the violet line 4680 of zinc, so
that in the case of these lines we may infer in round oumbers that a
magnetic field of 20,000 C.G.S. units strength produces a difference
of wave-length of one Angstrom unit between the side lines of the
triplet, i.e., a separation equal to one-sixth the difference of wave-
length between the two D lines of sodium. For iron the separation
is about half this amount in the case of several lines.

"Note on the Connection between the Faraday Rotation of
Plane of Polarisation and the Zeeman Change of Frequency
of Light Vibrations in a Magnetic Field." By GEO. FRAS.
FITZGERALD, F.R.S., F.T.C.D. Received March 2, 1898.

(Being Notes of a Contribution to the Discussion of Mr. Preston's Paper above,
read January 20, 1898.)

The rotation of the plane of polarisation of light in a magnetic
field is due to the velocity of propagation of light circularly
polarised in one direction being different from that of light circu-
larly polarised in the opposite direction. The Zeeman effect is due
to a difference in the frequency of vibration of these circularly
polarised waves. What is required is to connect the frequency of
vibration with the velocity of propagation.*

All modern theories of dispersion connect these two quantities.
The velocity of propagation of light in transparent media is now
universally considered to be determined in part by what may be

* From an abstract of a paper by M. Becquerel, in the ' Comptes Rendus ' of
last year, I understand him to view the Faraday effect as due to a carrying round
of the light vibrations by matter rotations. This is quite in accordance with the
view sometimes held as to refraction, namely, that it is due to the waves being pro-
pagated through the molecules more slowly than through the ether. The dynamical
theory of these views is difficult on account of the smallness of the molecules
in comparison with the length of the waves. M. Becquerel's view, as I under-
stand it, makes the Faraday effect depend on a change of frequency of rotation of
the waves in matter rather than on their velocity of propagation, and is conse-
quently quite at variance both with the commonly received theory and with the one
put forward in this note.

32 Prof. G. F. FitzGerald.

called the syntony of the matter and light vibrations, and is conse-
quently dependent on the frequency of the matter vibrations. In
most substances the dispersion is controlled within the visible
spectrum by a great absorption band in the ultra-violet, this band
representing a possible frequency of vibration of the molecules, i.e., of
that part of the molecules which affects the ether, be it electrons or
something which simulates the actions ascribed to electrons. If
owing to any cause this absorption band be changed in position, i.e.,.
the frequency of the molecular vibrations be altered, the dispersion
of the medium will be changed, and with it the velocity of propaga-
tion of light within the visible spectrum. Now Zeeman has shown
that in a magnetic field the frequency of vibration of molecules
producing light circularly polarised in one direction is different from
that of molecules producing light circularly polarised in the opposite
direction, and that consequently the absorption bands for molecules
in a magnetic field for oppositely circularly polarised waves will
differ. Hence we conclude that the velocity of propagation of
oppositely polarised waves within the visible spectrum will differ,
and that is the Faraday effect. Hence these two phenomena are
directly connected with one another, independently of any other than
general dispersion theory, i.e., independently of any theory of
electrons, such as Lorentz has shown will explain the Zeeman
effect. If we introduce such a theory, and use it to explain the
Faraday effect upon the lines now laid down, we arrive at the inter-
esting conclusion that before the Zeeman effect was observed the
Faraday effect would have shown that in the majority of substances
we must assume the ether vibrations to be due to the motion of a
negative electron. In substances with a negative Faraday effect,
such as some magnetic bodies, we may conclude either (a) the ether
vibrations are due to a positive electron, or (fr) the absorption band
controlling the dispersion is in the ultra-red, or (c) the cause of the
Faraday effect may be due rather to a difference of intensity of the
absorption band for oppositely circularly polarised vibrations than
to a difference of frequency. This latter alternative is in some ways
the most consonant with the usual theory as to the difference
between paramagnetic and diamagnetic bodies.

If we proceed to calculate what amount of Faraday effect might
be expected from the observed value of the Zeeman effect, we are
met by the difficulty of obtaining data. "We require to know, for
some one or more substances, the amount of the Zeeman effect, the
amount of the Faraday effect, and the ordinary dispersion of the
substance for light. The only gas (and it is only in gases that the
Zeeman effect has been observed) for which the dispersion and
Faraday effect are well ascertained, is air, and for it the amount of
the Zeeman effect has not been published. In preparation, however,

Light Vibrations in a Magnetic Field. 33

for the data, it may be interesting to write down shortly the equa-
tions which, upon Lorentz's theory as to the cause of the Zeeman
effect and Larmor's theory as to dispersion, we may expect to
hold.*

Assuming, then, that the electric displacement in the medium is
partly due to the electric force and partly to the displacement oC
electrons, we may write for its components in the wave face sup-
posed plane and perpendicular to z = 0,

/=KP+«B, £ = KQ + ey,

where P, Q are electric force, e the electron, and a', y are coordinates
that measure the displacement of this latter. From these and the
usual equations connecting magnetic and electric force we get for the
medium

For the motion of the matter, if m be the mass of whatever moves
with the electron, matter or effective inertia of ether, and H be the
component of the magnetic force normal to the wave, and k the
coefficient of restitution of the matter displacement which controls
its free period,

mx + kx = eP + eHy, my + ky = eQ — eHx.

It is to be observed that if we assume the motion periodic these
equations can be reduced to the form that Drudef and Leathern^
have shown to lead to results that agree with the observations on
the effects of magnetised media on the transmission and reflection of
light.

If we substitute in these equations what obviously solves them,
the equations of a right- or left-handed circularly polarised wave of
frequency n = pJ2irt and wave-length X = 2r/j, and whose amplitude
in x and y is a, and in P and Q is A, we get

a(mp2±eH .p— Jc)+eA. = 0.

If we substitute for k — mpQz, where p0 is a measure of the fre-
quency of the free period corresponding to the forces kx, ky which
have been assumed above to control the motion of the electron, we
get for the velocity of propagation p/q = V,

and

A in (p*— p0~)±eILp

* Larmor, * Phil. Trans.,' A, 1897.
f ' Wied. Ann.,' 1896.
j ' Phil. Trans.,' A, 1897.

34 Light Vibrations in a Magnetic Field.

These enable us to calculate the dispersion of the substance in terms
of the difference of velocity of propagation of waves of oppositely
circularly polarised light.

To get approximate formulae in terms of quantities that can be
observed, we have the refractive index /* = V0/Y, when V0 is the
velocity in vacuo and p = 2:rY/X. Assuming that \Q/\ is small, i.e.,
that the dispersion is due to an absorption band far up in the ultra-
violet, we get, writing p for e/m,

4 * H

The second term on the right-hand side of this equation gives the
ordinary dispersion, while the third term gives the Faraday rotation.
The first term /i0 is given by

and is, as Mr. Larmor has pointed out, composed of two parts, the
first being essentially refraction and the second dispersion.

In the case of air, it is possible to compare this equation roughly
with observation. The equation is of the form

We may estimate a from the dispersion in air, and it is approxi-
mately 1-8 x 10-14.

The equation gives for the two absorption bands that exist instead
of jp =j30,

p*—pi = ppi - H, p<?—pS = ppz • H,

.*. pz — PI = p . H.
So that, if 8p be the difference of frequency for unit magnetic force,

Hence, for the difference of refractive index of two circularly
polarised rays, we have

a pH a Sp0 TT
X * ^V = X ' "

Assuming, what is certainly not accurately true, that p is the same
for all lines, and taking that Mr. Preston's estimate for some lines of
Zn applies to oxygen, namely, that 1 A.U. change of wave-length is
produced by a field of 20,000 C.G.S. units of magnetic force, we get—

On artificial temporary Colour-blindness. 35

The observed rotation in oxygen gives a value for this of
3'5 x 10~u, so that it is about equal to the calculated value.

The discrepancy may be due to the fact that p is not the
same for all spectral lines, and we could not reasonably expect to
get an accurate result by assuming that the Zeeman effect in zinc
can be nsed in calculating the Faraday effect in oxygen. On the
whole I think the calculation shows that what must be a vera causa
for a Faraday effect is the whole cause of it. From the mere fact
that rotatory pola.risation is approximately inversely as the square of
the wave-length and consequently vanishes for long waves, it follows
that it is essentially a dispersion phenomenon.

" On artificial temporary Colour-blindness, with an Examination
of the Colour Sensations of 109 Persons." By GEORGE J.
BURGH, M.A. Communicated by Professor GOTCH, F.R.S.
Received February 5,— Read February 17, 1898.

(Abstract.)

By exposing the eye for a sufficient length of time to bright
sunlight in the focus of a burning glass behind suitably chosen
transparent screens, it is possible to induce over the whole retina a
condition of temporary colour-blindness.

After red light the observer is for some minutes completely red-
blind, so that scarlet geraniums appear black and roses blue, while
yellow flowers seem various shades of green, and purple flowers look
violet. The same mistakes are made in sorting Holmgren's wools as
by the red-blind.

Temporary violet blindness may be brought about by using a tank
of ammonio-sulphate of copper. While it lasts, violet wools look
black and purple flowers crimson, but the green foliage appears of a
richer tint than usual. The recovery from violet blindness is very
slow.

Green blindness may be brought about by exposing the eye to
light through three thicknesses of green glass. The colour-scheme
of the landscape during this condition is that of a picture painted
with vermilion, flake-white, and ultramarine, variously blended.

Purple blindness may be produced by a combination of films
stained with magenta and aniline violet, by which the green is
absorbed. During purple blindness the vision is practically mono-
chromatic, no colour being visible but green.

If one eye is rendered purple-blind and the other green-blind, the
observer sees all objects in their natural colours but with a curiously
exaggerated perspective due to the difficulty of combining the
images perceived by one eye with those visible to the other.

36 Mr. G. J. Burch.

General Appearance of the Spectrum during Temporary Colour
Blindness.

A large spectroscope, in which only about a tenth part of the
spectrum is visible at once, is directed to the sun, and the slit opened
till the illumination is as intense as can be borne. After the eye has
been sufficiently fatigued the results are observed in a single-prism
spectroscope in which the entire speotrum is visible.

The following parts of the spectrum, namely, the red from A to B,
the green from the neighbourhood of E, the blue about half-way
between F and Gr, and the violet at and beyond H, produce well-
defined and characteristic results, whereas the intermediate portions
of the spectrum produce results intermediate in character.

That is to say, while exposure to red light causes changes affecting
the red, and exposure to green light produces corresponding changes
in the green, yellow light, instead of causing corresponding changes
in the yellow, affects the whole of the red and the whole of the
green, the total change being equal to the sum of the changes due to
excitation by red light and by green light separately.

The effects produced by each of the four above-mentioned colours
differ in degree but not in kind.

(1) In each case all direct sensation of the colour used for
fatiguing the eye is lost.

(2) There is produced a positive after-effect of the same colour by
which the hue of all other colours is modified if they are relatively
weak, but which is unnoticed if they are bright.

(3) The temporary abolition of any one colour sensation is with-
out effect on the intensity of the remaining colour sensations.

(4) Any two or any three of these four colour sensations can be
simultaneously or successively exhausted.

(5) The positive after-effect of red is very transient ; that of
green lasts longer and is more noticeable ; that of blue is still more
powerful and persistent ; and that of violet is strongest and lasts a
long while. As the positive after-effect subsides the colour sensa-
tion returns, but the positive after-effect becomes unnoticeable long
before the colour sensation is restored to its full strength.

(6) During the process of dazzling the eye the observer is con-
scious of the progress of the change, but only realises the extent of
his colour blindness on attempting to examine a less brilliantly
illuminated spectrum.

The positive after-effect does not in these experiments pass through
cyclic changes of tint as after-images appear to do under other con-
ditions.

On artificial temporary Colour-blindness. 37

Examination of the Phenomena with a Spectroscope of Wide Dispersion.

Green blindness was produced by the spectroscopic method already
described. When the exposure was complete the slit was closed
until the Fraunhofer lines were sharply defined. All sensation to
green was lost, the red appearing to meet the blue in the centre of
the field. The position of the junction of these two colours could be
varied considerably by exposing the eye to strong red or strong
blue light, thus showing that the red and blue overlap. But violet
light had no effect upon the position of the junction of red with
bine.

Similarly, during blue-blindness, the green and violet were seen to
overlap, exposure to green light shifting the junction towards the
green and vice versa. Red light had no effect on the position of
the junction of green with violet during blue-blindness.

The phenomenon of flickering* visible between the red and the
green of a highly magnified spectrum, is also seen at the junction of
red with blue during green-blindness, and of green with violet during
blue-blindness, as well as at the junctions of green with blue and of
blue with violet under normal conditions.

The author has succeeded by an exposure of three minutes to
light from between H and K in blinding the eye to violet without
affecting the blue, the real hue of which is thus seen, unaccompanied
by any other colour sensation.

These experiments lead to the conclusion that no one colour-
sensation is related to any other in the sense indicated by Hering.
Each may be exhausted without either weakening or strengthening
the others. The observed facts are, in the author's opinion, more
in accordance with the Young-Helmholtz theory, but they imply the
existence of a fourth colour sensation, namely, blue. .

Examination of the Colour Sensations of 109 Persons.

The tests employed were Holmgren's wools, supplemented by gela-
tine films stained with various colours, Bering's method of coloured
shadows, and the author's spectroscopic method, which was applied
to seventy normal cases in the following manner.

Using the large spectroscope referred to, with the slit narrow so as
to give a comfortable degree of illumination, the observer selects
those portions of the spectrum at which he sees a marked change of
hue. He then looks at the red between A and B for thirty seconds,
and at a given signal traverses the spectrum rapidly, stopping at the
first of these changes.

Next he looks at the green for thirty seconds before turning to the

* c Physiol. Soc.' Proc.,1 June, 1897.

38 Profs. A. Gray and J. J. Dobbie. Connection between

second change of hue. Again, after looking at bine for thirty seconds
he seeks the third change of hue. The next step is to trace the
violet to its limits. After this he works through the spectrum back
again, fatiguing the eye with violet before finding the blue, and so
on, ending with the determination of the limits of the red. The
degree of fatigue is so slight that he is quite unconscious of it.

The seventy cases examined in this way agree as to the number
and mean position of the changes of hue, but they may be divided
broadly into those whose colour sensations overlap and those whose
colour sensations do not overlap, i.e., those who find the changes of
tint occur in the same place when working from red to violet as when
returning from violet to red.

The first class includes persons both educated and uneducated
whose avocations require them to compare colours. The second com-
prises all who fail with the closer shades of Holmgren's wools.
Details are given of some in whom the green and violet are so far
extended into each other that they see practically no pure blue, and
it is suggested that these, and other differences in the relative
intensity and extent of the colour sensations may account for the
divergence of opinions among writers on the subject. The paper
concludes with an account of five cases of red-blindness.

"On the Connection between the Electrical Properties and
the Chemical Composition of different kinds of Glass."
By Professor ANDREW GRAY, LL.D., F.R.S., and Professor
J. J. DOBBIE, M.A., D.Sc. Received February 7, — Read
February 17, 1898.

The experiments and results described in the following paper are
a first instalment of work we have undertaken with a view to finally
determining, if possible, the circumstances which affect the con-
ductivity and specific inductive capacity of glass. It appeared from
some experiments which were carried out by Professor T. Gray and
ourselves some years ago,* that it might be of interest to have a
number of glasses specially made up with a view to testing some of
the conclusions then arrived at.

A result previously obtained by Professor T. Gray had shown that
potash and soda lime glasses have a higher conductivity than flint
glasses; this result had also been arrived at by Dr. Hopkinson. In
particular it seemed desirable to ascertain whether by increasing the
amount of lead oxide and diminishing the amount of soda, the con-
ductivity would go on diminishing. We have experienced great

* ' Roy. Soc. Proc.,' No. 231, 1884.

Electrical Properties and Chemical Composition. 39

difficulty in getting glasses made according to our own specifications.
We endeavoured to make the glasses ourselves, and several experi-
ments were made accordingly, both, in the laboratories here and at
the Ogwen Tile Works, where a large furnace had been erected for
the construction of tiles from slate dust. Some success was achieved,
but it was found impossible, without the expenditure of far more
time than could be spared, to obtain the glasses in a condition suit-
able for the experiments we wished to carry out.

Through the kindness, however, of Messrs. Schott & Co., of Jena,
and of Messrs. Powell & Sons, Whitefriars, London, we have recently
obtained a number of specimens of glass all richer in lead than the
specimens formerly available, and, further, in some cases practically
free from soda. We have also had made to order by Messrs. Schott
specimens of their own glass, used, we believe, chiefly in the con-
struction of thermometers, as well as of a barium crown glass,
which have not hitherto, so far as we are aware, been experimented
with.

Determination of Conductivity. — The method of experimenting
followed was practically the same as that described in the paper
already referred to, but its nature may perhaps here be indicated.

Owing to the large percentage of lead oxide in some of the glasses
prepared for us by Messrs. Schott, it was found impossible to blow
them into flasks, and they were therefore cast into plates ; the
arrangements therefore required some modification for their case.

The specimens which were in the form of flasks were filled up
with mercury to the bottom of the stem (which in most cases was
about 8 or 9 inches long), and the flask thus filled was sunk in a
bath also containing mercury, so that the mercury was at the same
level inside and outside. One terminal of a circuit containing a
battery of about thirty secondary cells and a very sensitive galvano-
meter was connected to the mercury within the flask by a wire pass-
ing down the neck, while the other terminal was connected to the
mercury in the bath.

The galvanometer was the instrument formerly used and described
in * Eoy. Soc. Proc.,' vol. 36, p. 287. It was carefully insulated, as
was also the reversing key, and all necessary precautions were taken
to make sure that the current passing through the galvanometer
was that passing through the walls of the flask between the mercury
coatings. Thus it was always verified that no deflection took place
when the wire was withdrawn from the flask and placed round the
outside of the neck. This test obviated the possibility of the
existence of any disturbing film of moisture on the surface of the
glass. The bath could be heated to any temperature required in
the experiments.

The conductivity was calculated from deflection of the galvano-

40 Profs. A. Gray and J. J. Dobbie. Connection between

meter produced by the current through the glass, the area and thick-
ness of part of the specimen in which the current flowed, as
described in the former paper.

In the capacity measurements the plate or flask, as the case might
be, was supported as described above. A quadrant electrometer was
kept connected to the plates of one of Lord Kelvin's air leydens.
This was charged with twelve secondary cells, and therefore to a
difference of potential of about 24 volts. After the battery had been
removed a reading was taken of the electrometer deflection, and
then the specimen was connected for a very short interval of time as
a condenser in parallel with the leyden.

This connection was made by means of a myograph pendulum
which, when freed, swung over a considerable arc to a catch which
prevented it from returning. At its lowest point a metal piece pro-
jecting below the bob touched the top of a tongue projecting upwards
from a hinge at its lower end, and leaning against the point of an
adjustable screw. The connection between the two condensers thus
only endured while the three pieces, the screw, tongue, and bob,
were in contact. This was only the interval of time required for a
pulse of flexure to travel about a centimetre in a bar of steel about
half a centimetre thick, and about a centimetre broad. The interval
was reckoned as at most about 1/30,000 of a second.

The plates were originally rather over a quarter of an inch thick,
and after some observations of capacity had been made on some of
them, and it had appeared that their resistance was too great to be
measurable, they were cut down on a turning- table used for cutting
slates, to a thickness of about 3 mm. ; they were then fixed on a bed
of pitch, and ground down by hand to a thickness of about 0'24 cm.
They were polished and properly cleaned, and then covered on both
sides with a dense and thoroughly adherent coating of silver. This
was cut away for a space of about half an inch round the edges.
Great care was taken to remove every trace of silver, and to make
the edge thoroughly clean.

While being experimented on, the glass plate was laid with one
coating of silver resting on a plate of copper at .the bottom of an
iron bath. Another plate of copper was laid on the upper coating
of silver, and kept down with a weight, and the connections of the
battery circuit, described above, were made with the copper plates.
The iron bath was placed within a larger bath partly filled with
sand, so that the temperature could be raised by heating the outer
bath from below.

The results of the experiments are exhibited in the table which
follows. We have there given the density, specific resistance,
specific inductive capacity, and chemical composition of each speci-
men experimented on.

Electrical Properties and Chemical Composition.

41

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<,£>>

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III

II ii

•MI ill sfiiii

.g "^ -g i a3 -*s 3 tx^ ft £

M 1^ 1 ^

w!l I!

Specific resist-
ance (ohms).

3 « g^ 5fe £ * 3
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||||| flfii1^

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III *

VOL. LXIIT.

42 Profs. A. Gray and J. J. Dobbie. Connection between

The resistance was taken after five minutes' electrification in each
case. The "Jena" glass (XXIV of the table), in both resistance
and capacity experiments, showed very considerable effects of
dielectric polarisation, which were a very long time in disappearing,
though the conducting coatings of the flask were kept short-circuited.
The dielectric polarisation of the lead glass made by Messrs. Powell
was also considerable.

On- the other hand it is very remarkable that the barium glasses
XXIII, in the capacity experiments, showed little or no sign of
polarisation effects ; and we propose to make some further investi-
gations of the physical properties of this glass.

In our previous paper the results obtained with eight different
samples of lead glass were compared, and it was shown that the
electrical conductivity fell off almost quite regularly as the amount
of lead oxide increased, and increased with an increase in the amount
of soda. The glass which possessed the highest specific resistance
(8400 x 1010 ohms) contained 4O5 per cent, of lead oxide, 7'5 per
cent, of potassium oxide, and 2*1 per cent, of sodium oxide. Both
of the lead glasses dealt with in this paper contained a still higher
percentage of lead oxide, and were almost free from soda, and the
electrical resistance was so great as not to be measurable. It is, of
course, impossible to say how far this result is due to the increase of
lead oxide, and how far to the elimination of soda. With the view
of definitely settling this point, Messrs. Powell and Sons have kindly
undertaken to prepare for us a glass exactly similar to XXI, but
having the potash replaced as nearly as possible by the equivalent
amount of soda. It should be noticed that the amount of foreign
matter (i.e., of ingredients other than silica, lead oxide, and alkali)
present in glasses XXI and XXII is very small, and is less than one-
fourth of the amount present in the purest glass previously tested,
which was also, it may be mentioned, the glass possessing the high-
est resistance.

It is noteworthy that the barium glass XXIII has a very high
resistance, and in this respect behaves more like lead than lime
glasses, which have usually a low resistance. It is impossible, how-
ever, in view of the somewhat complicated composition of this glass,
to say how far the high resistance is due to the presence of the
barium, and how far ifc may be influenced by other ingredients,
especially the boric acid, which was not present in any of the glasses
previously examined by ourselves or others.

The " Jena " glass XXIV has a low resistance, as was to be anti-
cipated, from its high percentage of soda and complex composition.

The chemical composition of glass XXI is capable of being
expressed with tolerable accuracy by a simple chemical formula, and
this is also in accord with previous experience, which pointed to the

Electrical Properties and Chemical Composition. 43

conclusion that a glass, which approaches in composition to a definite
chemical compound, has a high resistance.

Our knowledge of the chemistry of glasses is still very imperfect,
and we cannot say in what way the silica is distributed amongst the
bases. We give, therefore, merely the relative number of formula
weights of each oxide present, calculated from the analytical num-
bers, after allowing for the elimination of traces of foreign matter.

Specimen XXL

After allowing for traces of iron and alumina, the composition of
this glass may be expressed by the formula

22Si02,5PbO,2K20,
or

5(PbO,2Si02) + 2(K20,6Si02).

Found. Calculated.

Si02 50-72 50-53

PbO 42-32 42-33

K20 6-96 7-13

100-00 99-99

Specimen XXII.

This glass is essentially a lead potash glass mixed with a very
small quantity of a lead soda glass. Allowing for the small quan-
tity of manganese oxide, arsenious oxide, and other impurities
present, and eliminating the soda and a corresponding quantity of
silica, calculated on the assumption that each formula weight of soda
is in combination with three of silica, we obtain as an expression for
the composition of the lead potash glass

17Si02,5PbO,2K20.

Found. Calculated.

Si02 44-07 44-11

PbO 47-72 47-82

K20 8-19 8-06

99-98 99-99

Specimen XXIII.

This is a borosilicate of barium and alumina. After allowing for
the small quantities of arsenious oxide and manganese oxide which
it contains, it has the composition

28Si02,16BaO,3Al2039B203.

E 2

44 Dr. E. Taylor Jones.

Found. Calculated.

Si02 33-33 33-35

BaO 48-48 48-20

ALA 6-06 6-02

B203 12-12 12-40

99-99 99-97

Specimen XXIV.

The "Jena" glass is essentially a borosilicate of zinc, soda, and
magnesia, containing

20SiOa,2ZnO,2MgO,3NmO,2BaOa.

Found. Calculated.

Si02 67-87 68-05

ZnO 9-03 9-11

Na20 10-04 10-46

MgO 5-02 4-50

B203 8-03 7-87

99-99 99-99

"On the Magnetic Deformation of Nickel." By E. TAYLOR
JONES, D.Sc. Communicated by Professor ANDREW GRAY,
F.R.S. Received February 8,— Read February 17, 1898.

On a former occasion a paper was communicated to the Royal
Society* containing an account of some measurements of the mag-
netic contraction of a nickel wire, and a comparison of these with
the values deduced from Kirchhoff s theory. It was there shown
that the most important term in the calculated value of the elonga-
tion of a long wire of soft magnetic metal is represented by
JH(£I/<5P), where H is the magnetising field and £1 the increase of
magnetisation produced by a small increase of longitudinal tension
£P per unit area. The results showed that the observed contraction
in nickel was much greater than the calculated value. It was then
sought to establish an empirical equation which might represent the
observed effects, and it was found that the difference between the
observed and calculated contraction was approximately proportional
to the fourth power of the magnetisation.

It was suggested to me at the time that this result should be
tested by repeating the experiments under different conditions in
order to find out whether it was generally true.

* ' Phil. Trans./ A, vol. 189 (1897), p. 189.

On the Magnetic Deformation of Nickel. 45

In offering the following results, I wish again to say that the
measurements were made in the Physical Laboratory of the Univer-
sity College of North Wales, and that I am greatly indebted to
Professor A. Gray for providing me with the apparatus, and allow-
ing me the time necessary for the experiments, and for many valuable
suggestions.

Preliminary experiments were first made to find the nature of the
influence of temperature on the magnetic contraction. The appa-
ratus was essentially the same as described in the former paper,
with the addition of a spiral tube and burner for heating the water
just before it entered the coil. The temperature of the water on
entering and leaving the coil was indicated by two thermometers
inserted in capsules through which the water flowed. When the
water was warmed and allowed to flow for some time, the two
thermometers indicated steady temperatures differing generally by
about 2° C.

The change of length was magnified by the same lever arrange-
ment as before, and observed by a telescope, scale, and mirror. A
few trials showed that it would be impossible to make any measure-
ments when the water was warmed unless precautions were taken to
remove air dissolved in the water, for this, on being liberated in the
heater, ascended in bubbles through the coil and disturbed the appa-
ratus so much that no readings could be taken. To prevent this, the
water was made to flow into a vessel through a pipe near the top,
and escape by a pipe near the bottom, whence it proceeded to the
spiral heater. A tall glass tube projected upwards from the vessel,
and the vessel was heated by a Bunsen flame. The dissolved gases
were thus liberated in this vessel, and, collecting at the top, escaped
at intervals up the glass tube. By this means the apparatus was
rendered steady enough to admit of readings at moderately high
temperatures. Further, by regulating the supply the water could be
made to stand at any level in the glass tube. Thus the flow of
water through the coil, and hence the temperature of the coil could
be controlled.

The glass tube was about 6 feet long, and by raising the level of
water in it through 1 foot the temperature of the coil was lowered
by about 1° C.

Observations of the change of length were always made at night,
generally between 10 P.M. and 2 A.M., the apparatus never being
sufficiently steady in the daytime.

The nickel wire was the same as that used in the former experi-
ments, of length 83'4 cm. between the terminal brass pieces, and
mean diameter 1*65 mm. This was re-annealed before the present
measurements.

A number of observations were then made of the change of length

46 Dr. E. Taylor Jones.

and corresponding field strength on several nights in July and August,
1897, the temperature indicated by the coil thermometers being
about 20° C. As before, the temporary and residual contractions
were measured separately, the total contraction corresponding to any
field strength being obtained as the sum of the temporary effect
(observed as an elongation when the current was broken), and the
residual effect observed by first demagnetising the wire by reversals,
then quickly making and breaking the current. It was found that
the curves thus obtained were not the same on different nights, but
showed a continual diminution of contraction as time went on. This
is probably due to a slow hardening of the metal which seems to go
on for some time after the wire has been annealed. The effect of
this change can be seen by comparing Tables I (column 2) and III
(column 4), which contain values of the contraction of the wire in
million ths of its length for a series of fields, observed about the
middle of August, 1897, and at the end of December, 1897, respec-
tively.* The wire was annealed on July 3, 1897.

In order to observe the effect of a change of temperature on the
magnetic contraction at any field strength it was necessary to take
readings at two temperatures immediately after one another, so that
the results would not be affected by the above-mentioned time effect.
This was done on several nights and with several field strengths, the
two temperatures used being about 20° C. and 55° C. The results
showed that at low fields (up to about 90 C.Gr.S.) this rise of tempera-
ture of 35° C. caused an increase, at higher fields a diminution, of
contraction ; and if the temperature was then lowered back to 20° C.
the contraction returned to its former value.

Table I contains values of the change of length in millionths and
corresponding field strength at the two temperatures, determined on
two successive nights, the effect at both temperatures being observed
at the lower fields on one night, and at the higher fields on the next.
Each field was reversed several times before readings were taken,
and the wire was demagnetised on each night while the tempera-
ture was being changed. The curves representing these results
(contraction, field) have the same general form as was described in
the former paper, but the temporary contraction is here considerably
greater, though the residual contraction is much the same as before.
The effect of temperature is chiefly seen in the temporary contrac-
tion : the residual effect, however, appears to be slightly less at the
higher temperature at all fields.

On referring to Professor E wing's 'Magnetic Induction in Iron
and other Metals ' (§ 114, p. 169), I find that rise of temperature
causes increase of magnetisation in nickel at low fields and diminu-

* The temperatures on the two occasions differed by about 10" C., but the effect
of this would be comparatively small.

On the Magnetic Deformation of Nickel. 47

tion at high fields. Change of temperature, therefore, seems to have
similar effects on the magnetisation and contraction curves. Of
course this comparatively small difference of temperature, 35° C.,
would have but a small effect on the magnetisation curve, but as the
contraction seems to depend on rather high powers of the magnetisa-
tion, it might be expected that the effect would be more noticeable
in the change of length than in the magnetisation.

Measurements were next made of the magnetisation and the effect
of change of tension on the magnetisation, in order to calculate the
quantity

0-123 0-00587

which was shown in the former paper to be the value of the
elongation, <>Z/Z, of the wire deduced from Kirchhoff's theory. For
these measurements a coil of 611 turns of No. 40 double silk-covered
and shellacked copper wire was wound en the nickel wire near the
middle, and connected in series with a ballistic galvanometer, and
with the secondary of a standardising solenoid. The magnetisation
was determined by reversing a measured magnetising current, and the
galvanometer standardised by reversing a current in the solenoid,
the deflections being observed in the two cases. The galvanometer
was standardised before and after each set of readings.

Since the resistance in circuit with the galvanometer changed
when the temperature of the coil on the nickel wire changed, care was
taken that the temperature indicated by the coil thermometers was
the same in the magnetisation and standardising experiments. By
using a series of different currents in the standardising coil, it was
verified that the " quantity of electricity " flowing through the
galvanometer was proportional to the sine of half the deflection of
the needle. The deflections were observed by a telescope and scale
at a distance of 124 cm.

In observing the influence of tension on magnetisation, galvano-
meter readings were taken first with a load of 1'4 kg. on the wire,
then after an additional weight of 7 kg. was applied. The mag-
netising current was reversed several times and the load ap-
plied and removed several times before readings were taken. This
was repeated for various field strengths, ranging between 30 and
320 C.G.S., and with the coil at 10° C. and 55° C. Then the mag-
netisation curve of increasing reversals was determined for the
mean load 4'9 kg. at both temperatures, after which the coil was
removed from the nickel wire, and observations made with load
4'9 kg., and at the same two temperatures, of the magnetic contrac-
tion at a number of increasing field strengths, each field being
reversed several times before readings were taken.

48 Dr. E. Taylor Jones.

In order to make allowance for the slow time-change in the pro-
perties of the wire, the determinations of magnetisation and effect
of change of tension on magnetisation were then repeated, the
nickel wire being rewound with the same number of turns of insu-
lated copper wire.

Finally, the contraction of the wire was once more determined at
the temperature 10° C.

Values of the expression (1) were calculated from both sets of
magnetisation observations, and the mean of the two sets compared
with the actual contraction observed between them.

The results are shown in Tables II, III, IY, Y, VI, in which values
of all the quantities (obtained from the corresponding curves) are
given for the same set of field strengths.

In Tables II, IV, the first column contains values of the field
strength H, the second the magnetisation I at load 4*9 kg., the third
the change of magnetisation £1 accompanying an increase of load
of 7 kg., the fourth the corresponding values of expression (1), i.e.,
the calculated value of 5Z/Z. The numbers in the second, third,
and fourth columns were determined in November, 1897. The fifth,
sixth, and seventh columns contain values of I, 51, and 5Z/Z, deter-
mined in January, 1898.

Tables III and V contain values of the field, the mean values of I
and SI 1 1 calculated from Tables II and IV, the actual change of
length a in millionths, observed about the end of December, 1897,
and the difference (tx—Bl/l) between the observed and mean calculated
elongations.

Finally, in Table VI are given the values of I and 3Z/Z, measured in
January ; the mean a of the actual changes of length observed in
December and in January, the latter being determined after the
second set of magnetisation measurements ; and the difference,
(a — 5Z/Z), representing the corrected elongation at the time when the
second set of measurements of I and el/SP was made.

Tables II and IV show the nature of the slow time-change in the
magnetic behaviour of the nickel wire, the magnetisation at any
field and load being less in January than in November.

The effect of this change on £l/<)P is very marked at low fields,
though slight at higher fields ; 5I/&P appears to diminish rapidly at
low fields, as time goes on. This is remarkable, because the magnetic
contraction at low fields seemed to change but slowly with time, and
more rapidly at higher fields.

The change of length observed in January was nearly the same as
in December (about four weeks earlier). At medium fields it was
rather greater, but this may be due to a slight annealing caused by
the repeated warming and cooling during the determinations of the
magnetisation earlier in January.

Oil the Magnetic Deformation of Nickel. 49

A comparison of Tables II and IV, or III and V, shows again the
nature of the influence of temperature on magnetisation and contrac-
tion, but as the measurements at the two temperatures were not
made quite at the same time, the results probably do not accurately
represent this influence.

If the results given here are compared with those given in the
former paper, it will be seen that the magnetic contraction at any
field observed in December, 1897 (Table III), is practically identical
with the former value, but that the magnetisation curve is very
different from the former one. The present magnetisation is much
greater at low and medium fields, but about the same as before at
higher fields. Further, the calculated value of the contraction is,
especially at medium and high fields, considerably less than before.
Hence the "corrected" contraction — (a — £Z/Z) cannot now be the
same function of the magnetisation as before ; it is, in fact, now much
more nearly proportional to I6, as the last two columns of Tables III,
V, and VI show.

It is impossible to say how much this discrepancy is due to the
slow change which appears to be always going on in the magnetic
properties of the nickel wire. In the former experiments the mag-
netisation was determined first, and a short time after the elongation
was observed, but no allowance was made for any change of magnet-
isation which might have taken place in the meantime. Still, it is
improbable that that would entirely account for the discrepancy.

Some of the above results are shown graphically in figs. 1, 2, 3.
In fig. 1 the difference of ordinates of the highest and lowest curves
for any value of the field H represents the effect on the magnetisa-
tion of changing the load from 1'4 kg. to 8'4 kg., after the additional
load of 7 kg. has been applied and removed, and the field reversed,
several times. The intermediate curve is the magnetisation curve of
increasing reversals for the mean load 4'9 kg. These curves were
determined in January, 1898.

In fig. 2 the curves represent, as functions of the field, the observed
contraction (December, 1897), the calculated contraction (mean of
November, 1897, and January, 1898), and the corrected contraction,
i.e., the difference between the observed and calculated contractions,
The calculated contractions of November and January are repre-
sented by the points -f + + • • and Q 0 O • • respectively. The
observed contraction curve is practically the same as that given in
the former paper, but the calculated and corrected curves show
considerable differences.

In fig. 3 the points marked + -f + . . represent the corrected con-
traction as a function of I6 (Table III), and these points lie nearly
on a straight line through the origin. The temperature during all
the experiments represented by these curves was 10° C.

50

Dr. E. Taylor Jones.

FIG. 1.

O 50

FJG. 2.
ff. r.^. Temp. /o°C.

/3

\

/50 200 Z3O JOO J5O

Cd/G-

On the Magnetic Deformation of Nickel.

51

O /OO 2OO JOO

/o

FIG. 3.

SCO 6OO 7OO 8OO 900 /,OOO l/OO J£OO

Table I.
Load 4-9 kg. August, 1897.

H.C.CKS.

Contraction of nickel wire in
millionth s of its length.

At 19° C.

At 56° C.

35

7'0

7-5

60

12-5

13-2

80

16-5

16-7

100

20-0

19-6

125

23-6

22-8

150

26-5

25-3

175

29-0

27-6

200

31-4

29-8

225

33-6

31-6

250

35-5

33-3

275

37-0

34-6

300

38-2

35-7

330

39-1

36-8

Dr. E. Taylor Jones.

Table II.
Temperature 10° C. Load = 4'9 kg.

P x Section of Wire = 7 kg.

November, 1897.

January, 1808.

H.C.G.S.

SJ

_.]06

? . 10G

I.

<5I.

I

I.

u.

I

calc.

calc.

35

272

-94-5

-5-1

258

-70-0

-3-7

60

340

-73-5

-6-6

323

-60-0

-5-5

80

375

-58-0

-7-1

359

-54-0

-6-45

100

399

-47-0

-7-15

385

-47-5

-7-05

125

419

-38-0

-7-0

409

-38-0

-7-1

150

434

-30-5

-67

426

-31-0

-6-7

175

446

-21-0

-6-3

410

-24-0

-6-3

200

454

-19-0

-5-65

450

-18-5

-5 5

225

461

-14-5

-4-6

458

-14-0

-4-65

250

466

-ll'O

-4-0

464

-11-5

-4-2

275

470

-9-0

-3-55

468

-9-5

-3-8

310

476

-8-0

-3-15

473

-8-0

-3-5

Table III.
Temperature 10° C. Load = 4'9 kg.

Mean

Mean

Cl 106

a . 10G

(a-~\ .10fi.

F.10-13.

H.

I.

I '

calculated.

observed.

_

35

265

-4-40

-5-3

-0'9

34-6

60

331

-6-05

-10-0

-3-95

132-0

80

367

-6-78

-13-35

-6-6

244-0

100

392

-7-10

-16-35

-9-2

363-0

125

414

-7-05

-19-9

-12-8

503-0

150

430

-6-70

-22-8

-16-1

632-0

175

443

-6-30

-25-3

-19-0

756-0

200

452

-5-58

-27-35

-21-8

852-0

225

460

-4-62

-28-9

-24-3

948-0

250

465

-4-10

-30-3

-26-2

1012-0

275

469

-3-70

-31-5

-27-8

1064 -0

310

474

-3-30

-32 9

-29-6

1134-0

On the Magnetic Deformation of Nickel.

53

Table IV.
Temperature 55° C. Load = 4'9 kg. SP x Section of Wire = 7 kg.

November, 1897.

January, 1898.

H.

I.

SI.

«.w.

I.

*L

f'106

calc.

calc.

35

274

-93-0

-4-8

264

-70-0

-3-65

60

340

-67-0

-6-15

326

-62-5

-5-45

80

372

-55-5

-675

359

-55-0

-6-4

100

393

-45-5

-6-8

385 -44-8

-6*75

125

413

-35-0

-6-5

409

-35-5

-6-6

150

427

-27-5

-6-1

425

-27-0

-6-0

175

438

-22-0

-5-55

436

-21-0

-5-45

200

446

-18-0

-5-0

446

-16-8

-4-9

225

453

-14-2

-4-55

453

-12-9

-4-2

250

457

-11-5

-4-1

457

-10-5

-3-65

275

461

-8-3

-3-65

460

-7-5

-3-60

Table V.
Temperature 55° C. Load = 4'9 kg.

Mean

H.

Mean I.

T'106

o.lO«
obs.

(°->8-

IMO-".

calc.

35

269

-4-2

-5-5

-1-3

37-9

60

333

-5-8

-10-0

-4-2

136-0

80

365

-6-6

-13-3

-6-7

236-0

100

389

-6-8

-16-3

-9'5

347-0

125

411

-6-5

-19-4

-12-9

482-0

150

426

-6-0

-22-2

-]6-2

597-0

175

437

-5-5

-24-5

-19-0

697-0

200

446

-4-9

-26-3

-21-4

787-0

225

453

-4-4

-27-8

-23-4

864-0

250

457

-3-9

-29-1

-25-2

911-0

275

460

-3-6

-30-2

-26-6

948-0

54 Mr. 0. S. Tomes. Structure and Development

Table VI.

January, 1898.

Mean

H.

Si

a . 106

fa — — \106.

I6 . 10-».

I.

T ' 10

obs.

V I )

calc.

35

258

-3-7

-5'30

-1-6

29-5

60

323

-5-5

-10-1

-4-6

114-0

80

359

-6-45

-13-6

-7-2

214-0

100

385

-7-05

-16-7

-9-6

326-0

125

409

-7-1

-20-2

-13-1

468-0

150

426

-67

-23-1

-16-4

598-0

175

440

-fi-3

-25-5

-19-2

726-0

200

450

-5-5

-27-5

-22-0

830-0

225

458

-4-65

-29-05

-24-4

923-0

250

463

-4-2

-30-4

-26-2

986-0

275

468

-3-8

-31-6

-27-8

1050 -0

310

473

-3-5

-32-9

-29-4

1120-0

*' Upon the Structure and Development of the Enamel of
Elasmobranch Fishes." By CHARLES S. TOMES, M.A.,
F.R.S. Received February 7,— Read February 17, 1898.

(Abstract.)

The nature of the hard polished outer layer of the teeth of this
group of fishes has been from time to time a subject of discussion,
some authors holding that it is enamel, whilst others deny its claim
to be so styled.

The author describes its physical, chemical, and histological
peculiarities, calling attention to its hardness, its optical properties,
its almost entire solubility in weak acids, and to its tubularity, in all
of which respects it resembles unquestionably an enamel.

But it contains lacunar spaces, and presents a very distinct lami-
nation, parallel, or nearly so, with its surface, in which respect it is
unlike an enamel.

Still upon the balance of its characters it has much more in
common with enamel than with dentine, from which it is sharply
marked off by the entire absence of any collagen basis.

It is also shown that the tubular structure, which may be regarded
as typical in these fish, passes by insensible gradations into a simple
tissue differing but little from an ordinary enamel ; this is especially
the case where the whole layer is thin, as in the Rays. But the
study of its development raises the difficulty afresh.

of the Enamel of Elasmobrancli Fishes. 55

Each dentine papilla forms upon its surface a specialised layer
which is derived from spindle-shaped cells, sending out immensely
elongated processes which run nearly parallel with the surface.
There is a large amount of intercellular substance formed so that the
cell processes ultimately become inconspicuous, and a lamination or
fibrillation of this layer only remains ; in this stage it is exceedingly
resistant to staining.

The layer is also permeated by cell processes which run through
it at right angles to its surface, and these persist. It is found that
this layer is the site of the so-called enamel formation, the first
named cell processes giving rise to its lamination, and the last men-
tioned cell processes giving rise to the tube system which per-
meates it.

In all mammals dentine calcification commences at the very out-
side of the dentine papilla, and nothing at all corresponding to this
specialised layer exists at any period.

But in the Elasmobranch fishes the calcification of the dentine,
whether it be an osteodentine as in Lamna or a fine-tubed dentine as
in most others, does not take place at the outer surface of the entire
dentinal papilla, but along the deeper side of the specialised layer,
thus soon cutting it off from any free communication with the body
of the pulp.

This layer, in the extent to which it is developed, bears a ratio to
the thickness of the ultimate ** enamel." Over it lie the columnar
epithelial cells of the enamel organ, which present several peculiari-
ties ; they are found to grow to three or four times their original
size quite suddenly ; that is to say, on one tooth germ they are small,
on the very next they are enormous, and this is the tooth germ in
which the specialised layer has attained to its maximum. Then on
the next older germ the ameloblasts have fallen to their original size,
and have lost their distinctness of outline.

The great growth of these cells just at one particular stage of tooth
development, their subsequent immediate atrophy, and the fact that
their length bears also a direct ratio to the thickness of the enamel
formed, renders it impossible to suppose that they can be function-
less, and it is suggested that they furnish the lime salts for the
calcification of the specialised layer of the dentine papilla before
alluded to, there being difficulties in the way of supposing that the
dentine papilla does so.

In that case the disputed enamel layer of the finished tooth does
not correspond precisely either to the enamel or to the dentine of the
completed mammalian tooth, but is a joint product of the epiblastic
enamel organ and the mesoblastic dentine papilla.

The general conclusion arrived at is that, just as the whole teeth
of the Elasmobranchs present the simplest known form of tooth

56 Mr. W. H. Lang. On Apogamy and the

development, so do they also present the first introduction of enamel
as a separate tissue.

In its first introduction it was a joint product, made under circum-
stances which almost precluded any slow and gradual formation of
an outer layer upon the teeth ; but in the further specialisation of
teeth in reptiles and mammals the tooth germs sink more deeply into
the submucous tissue, and are protected for a much longer time.

The enamel organs become more specialised, and finally take upon
themselves the entire work of enamel building, manufacturing both
the organic matrix and furnishing it with lime salts, as unquestion-
ably happens in mammals.

And if these conclusions be correct, it would be quite justifiable to
call it enamel, even though the dentine papilla has had a share in its
production.

*' On Apogamy and the Development of Sporangia upon Fem
Prothalli." By WILLIAM H. LANG, M.B., B.Sc., Lecturer in
Botany, Queen Margaret College, and " G-. A. Clark "
Scholar, Glasgow University. Communicated by Professor
F. 0. BOWER, Sc.D., F.R.S. Received February 28,— Read
March 3, 1898.

(Abstract.)

The two most important deviations from the normal life-history
of ferns, apogamy and apospory, are of interest in themselves, but
acquire a more general importance from the possibility that their
study may throw light on the nature of alternation of generations-
in archegomate plants. They have been considered from this point
of view by Pringsheim, and by those who, following him, regard the
two generations as homologous with one another in the sense that
the sporophyte arose by the gradual modification of individuals
originally resembling the sexual plant. Celakovsky and Bower, on
the other hand, maintain the view that the sporophyte, as an inter,
polated stage in the life-history arising by elaboration of the zygotey
is not the homologue of the gametophyte, and is only represented in
a few thallophytes. In the light of the theory of antithetic alterna-
tion no weight is attached to apogamy and apospory for phyloge-
netic purposes.

In the paper of which this is an abstract the results obtained by
cultivating the prothalli of a number of species of ferns under
conditions slightly different from the natural ones are described, and
their bearing on the problem of the nature of alternation considered.
The behaviour of Scolopendrium vulgare, Sm., and Nephrodium- dilata-

Development of Sporangia upon Fern Prothalti. 57

turn, Desv., in which sporangia were borne upon the prothallus, has
already been described in a preliminary statement.* It is therefore
sufficient to express the results of prolonged cultivation of these and
the remaining species in a tabular form.

Table of the Results of cultivating Prothalli for a Period of Two
Yea,rs and a Half.

[Note. — In every species normal embryos were produced when
conditions permitted fertilisation.]

Name.

Scolopendrium vulgare. Sin., var.
ram u losisa imuin.

var. marginale.

Nephrodium dilatatum, Desv., var.
cristatum gracile.

Nephrodium Oreopteris,Desv.^ var.
coronans.

Result.

Garaetophytic budding.
Development of archegonial projections.
Development of cylindrical process usually
from the apical region of the prothallus.

C Tracheides in cylindrical process.
Leaves, roots, and ramenta on

process.
Apogauiy. \ Sporangia on the process.

Vegetative buds from tip of
cylindrical process, or ir. place
L of an archegonial projection.

Similar to var. ramulosissimum, but no spor-
angia, isolated ramenta, or leaves found.

Gametophytic budding.
Development of archegonial projections.
Development of cylindrical process, usually
from the under surface just behind the
apex, which formed a " middle lobe."

TTracheides in middle lobe and

cylindrical process.

. J Sporangia, sometimes associated

* ' j with ramenta, on middle lobe

and process.
l^JNo vegetative buds.

Gametophytic budding.
Development of archegonial projections.
Development of cylindrical process from apex
of prothallus.

/-Tracheides in cylindrical pro-

] Ramenta on cylindrical process.
L Vegetative buds (rare).

1 Boy. Soc. Proc,,' vol. 60, p. 250.

VOL. LX1II.

Mr. W. H. Lang. On Apogamy and the

Name.

Aspidium aculeatum, Sw., var.
multifidum.

Aspidium angular e, Willd., var.
foliosum multifidum.

Tar. acutifolium multifidum.

Athyrium niponicum, Mett., nor-
mal form.

var. cristatum.

AtJiyrium Filix-foemina, Bernh.
var. percristatum.
var. cruciatum cristatum.
var. coronatum.

Polypodium vulgare, L., var.
grandiceps.

Aspidium frondosum, Lowe (from
the Pits, Royal Gardens, Kew).

Result.

Gametophytic budding.

Development of archegonial projections.

Apogamy. j Tl'acheides in prothallus.
I Vegetative buds (rare).

G-ametophytic budding.

Development of archegonial projections.

Apogamv / Bamenta on Prothallus.

L Vegetative buds (frequent).
G-ametophytic budding.
Development of archegonial projections.
No apogamy seen.

Gametophytic budding.

Development of archegonial projections.

Apoeam -f Trac^e^es in prothalloid growths

I from archegonial projections.
Similar to the normal form, but in addition a
few apogamously produced vegetative buds.

Gametophytic budding.
Development of archegonial projections.
Development of cylindrical process from apex
or from under surface of the prothallus.

r Tracheides in process.
Apogamy. < Continuation of process as a leaf.

L Vegetative buds.

Gametophytic budding.

A o am •[ *8°lated leaf -like growths.

L Vegetative buds (numerous).

Apogamy. Vegetative buds produced on
short cylindrical processes before the cul-
ture had been watered.

After the culture was watered, normal em-
bryos.

In addition to the species mentioned in the table above, cultures
were made of crested and uncrested forms of Neplirodium Filix-mas,
Rich., representing the three sub-species, which are sometimes
distinguished in this country. Some of these (both crested and
normal) behaved in a similar manner to the species referred to in
the table, though only one instance of apogamy induced by long
cultivation has as yet been found. Others (crested and normal
forms) produced a single bud on the under side of the prothallus
which, did not bear archegonia.

Connecting this latter type of apogamy, which agrees with the
description of l)e Bary and Kny, with the more normal prothalli, was
one variety, the archegonia of which developed into typical arche-

Development of Sporangia upon Fern Prothalli. 59

gonial projections. In the place of the projection nearest to the
apex a vegetative bud arose.

It is possible to draw some general conclusions from this series of
cultures. It is a striking fact that in every one of the species,
prothalli, which under normal conditions would have produced
normal embryos, became, after a longer or shorter period, apo-
gamous. Further there was a general similarity in the changes of
form and structure of the prothallus, which preceded this result.
This form of apogamy, occurring after prolonged cultivation of
normal prothalli under special conditions, may be distinguished as
induced apogamy, in contradistinction to direct apogamy, by which is
meant the immediate production of vegetative buds by prothalli,
which are usually incapable of being fertilised. Both forms occur
in Nephr odium Filix-mas.

The causes which appeared to induce apogamy in these prothalli
were the prevention of contact with fluid water which rendered
fertilisation impossible, and the exposure to direct sunlight. Pos-
sibly the temperature also had some effect. The case of Nephrodium
Filix-mas shows that the variable condition of the sporophyte, as
indicated by cresting, &c., though possibly predisposing to the
changes which lead to apogamy, does not stand in any necessary
connection with the phenomenon.

That different decrees of apogamy are distinguishable was also
shown by these cultures. The cylindrical process, arising from the
apex of the prothallus, or from its under surface, is to be regarded
simply as a modification in form and structure of the gametophyte
dependent on the altered conditions, and possibly a direct adapta-
tion to these. The next stage is seen in cylindrical processes,
which, while bearing sexual organs, also produce isolated members
of a sporophyte (roots, ramenta, sporangia). It is to be borne in
mind, however, that tissue differing from the rest of the process
always occurred beneath the last-named structures. The final stage
is the production of a vegetative bud capable of further growth as a
typical sporophyte. In this a series, leading from the bud arising
by transformation of the tip of a cylindrical process, to buds pro-
duced on or in the place of archegonial projections, and from this to
buds situated on the under surface of the prothallus itself, can be
recognised.

The readiness with which the intermediate form between gameto-
phyte and sporophyte and the early stages of vegetative buds
reassume the prothalloid form, is worthy of note, as bearing on some
cases of apospory.

These departures from the normal development of the prothallus
are not regarded as reversions in the ordinary sense, but as indica-
tions of the capability of direct response to altered conditions,

F 2

60 Apogamy and Development of Sporangia upon Fern Prothalli.

possessed by the gametophyte. Their possible importance in relation
to the theory of homologous alternation appears to the writer to be
of this nature. If that theory be true, the sporophyte and gameto-
phyte are modifications of a similar form. The gametophyte, espe-
cially the simple free-living prothallus of the Ferns, has departed
less widely from that form. Such an organism as a fern prothallus
would therefore appear to be suitable for experimental work, in the
hope that its behaviour under altered conditions would afford hints
as to the sort of changes which, in the original algal form, led to
the evolution of the sporophyte. The altered conditions in this
series of experiments are of a similar kind to those which are
assumed by Professor Bower to have occurred on the spread of
algal forms to the land, and to have conduced to antithetic alter-
nation.

The results may now be used in picturing the manner in which
alternation of generations might have come about by the modifica-
tion of originally similar individuals into gametophyte and sporo-
phyte. It is assumed for this purpose that the sporophyte of the
vascular cryptogams did not arise by the elaboration of a structure
resembling a bryophytic sporogonium. It is recognised that the
theory of antithetic alternation, as elaborated by Professor Bower,
affords a consistent and satisfactory explanation, if the assumptions
necessitated by the theory are granted. The p'resent theory, which
is put forward merely as a provisional hypothesis, is founded on
another class of facts.

With the spread of algal organisms to the land, where in the
absence of any vegetation affording shade, some at least would be
exposed to more intense illumination, the flattened form would
probably be assumed. Prolonged drought and the influence of direct
sunlight, inducing directly a change of form into a cylindrical
body, might be accompanied by the substitution of a reproductive
organ forming dry reproductive cells (spores) for those adapted to
an aquatic existence. The acquisition of more highly developed
absorbent organs (primitive roots) would further the existence and
growth of this modified gametophyte. This spore-producing stage
would at first follow the sexual stage in any individual exposed to
dry conditions. It is possible to imagine, however, how the asso-
ciation of the asexual with the sexual individual might come about.
Absence of fluid water would prevent the liberation of motile spores
from the zygote. The latter would be obliged to germinate in situ,
and the fact that it did so under dry conditions would tend to the
shortening of the sexual stage, and the speedy assumption of the
sporophytic form and mode of reproduction. From the spore, which
would always separate from the parent, a sexual individual would
arise, since germination could only take place in a damp spot. AS

Degenerative Changes in Sensory End Organs of Muscles. 61

soon as, with the increase in size and complexity of the spore-bearing
plant, a vegetation capable of affording shade came into existence,
the conditions suitable for the persistence of the more primitive,
alga-like, sexual stage in the life history would be present. The
latter has, of course, also been modified in various ways.

In the concluding portion of this paper, the theories of antithetic
and homologous alternation are compared by considering the expla-
nations they afford of the facts. The general conclusion reached is
that, while both afford a possible explanation of the facts of alter-
nation in archegoniate plants, any evidence which would render one
or the other untenable is wanting. The reasons on which either is
considered more probable depend on the views held as to the lines
of descent which have been followed, and the degree to which the
different groups of archegoniate plants have had a common origin,
or represent actual steps in the process of evolution of the sporo-
phyte. Under these circumstances the question must be regarded
as an open one until the available lines of evidence have been more
fully investigated.

I am especially indebted to Dr. Scott and Professor Bower for
their assistance and advice ; the work was commenced in the Jodrell
Laboratory of the Royal Gardens, Kew, and subsequently carried on
in the Botanical Laboratory of the University of Glasgow.

" Experimental Observations on the early Degenerative Changes
in the Sensory End Organs of Muscles." By F. E. BATTEN,
M.D. Communicated by Professor VICTOR HORSLEY, F.R.S.
Received February 17,— Read March 3, 1898.

(Abstract.)

The experiments described in the following paper were under-
taken in order to show, firstly, that degeneration occurred in the
first place in that part of the neuron most remote from the cell, and
secondly, to reproduce within the muscle-spindle, if possible, certain
changes which had been shown by the author to be present in the
case of tabes dorsalis in man.

The method of experiment was as follows: — Dogs were selected,
and the mixed roots of the 5th cervical to the 1st dorsal inclusive
were divided, and the animals killed at the following periods after
section of the nerve, viz., 24, 48, 72, 96, 120 hours, and 7 and 14
days.

From the biceps muscle after being treated by Sihler's method
mscle-spindles were teased out ; some of these were mounted with-
>ut further staining, others were treated by Marchi's method, others.

)re stained by the Marchi-Pal method,

62 Degenerative Changes in Sensory End Organs of Muscles.

The normal muscle-spindle showed the existence of a spiral form
of nerve termination in connection with the large nerve fibre that
passes to the equatorial region of the spindle, this spiral nerve
termination is shown to wind round a muscle fibre, which at this
point contains large cells, at one point completely filling the muscle
fibre and interrupting the striation, but tailing off in either direc-
tion so that the cells come to lie in the centre of the muscle fibre.
It is then shown that in twenty-four hours after section of the nerve
changes may be seen in this spiral termination, and that in forty-
eight hours after section of the nerve the spiral is no longer recognis-
able, oval and elongated granular cells now making their appearance.
Changes then appear in the large intramuscular cells. The musculo-
spiral nerve was then examined in three parts of its course, (1) in
the muscle, (2) at its entrance into the muscle, (3) near its origin, at
various periods after section of the nerve. No obvious change could
be found in the nerve till between the fifth and seventh day after
section of the nerve, and at that time degeneration was as marked
in the central portion of the nerve as in the peripheral (Marchi and
Marchi-Pal methods were used).

The existence of a spiral form of nerve termination has already
been described by Ruffini as encircling a muscle fibre, and other
authors refer to a spiral within the muscle-spindle; but it has not, I
believe, been shown that the spiral encircles the large intramuscular
cells first described by Kiihne.

Early degeneration was first described by Cattaneo in the nerve
termination in the musculo-tendon organ twenty hours after section
of the nerve. Both these investigators used the gold-chloride
method, in the present research Sihler's method has been used.

The results of the research have been to show —

(1) That within the muscle-spindle a spiral form of nerve ter-
mination exists surrounding a fine muscular fibre, in the centre of
which are large, clear, non-nucleated cells.

(2) That changes take place in the spiral in twenty-four hours
after section of the nerve, and that such changes become marked in
forty-eight hours.

(3) That degeneration of the medullated sheath of the nerve takes
place in the whole course of the nerve at the same time after section
of the nerve.

(4) That no fatty change could be demonstrated in the intra-
muscular cells by the Marchi method similar to those found in the
case of tabes dorsalis in man.

Proceedings. 63

March 17, 1898.
The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.

Professor Wilhelm Pfeffer, who was elected a Foreign Member in
1897, was admitted into the Society.

The CROONIAN LECTURE, " The Nature and Significance of Func-
tional Metabolism in the Plant " (Das Wesen und die Bedeutung des
Betriebsstnffwechsels in der Pflanze), was delivered by Professor W.
Pfeffer, For. Mem. R.S., of the University of Leipzig.

The following Papers were read : —

" On the Intimate Structure of Crystals. Part III. Crystals of the
Cubic System with Cubic Cleavage. Part IV. Cubic Crystals
with Octahedral Cleavage." By Professor SOLLAS, F.R.S.

March 24, 1898.

SIR JOHN EVANS, K.C.B., D.C.L., Treasurer and Vice-President,

in the Chair.

The Right Hon. Sir Herbert Eustace Maxwell, a Member of Her
Majesty's Most Honourable Privy Council, was admitted into the
Society.

The BAKERIAN LECTURE, " Further Experiments on the Action
exerted by certain Metals and other Bodies on a Photographic Plate,"
was delivered by Dr. W. J. RUSSELL, V.P.R.S.

The following Paper was read : —

" A Photographic Investigation of the Absorption Spectra of Chloro-
phyll and its Derivatives in the Violet and Ultra-violet Region
of the Spectrum." By C. A. SCHUNCK. Communicated by Dr.
E. SCHUNCK. F.R.S.

VOL LXI11.

64 Mr. W. Ellis. Relation between Diurnal Range of

" On the Relation between the Diurnal Range of Magnetic
Declination and Horizontal Force and the Period of Solar
Spot Frequency." By WILLIAM ELLIS, F.R.S., formerly
of the Royal Observatory, Greenwich. Received March 3,
—Read March 10, 1898.'

(Second Paper.)

In a paper communicated to the Royal Society in the year 1879,
and printed in the ' Philosophical Transactions ' for 1880, I com-
pared the diurnal range of magnetic declination and horizontal
force, as observed at the Royal Observatory, Greenwich, during the
vears 1841 to 1877, with the corresponding numbers of sun-spot
frequency as determined by the late Dr. Rudolf Wolf, of Zurich. As
I then said, I conceived that the long series of Greenwich observa-
tions, made throughout on the same general plan and with instru-
ments of the same kind, might be applied as a valuable independent
test of the reality of the relation generally understood to exist
between the phenomena in question. And the comparison appeared
to be distinctly confirmatory thereof. For it was to be observed
that, although the sun-spot period, commonly called the eleven-
year period, varied in length to the extent of several years, the
corresponding magnetic periods varied in a similar manner. Still,
in a case of this kind, in which the cause of the phenomena
observed has not been determined or a'scertained, it becomes im-
portant indisputably to prove the accuracy of the observed facts and
of the inference to wrhich they lead. And if further observation
shows that the phenomena continue to progress collaterally, the
circumstance must eventually be accepted as indicating that between
the two phenomena there exists a more or less direct relation which,
in any theoretical consideration of the subject, could not be ignored.
The previous paper, as mentioned, includes results to the year 1877,
but the material since accumulated, available now to 1896, happens
to be especially interesting, and, contrasting in some respects with
the earlier portion, is worthy of being made known, the series
as a whole forming one continuous chain of evidence that much
strengthens the argument for relation. Apart, however, from any
individual opinion on the matter, it is well that, so long as the
phenomena observed remain without explanation, the facts thereof
should be carefully set forth. I propose, therefore, to discuss the
question anew for the whole period 1841 to 1896.

It is unnecessary to say anything in explanation of the results
given in the previous paper. I will therefore proceed to describe
the new work, extending from 1878 to 1896. As before, the mean

Magnetic Declination and Horizontal Force and Solar Spots. 65

diurnal range of declination in each individual month is taken to
represent (relatively to other months) the magnetic energy of the
month, and similarly for horizontal force. By the mean diurnal
range is to be understood a number formed as follows. Means of
the indications at each separate hour of the day being taken through
a month (omitting days of extreme disturbance) the difference
between the least and the greatest of the twenty-four mean values is
the monthly mean diurnal range. The numbers are obtained from
the Greenwich annual volumes, but those for the years 1895 and
1896 not having been yet published, the Astronomer Royal has
kindly allowed me to use them as necessary for the purposes of this
paper. The very small correction for temperature required by the
horizontal force results from 1878 to 1882 as printed, has been duly
applied : beginning with 1883, the values are printed corrected for
temperature.

Thus is obtained, both for declination and horizontal force,
results strictly comparable with those of the previous paper, giving
in all a series of results for fifty-six years. In any graphical repre-
sentation of unexplained phenomena, it is most important that
there should be ready reference to the numerical data on which it is
founded, to enable those who might wish to test the work the means
of so doing without great inconvenience, otherwise the graphical
representation alone can carry no proper conviction. The numbers
for the years 1841 to 1877 are to be found in the previous paper; it
is therefore necessary to give here only the corresponding numbers
from 1878 to 1896. These are contained in Table I. The numbers
for horizontal force are given, as in the previous paper, in parts of
the whole horizontal force taken as unity. The relation in magni-
tude of the westerly force (declination) to the northerly force (hori-
zontal force) will be understood by considering that one minute of
arc of declination corresponds to 0*00029, that is 29 of the hori-
zontal force unit of Table I. Examining now this table, it will
be seen that there is an annual inequality in the magnitude of the
diurnal range, the summer numbers being much greater than the
winter numbers. In order, therefore, to estimate progressive
change, it is convenient to form a number for each month that shall
be free of annual inequality, to allow the progressive change better
to appear. Assuming the different months to be of the same length
this is done, as before, by taking the mean of each twelve consecu-
tive monthly numbers, beginning successively with each individual
month, first, say, with January, next with February, and so on,
taking afterwards the mean of each two consecutive numbers so
found, thus producing annual values free of annual inequality,
which may be presumed to apply to the middle of each successive
month. The process is equivalent, suppose for the number for

G 2

66 Mr. W, Ellis. Relation between Diurnal Range of

January, to adding together half the sum of the numbers for the
preceding and following July, and the sum of the numbers for the
intervening eleven months, August to June, and dividing the whole
by twelve. These new monthly numbers, each expressing an annual
mean, are given in Table II, both for declination and horizontal
force, and they are used with those of Table II of the previous paper
to form the two lower curves of the accompanying plate. I remarked
in my previous paper that the indications of vertical force were for
the present purpose not very manageable ; several different instru-
ments had been employed, and the results presented anomalies.
Certain beneficial alterations were, however, made in 1882, in the
instrument still in use, since which time it has worked better. It
showed a maximum diurnal range in 1883, the descent to a minimum
in 1889, and the subsequent rise to a maximum, although there
remains still some degree of irregularity of action.

As regards sun-spot frequency, Dr. Wolf's monthly values, as
derived directly from observation, are given for the years 1841 to
1877, in Table VI of my previous paper. Those for the years fol-
lowing 1878 to 1896 are to be found in different numbers of his
' Astronomische Mittheilungen,' the values in the later years, after
the death of Dr. Wolf, in 1893, having been similarly prepared by
Professor Wolfer, his successor at Zurich. I am not aware that
these have been before given in a collected form; they will be found
in the annexed Table III. For the purpose of smoothing the acci-
dental irregularities of these observed sun-spot numbers, Dr. Wolf
treated them in the same way as the numbers of our Table I (expressing
magnetic range) were dealt with to form those of Table II. Though
the process was here employed for a reason different to that which
rendered its application necessary in the case of magnetic range, the
similarity of treatment happily makes the resulting numbers strictly
comparable with the magnetic numbers. The smoothed sun-spot
numbers, from 1841 to 1876, June, are to be found in a table con-
tained in Dr. Wolf's paper, "Memoire sur la Periode commune a la
Frequence des Taches Solaires et a la Variation de la Declinaison
Magnetique."* Those from 1876, July, to 1896, added in our
Table III, have been in part taken, from the ' Astronomische Mit-
theilungen ' and in part calculated from the observed numbers con-
tained in the same table. These smoothed values, with those of the
preceding series taken from the paper above mentioned, are used to
form the upper curve in the diagram of collected sun-spot and
magnetic curves. It may be asked why the Greenwich magnetic
variations are not compared with the Greenwich sun-spot record.
But this record having been maintained only for some twenty years,
it was deemed better to adhere throughout to the long Wolf series
* ' Memoirs of the Royal Astronomical Society/ vo 43, p. 199.

Magnetic Declination and Horizontal Force and Solar Spots. 67

rather than endeavour to make reduction from one to the other for a
portion of the series.

Examination of the collected curves will, I think, show that the
extension of the period previously employed by inclusion of the new
resnlts, extending from 1878 to 1896, has produced carves that offer
striking points of interest. Selecting the extreme points of the
several curves, or, which is better, taking the successive least and
greatest values from Table II, and from the corresponding table
of the previous paper, for magnetic values, and from Table III, and
from the corresponding table in vol. 43 of the ' Royal Astronomical
Society Memoirs,' for smoothed sun-spot values, the following epochs
of minimum and maximum are obtained : —

Table of Epochs of Magnetic and Sun-spot Minima and Maxima.

Excess above sun-spot

Magnetic epochs.

epoch.

o

Sun-

0

Phase.

spot

g

^

bjQ

1

Declina-

Hori-

Mean

epoch.

1

O O

g o
,-< '-3

5

tion.

ZOXlt&I

force.

magnetic.

J

'o^

§ «

<t> M

w

fi

W

^

y-

t).

y-

1

Minimum

1844-3

1842 -9

1843 -60

1843 -5

+ 0-8

-6-6

+ 0-10

2

Maximum

1848-1

1849 -0

1848 -55

1848-1

o-o

+ 0-9

-f-O-45

3

Minimum

1857 '2

1855 -1

1856 -15

1856-0

+ 1-2

-0-9

+ 0-]5

4

Maximum

1860 -6

1860 -2

1860 -40

1860 -1

+ 0-5

+0-1

+ 0-30

5

Minimum

1867-5

1867 -6

1867 -55

1867 '2

+ 0-3

+ 0'4

+ 0-35

6.

Maximum

1870 -8

1870 -9

1870 -85

1870 -6

-t-0-2

+ 0-3

+ 0-25

7

Minimum

1879 -0

1878 -7

1878 -85

1879-0

o-o

-0-3

-0-15

8

Maximum

1884 -0

1883 -8

1883 "90

1884-0

o-o

-0-2

-o-io

9

Minimum

1889-5

1890 -0

1889 -75

1890 -2

-0-7

-0-2

-0-45

10

Maximum

1893 -5

1894 -0

1893 -75

1894 -0

-0-5

o-o

-0-25

Mean excess (five epochs of minimum) ....

+ 0-32

-0-32

o-oo

Mean excess (five epochs of maximum) ....

+ 0-04

+ 0-22

+ 0-13

G-eneral mean e

+ 0-18

-0-05

+ 0-06

The mean magnetic epoch is taken to be the mean of those for
declination and horizontal force. These vary somewhat for the
epochs Nos. 1 and 3, but the mean epoch in both cases falls near to
the sun-spot epoch.

Taking the differences between successive epochs of minimum and
maximum 1 — 2, 2 — 3, &c., the following intervals are found : —

68

Mr. W. Ellis. Relation between Diurnal Range of

Intervals between successive Magnetic Epochs.

Min.

to

Max.
1_2.

Max.

to

Min.
2-3.

Min.
to

Max.
3—4.

Max.

to

Min.
4—5.

Min.

to

Max.
5—6.

Max.

to

Min.
6-7.

Min.

to
Max.

7—8.

Max. Min.

<o to

Min. Max.

8—9. 9—10.

4-95?/ 7-6Cty 4-25y 7'15y 3'30y 8'(% 5'(% 5'85?/ 4'00//

Intei'vals between successive Sun-spot Epochs.
4-60?/ 7-90?/ 4-10y 7'10?/ 3'40?/ 8'40?y 5-(% 6'20//

FIG. 1.— Intervals between successive Sun-spot and Magnetic Epochs compared.

The thick line shows the variation in length of the interval between successive sun-
spot epochs, and the thin line that between successive magnetic epochs. 1 to 2,
3 to 4, &c., indicate intervals .from minimum to maximum, and 2 to 3, 4 to 5,
&c., those from maximum to minimum.

These numbers are represented in a graphical form in fig. 1. They
fun so closely together that it became necessary, iii the figure, to
diminish the magnetic intervals by one hour, otherwise much of the
magnetic curve would have fallen so near to the sun-spot curve as to
become obliterated thereby. The general similarity of the variations
in length of successive magnetic and sun-spot intervals, alternately
from minimum epoch to maximum epoch, and from maximum epoch
to minimum epoch, is thus very clearly seen. When the variation
of the magnetic interval is large, that of the sun-spot interval is also
large, and when the one is small, the other is also small.

The mean of the five intervals from minimum epoch to maximum
epoch is for the magnetic effect 4*31?/, and for the sun-spot effect
4'18i/; the mean of the four intervals from maximum epoch to
minimum epoch is for the magnetic effect 7'15y, and for the sun-spot
effect 7'40y. Whole period for magnetic effect 1T46?/, and for sun-
spot effect ll-58y.

Taking further from the table of epochs, instead of successive
intervals, the successive periods, 1 — 3, 2 — 4, &c., we have —

Magnetic Declination and Horizontal Force and Solar Spots. 69

8—10.

Length of Magnetic Period.

1—3. 2—4. 3—5. 4—6. 5—7. 6—8. 7—9.
I2'55y ll-85y H'40y 10'45y ll'30y 13'(% 10'90y

Length of Sun-spot Period.
12-50y 12-OOy ll'20y I0'50y ll'SOy 13'^Qy ll-2Qy 10'OOy

The odd numbers, 1 — 3, 3 — 5, &c., indicate the periods between
successive minimum epochs, and the even numbers those between
successive maximum epochs. They are represented graphically in
fig. 2. The similarity of the variation in length of the complete

FIG. 2. — Length of Sun-spot and Magnetic Periods compared.

K. 03

10

The thick line shows the variation in length of successive sun-spot periods, and the
thin line that between successive magnetic periods. Odd numbers indicate
periods from minimum to minimum, and even numbers periods from maximum
to maximum.

magnetic and sun-spot periods, amounting to above three years, is
here well brought out. Mean magnetic period ll*42y. Mean sun-
spot period ll'57y. These values differ slightly from those above
given, owing to the numbers becoming here combined in a little
different way. Fig. 2 suggests a suspicion that the period decreases
in length through several periods, then increases for several periods,
and so on. But what may be the order of such variations is a
question to which at present it does not seem possible to give any
reliable answer.

Examining further the collected curves, it is seen that the maximum
points of the curves have at different epochs very different degrees of
intensity. If for each curve we arrange the epochs of maximum in
order, with reference thereto, we find as follows : —

70 Mr. W. Ellis. Relation between Diurnal Range of

Order of Epochs with reference to intensity of Sun-spot and
Magnetic Effects.

Sun-spot
eDoch.

1870

Corre-
sponding
number.

140-5

1848

131-5

1860

97-9

1894

87-9

1884

74-6

Declination
epoch.

1870

Corre-
sponding
number.

12-76

1848

12-46

1860

11-42

1894

10-42

1884

9-84

Hor. force
epocli.

1870

Con-e-
spoxiding
number.

308

1860

295

1848

268

1894

233

1884

221

In each curve the greatest and least maxima are those of 1870 and
1884 respectively, and the order in each case is similar excepting
for the epochs of 1848 and 1860, which in horizontal force are
reversed in position, although otherwise falling in with the general
order of fche other curves. The horizontal force observations have to
be corrected for the effect of temperature (a correction not required
for decimation), and in the years 1848 and 1860 the magnets were in
the original upper magnet room, in which the diurnal range of tem-
perature was considerable, rendering difficult the determination of
the actual temperature of the magnet (a bar 2 feet in length), and
this may possibly account for the apparent displacement of the 1848
and 1860 epochs of maximum in horizontal force. In 1864 an under-
ground basement was specially constructed for the magnets, in
which the variation of temperature is small, and in this apartment
the magnets have since remained. As regards the minimum points
of the curves, the sun-spots at the epochs of 1856, 1867, 1879, and
1890 practically disappear, but not so at that of 1843, at which epoch
the most elevated of the magnetic minima, both in declination and
horizontal force, occurs, being so far in harmony with what has been
pointed out as to the behaviour at maximum.

Considering that the irregularities in the length of the sun-spot
period so entirely synchronise with similar irregularities in the
magnetic period, and also that the elevation or depression of the
maximum points of the sun-spot curve is accompanied by similar
elevations and depressions in the two magnetic curves, it would
seem, in the face of such evidence, that the supposition that such
agreement is probably only accidental coincidence can scarcely be
maintained, and there would appear to be no escape from the conclu-
sion that such close correspondence, both in period and activity,
indicates a more or less direct relation between the two phenomena,
or otherwise the existence of some common cause producing both.
The sharp rise from minimum epoch to maximum epoch, and the
more gradual fall from maximum epoch to minimum epoch, may be
pointed out as a characteristic of all three curves. The similarity of

Magnetic Declination and Horizontal Force and Solar Spots. 71

the little drop shown in all the curves in 1882 and 1883 is also
striking.

Observation has been supposed to indicate that the magnetic effect
follows the sun-spot effect, so that a retardation, or what has been
called a "lagging," of the magnetic effect exists, but the evidence for
this has never appeared to me to be quite satisfactory. The fewer
comparisons of sun-spot and magnetic epochs given in my first paper
seemed to give support to such supposition. But taking the more
extended comparison contained in the preceding table of epochs, it is
seen that the declination epoch is on the whole retarded by Q'lSy (frac-
tion of year), whilst that of horizontal force is accelerated by O'QSy.
Mean retardation = 0'Q6y. Looking at the irregularities in the num-
bers on which these means are founded, it seems doubtful whether,
without a yet more extended comparison, any real difference or
definite lagging can be said to exist. Two things, however, may be
noted. One is, that the differences in the early part of the table are
inclined to positive, and in the later portion to negative values.
What will happen when further results are included ? Considering,
however, the strength of the evidence for some form of relation that
has been shown by what has preceded to exist, it seems in every way
probable that the individual differences of epoch represent in great
part accidental residuals. Rather, indeed, is it not likely that to
some extent small differences or irregularities may be expected to
appear, when it is remembered that we are comparing together solar
and terrestrial phenomena, to us probably only incomplete manifest-
ations of involved actions, about which little is known and of which
the cause is obscure. Especially, too, when, as regards the terres-
trial effect, the magnetic variations are deduced from the observa-
tions at a single station, Greenwich. Consider also the composite
character of the sun-spot phenomena at about the time of minimum
epoch. After a maximum, as the following minimum epoch is
approached, sun-spots become in successive years fewer in number
and smaller in magnitude, the regions north and south of the solar
equator in which spots appear tending, as the spots become less
numerous, more and more towards the equator, until at the minimum
epoch the spots disappear. At the same time, spots of, as it were, a
new cycle come into view in high latitudes, and become rapidly more
numerous and important until another maximum is passed, after
which the spots become again less numerous, the regions in which
they appear approaching as before the solar equator, until at the
following minimum again the spots disappear. Thus the curve at
the minimum epoch seems to be produced by the junction of an
expiring cycle with a new outburst becoming rapidly active.

In tabulating the magnetic records at Greenwich, ifc has been the
practice to include all days (except those of extreme disturbance),

7'2 Mr. W. Ellis. Relation between Diurnal Range of

consequently on many that are retained considerable disturbance
exists. Now abnormal disturbance is more frequent, as well as
greater in magnitude, towards the epochs of maximum sun-
spot frequency, and tends almost to disappear at the epochs of
minimum frequency. For instance, the sun-spot minima of 1856
and 1879 were both remarkable for little irregular disturbance,
especially the latter, whilst at the sun-spot maximum of 1870, dis-
turbance was unusually frequent and considerable in amount, the
difference in this respect being very striking, as a mere inspec-
tion of the photographic records for the epochs mentioned would
abundantly show. In preparing the former paper the question,
therefore, did arise whether and to what extent the increased diurnal
magnetic range, about the periods of sun-spot maximum, might be
due to the greater prevalence at such periods of abnormal disturb-
ance, but I then satisfied myself, by examination of the records, that
this circumstance exercised no important influence on the results.
Now, however, I can substantiate that conclusion by numerical data.

It is known to those acquainted with magnetic work that in order
the better and more readily to compare together the diurnal magnetic
inequalities for different places it has been the practice, since the
year 1889, to tabulate the records at British observatories for five
selected quiet days in each month, the selection of days being made
by the Astronomer Royal. These quiet day results, unaffected by
magnetic disturbance, show only the solar diurnal variation, and are
now available for Greenwich, from 1889 to 1896. Mean hourly
values being formed in each month, from the indications on the five
quiet days, the diurnal range of declination and horizontal force was
found in the same way as before described for the full monthly
values, the resulting numbers being given in Table IV. These were
further treated for removal of the annual inequality, in the same way
that the numbers of Table I were treated to form those of Table II.
The values so found are contained in Table Y, and are those repre-
sented graphically in fig. 3, adding thereto the graphical representa-
tion of the sun-spot and magnetic phenomena, for the corresponding
years from the long series 1841 — 1896, in which all days (excepting
those of extreme disturbance) were included.

The thick line in declination and horizontal force (fig. 3) shows the
diurnal magnetic range as found from employing all days, including
many of magnetic disturbance. The thin line, formed from five
selected qniet days in each month indicates the true solar diurnal
range. Two things thus appear. Firstly, that the solar diurnal
range (thin line), in which the influence of irregular magnetic dis-
turbance has no part, is itself really affected with a periodical varia-
tion similar to that of sun spots. And secondly, that the effect of
including disturbed days (thick line) alters the solar diurnal range

Magnetic Declination and Horizontal Force and Solar Spots. 73

Fia. 3. — Sun-spot Frequency and Diurnal Eange of Decimation and
Horizontal Force compared.

^10

1

9*

^ 8

|/

0-3 •(

5

£•<

•0012

1

M

\

n

The upper curve is that of
sun-spot frequency. The middle
and lower curves are those of
diurnal range of declination and
horizontal force respectively ;
the thick line is that resulting
from the employment of all
days, and the thin line that
found from five selected quiet
days in each month.

(thin line) in a small degree only as compared with its variation
with sun spots, from which it follows that the diurnal range as found
from employing all days (thick line), as in the 1841 — 1896 series, may
be taken to represent the solar diurnal range (thin line) the varia-
tion of the former being essentially that of the solar diurnal range.

The explanation of the circumstance that the difference in the
amplitude of the magnetic range, as found from five selected quiet
days, and from all days, is so small as compared with the variation
in amplitude of both with variation of sun spots, would seem to be
that the effect of irregular magnetic disturbance is such as sometimes
to increase the value of the magnetic element and sometimes to de-
crease it, these opposite effects combining to neutralise each other to
such an extent as to influence the solar diurnal range in an unim-
portant degree only, as compared with its considerable variation
with that of sun spots, which is the point that is here material.

Although the change produced in the character of the diurnal
magnetic movement by including disturbed days is not a matter that
possesses significance as regards the purposes of this paper, it be-
comes in other respects one for consideration. It is, however, a
question related toothers that would be better discussed in a separate
communication.

74 Mr. W. Ellis. Relation between Diurnal Range of

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Magnetic Declination and Horizontal Force and Solar Spots. 75

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76 Mr. W. Ellis. Relation between Diurnal Range of

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Magnetic Declination and Horizontal Force and Solar Spots. 77

Table IV. — Monthly Mean Diurnal Range of Declination and Hori-
zontal Force as determined from the observations on five selected
quiet days in each month.

I

Tear.

Jan.

Feb.

Mar.

Apr.

May.

June.

July.

Aug.

Sept.

Oct.

Nov.

Dec.

Declination.

1889

2-9

4-7

6-4

9-6

8-3

8'4

8-0

8-0

7-5

6-1

4-3

3-2

1890

3-9

5-0

6-7

9-3

8-3

8-5

9-4

9-5

6-6

5-9

4-4

3-9

1891

4-0

4-3

9-1

8-7

11-4

10-3

10-9

9-8

10-1

9-0

6-7

3-9

1892

6-4

7-1

9-7

10-2

13-0

13-4

12 -d

13-2

10-9

9-5

4-9

6-1

1893

7-0

6-6

11-4

12-7

14-1

12-0

13-0

12-2

11-7

9-2

7-5

4-2

1894

6-0

8-6

10-3

13-1

12-5

10-3

10-9

12-2

8-9

6-3

5-3

3-9

1895

2-9

6-9

9-5

11-9

10 -y

14-6

11-8

11-9

9-6

6-9

4-6

3-9

1896

7-2

5-3

9-1

10-9

9-5

95

9-7

9-4

11-0

6-9

4-0

3-6

Horizontal Force.

1889

42

79

103

177

192

202

185

235

183

155

101

59

1890

66

102

111

182

186

219

196

203

158

166

76

60

1891

10 »

106

155

183

264

280

254

267

244

217

162

63

1892

171

164

205

260

270

258

2S5

304

227

205

153

109

1893

118

181

240

287

287

289

308

280

272

226

201

120

1894

130

165

197

289

287

329

272

303

238

206

179

117

1895

72

189

202

318

284

305

292

251

209

195

117

61

1896

124

139

183

236

213

210

203

218

275

172

110

52

Table Y. — Annual Means of the Monthly Mean Diurnal Range of
Declination and Horizontal Force as determined from the obser-
vations on five selected quiet days in each month. (As in Table II,
each number represents an annual mean of which the month itself
is the middle point.)

Year.

Jan.

Feb.

Mar.

Apr.

May.

June.

July.

Aug.

Sept.

Oct.

Nov.

Dec.

Declination.

1889
1890
1891
1892
1893
1894
1895
1896

/

:
6'57
6-91
8-73

10-00

10-14
8-51
8-93

6-56
7-01
8-86
10-15
10-09
8-39
8'83

/
6-56
7-22
9-05
10-14
9-95
8-50
8-56

6-49
6-79
8-28
9-77
10-09
8-90
8-76

6-55
6-76
8-50
9-78
10-13
8-70
9-07

6-57
6'83
8-61
9-83
10-17
8-59
8-99

6-62
7-35
9-25
10-10
9-80
8-72
8-26

6-75
7-43
9-47
10-08
9-71
8-75
8-07

6-77
7-59
9 '64
]0-07
9-59
8-76
8-03

6-73

7-86
9-70
10-09
9-35
8-82
8-08

6 '72

8-09
9-64
10-18
9-H
8-81
8-06

6-75

8-18
9-66
10-21
9-04
8-78
8-05

Horizontal Force.

1889
1890
1891
1892
1893
1894
1895
1.-96

144
145
194
215
235
224
210

146
147
200
214
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Relative Retardation between Components of a Stream of Light. 79

" On the Relative Retardation between the Components of a
Stream of Light produced by the Passage of the Stream
through a Crystalline Plate cut in any Direction with
respect to the Faces of the Crystal." By JAMES WALKER,
M.A. Communicated by Professor R. B. CLIFTON, F.R.S.
Received February 29— Read March 10, 1898.

The relative retardation between the components of a stream of
light produced by the passage throngk a crystalline plate can, as is
well known, only be determined in finite terms in a limited number
of special cases. Tn general it is necessary to be content with an
approximate solution, and those hitherto published have, as far as I
have ascertained, never been carried beyond terms of the second
order with respect to the sine of the angle of incidence of the light,
while they do not readily lend themselves to a further approxima-
tion. The following method of dealing with the problem, which,
except for the labour of calculation, can easily be extended to
terms of any order, may then be of practical use, and, as leading to
an interesting relation between the corresponding terms in the
development of the roots of a certain biquadratic equation, of some
interest.

1. Let the pla.ne of the paper represent the plane of incidence, OT
represent the normal to the front of the incident plane wave, OP and
OP' the normals to the fronts of the two corresponding refracted
waves ; then if OM, ON, and ON' represent the spaces these waves
would traverse in unit time, planes through. M, N, and N' perpendi-
cular to OT, OP, and OP' respectively will represent the position*
that the fronts of the waves would occupy in unit time after leaving-
0, and these planes will, by Huygens' principle, intersect tl e
surface of the crystalline plate in one straight line, projected on the
plane of the figure in the point C.

Let OT, OP, and OP' meet the second surface of the plate in the

VOL. LXIIf.

-80 Mr. J. Walker. Relative Retardation between Component*

points T, P, and P' respectively, and through P and P' draw PE,
P'E' perpendicular to OT, meeting it in the points E and E' ; through
E' draw E'T' parallel to the surface of the plate, meeting PE in T'.

Draw OD normal to the plate, meeting the second surface in D,
and let the wave fronts CN and CN' meet this normal in the points
Q and Q'.

Then the triangles OPD, CON, CQO are similar, as are also the
triangles OP'D, CON', CQ'O, and the triangles T'E'E, COM.

The relative. retardation, measured in time, of the two waves after
both have traversed the plate, is represented by

OP_OEI _ roF_ojn _ OP _or EE'

ON OMJ [ON' OMj ~ ON ON~/

ON2 ON'2 OC~~OC.ON2 OC.ON'2

DP'J " OQ OQ''

Hence if the axis of Z be normal to the plate, and

Z = 1 ZX + wY-HiZ = i

are the equations of the refracted waves in unit time after passing
through O, their relative retardation, measured in length in air, after
both have traversed the plate is

A = i;T(Wi — ?z2),

where v is the propagational speed in air, and T is the thickness of
the plate.

Also i being the angle of incidence, and w the azimuth of the
plane of incidence with respect to that of XZ,

Z = sin i cos w/v, m = sin i sin wfv.

2. In applying this result to the case of a plate cut in any manner
from a, biaxal crystal, let the surface of the plate on which the light
is incident be taken as the plane of XT, the plate lying on the side of
Z positive, and let the plane of XZ be taken so as to contain the
least axis of elasticity of the crystal.

Let O#, O?/, Oz be the axes of elasticity, and the angle yoY = 0,
the angle zoZ = x, then the transformation from the axes of elasti-
city to the new axes may be effected by the following successive
•transformations, each in one plane : —

(1) Through an angle 0, in the plane of xy, from Ox, Oy to

0*,, Oy.

(2) Through an angle x, in the plane zx^ from Oz, Oxt to OZ, OX.

of a Stream of Light passing through a Crystalline Plate. 81
The formulas for these transformations are —

x = Xi cos 0— Y sin 0, ?/ = #t sin 0-f- Y cos 0,

Xi = X cos x + Z sin x, z = — X sin x + Z cos x»

from which we obtain

x = X cos 0 cos x~~Y sin 0+Z cos 0 sin x>
?/ = X sin 0 cos x + Y cos 0 + Z sin 0 sin x>
2 = —X sin + Z cos -

Now the equation to the wave surface referred to the axes of
elasticity is

«, &, c being the principal wave velocities, and the condition that the
plane

nz =

should be a tangent plane to it, is obtained by eliminating p between
the equations

Hence the condition that in the new system of co-ordinates the
plane

mY+rcZ = 1

should touch the wave surface is found by eliminating^ between the
equations

(I cos 0cos x~ m sin 0-j-w cos 0 sin

(Z sin 0 cos x + m cos 0 + TO sin 0 sin x)2 (Zsin x~ _

*- 2-2

The result of this elimination is a biquadratic in w, which, from
the nature of the problem, has two real positive and two real nega-
tive roots, and if n\, n2 are the positive roots of the biquadratic, the
relative retardation required is

3. Before proceeding with the general case, these results may be
applied to certain simple cases : —

u 2

82 Mr. J. Walker. Relative Retardation between Components

(1) Let the plate, be cut from a uniaxal crystal, then writing
6 = 0, equation (i) gives the two equations

_p2 = a- and

(p2— c2) {(I cos x + n sin %)2 + m2} + (p-— a?) (I sin x—n cos x)2 = 0,
and the values of n are given by

2 + <) -1+ (a2-c2) (I sin x— w cos x)2 = 0,
whence

1 /_ 0 sin2 1

a

2sin2x) (l— c2sinH'/V-) — c2(a2— c2) sin2x c
+ (a2 — c2) sin x cos x cos ?0 sin i/v} — (a2 cos2x + c2 sin2x)
and

A _ ^/v~— a2sin2i (a.2-— G2)sin x cos x cos w sinz
T ~ a a2 cos2 x + c2 sin2 x

v/fVr cos2 x + c3 s^n2 x) (^'2— c2 sinzi) — c2(a2 — c2) sin2 x cos2 w sin8*
a3 cos2 x 4- c2 sin2 x

(2) Let the plate be cut from a biaxal crystal perpendicularly to
the mean line ; then taking the axes of elasticity as the co-ordinate
axes, the biquadratic in n becomes

(7rcT~ -f cVm2 + aW) (P + m2 + w2)

-{(fcs + c8) Z2 + (c3 + a2)m3+(a3 + &2)»2} + l = 0,

or

2)} {l-62/2-«2m2} = 0,
and %i, n2 being the positive roots of this equation
(»i -O2 aafc3 = («2 4- 6s) - 62 (c2 + a2) Z3 - a2 (6s + c2) m2

and

" 'V 4- c2) sin2 w\ sin2 i

T2

— 2ab \/(vz— c2 sin'- i) { v~— (62 cos2 w + a2 sin2 «t?) niir t}

:

of a Stream of Light passing through a Crystalline Plate. 83
4. Keturning to the general equation (i), write

A' = cos 0 sin x? A = cos 0 cos x cos w— sin 0 sin w,

B' = sin 0 sin x» B = sin 0 cos % cos w-j-cos 0 sin w,

C' = cos x, C = — sin x cos w.

Then the equations between which.jp has to be eliminated become

! . . sin A2 /63 \ /c2 \ / „ „ sin A2 c3 \ a3 \

A'« + A- - --1 )(-a-l + B'» + B
\ v / \p~ I \f I \ v

~ »

„ sin i\* fa* \ fbz \
+ C'«+C- ---!--!= 0.

\ i' / \p- / V /

1 3 sin

and since

3

/. . sin A3 /—^ _. sin A2 /' _ sin A2 sin2^ 1

f Ar*+A - + B^+B - -f-lCn-fC - = n*+—— = — ,
v } \ v / \ v I tr jr

the result of the elimination becomes

and multiplying out and arranging the terms, this equation may be
written

sn

7 sin i . I sin~ i. , /_ sin i _ sin3 i\

»'-»*— » 3+(c»+^-Hn-2(6'--+^-^-)

^-=0.. . (ii),

where

XA'iV

~, »

61 ~ "SA^I^" ' 3 ~ x ~ ""73"2"

/2/--c3)

' *'

84 Mr. J. Walker. Relative Retardation between Components

Now the roots of equation (ii), p, q, r, s will be functions of sin i/v,
and expanding these in series proceeding according to powers of this
quantity, we may write generally

p =

2 =

sin*

sin* i

i~r+

'Pz v*

sin *

sin3 *

V

•?*--

sin*

sin2 *

V

pS

sin*

sin2*

V

*-yH

But

, sin i sin2 * 7 sin i . sin3 i

2p = 2c?! - , 2pg = C0 + c2 — — , 2pgr = 2&1-^-+2&8 — -,

sin2 1 sin4 i
^pqrs = ani-a<i — — + a4 — — ,

and therefore equating the coefficients of like powers of sin ijv on the
two sides of these equations, the coefficients p, 5, r, 5 may in general
be determined in succession by means of linear equations, provided
we can determine _p0, q0, r0, s0t which may be at once done, since they
are the roots of the equation

Moreover, when this method is practicable, the roots of the
biquadratic take the following form

where

s

" l!

sin- * sin *

Ii «"

^ sin* ^

si n ^ sin0 * sin

sn sn sn

v £3 i>5

For suppose that this is true as far as the terms involving
""*, and let a, /3, 7, £ denote the sum of the terms in wlt 7r2,
/>2 respectively of an order less than n, then we may write

q = — a + 7 + /t2, r = y3 -j-

of a Stream of Light passing through a Crystalline Plate. 85-

and neglecting the products of the /*'s with one another, and with 7*
and d. since such products will introduce terms that we shall not
require, we have

Hence if pn, qn, rn, sn denote the coefficients of sinnilvn in p, 3, r, *•-
respectively, and [ ]rt denote the coefficient of sin^jv" in the expres-
sion within tbe vinculum, the equations that determine these quan-
tities are —

(1) If n = 2m

= R2m, say,

= S2wt, say,
and from the first and third of these equations, we have, unless

zm — 0,

Avhich relations hold whatever m may be.
(2) If n—

— 0,

= T2m+i, say,

= 0,

and from the second and fourth of these equations

and when wi>0, <?2tft+i = 0, so that r2m+1 = £>2;»j+i (w>0).

86 Mr. J. Walker. Relative Retardation between Components

Leaving then for the present the case in which a03 = A2) the roots
have the form given above, and

jwi4"vl -. JJ(\ "U i 4 f1! -1-2/W+l

1 'W pjMt

~~ "2 3 tf~2 '

—

a,r — /V a<r— /V

whence

A

2ft 1 4- (ao2 -*- A2) ^i 8^u * i^- + S2 sin'-

__lRi+S4 sin4 1

2 ^ /J y.,4 '

the terms of which may be readily calculated in succession.

5. It is now necessary to consider the case reserved above, in
which oo3 = /302- When this occurs, the two refracted waves, corre-
sponding to normal incidence of the light, traverse the plate with the
same velocity, and hence the plate is perpendicular to an optic axis.
The case, then, of a plate cut perpendicularly to an optic axis
requires a special investigation.

Now for a plate so cut —

0 = 0, cos X= v/(^-c^/v/K-c^, sinX =
and the biquadratic (ii) has the form

_ , sin i . / ' , , sin2 i\ /, r sin

^here

= -cos w •

, sin- i , sin4

p V(tf — 1>~) (b~— c2),

.

of a Stream of Light passing through a Crystalline Plate. 87
whence writing n + \di - - for n, tbe equation becomes

/ sinai\ . 7 sin3 i

» -H <fc+<Ji — 3— ]«' — 263— — '

sn2 sn

"where

2 1_

C» ~ - Ji, <* - ^

-^ 8-c8 . cos w,
If, (a°--Z>-)(62-c-

'i, - ^ { aV + i • ^±-^(a2-62) (63-c2)

L'jt us, in the first place, neglect the coefficient of nt then we
liavc —

sn

V v V"

+ ±[*r{V4*^V<r-*>-ti'*g

±

sini / f (64— aV)s , 64 + aV <2 \ siir q

A / 1 ~r i T^ v T^T 7~T'> >>\ — "o 7"o COS W ? ~

v V t463(a4— 62) (/»*— c') lz J v- J

iind the roots are ± (TT -}-/>), ± (T— />), where

Sln^ Bm
*_+J%

and writing for shortness

P = (a'-W--^), Q = i(a2-62

\\G have

88 Mr. J. Walker. Relative Retardation between Components

Suppose now that the actual roots or the biquadratic are —

, — 7T - />-f-/3, 7T — ^> + 7, - 7T -|- p + C ;

then

= 0,

«/J7« + O-r/0 7« W

+ (^2-/>2)(/3-«) (^-7)
-(^-/>)2{^ + (^-r/>) (/8-« = 0,

which, on reducing and simplifying, become

2 = 0,

= 0.
Let

with similar expressions for /3, 7, B ; then the terms involving sinH'/t;2
give—

a2 + A + 72+c2 = 0, a2 + 72 = o,

. • . 72 = — a.z and ^ = — /32,

and from the terras involving sin3V/u", we obtain —

7s +Pia2 + £2 = 0,

of a Stream of Light passing through a Crystalline Plate. 89
whence

«2 = #! = -73 = —^ —

and 73 = — a3, £3 = —

Again, from the terms involving sin4i'/y4 —

= 0,

whence a3 = -fa = -73 = 3, = _ ?L = __ . J,»,

and a4 = —74, /34 = — 64.

Similarly the terms involving sin5 i/v5 give —

) +^1(^4+ ^) = 0,
+ 2 J3i_p2 +p*pa) «2 + 2po02a3 = 0,

*3— pz) +«22 = 0, or a4—/34 = 0.

Hence

Pbpi pi 4P ' 4PS

and a-0— -75, /?5 = — r>5,

and so on.

Hence, as far as terms of the fourth order,

— _o - sin2** sin3 i . sinS'

__._ smn 55Ui sin*t

where

«2 = — — cos w , a3 = — cos* ?y ,

— (&4 — a2c3)2 sin2 w } cos z^^

90 Relative Retardation between Components of a Stream of Lwht.

and the difference of the positive roots being 2/> + a — 7, we have, to
the same degree of approximation,

su

v/Oa-62)(Zr-c-) sin*', //4-aV shri

-p- -•— -l-i.-ji-cos*—

1 (a2-c2)2 . ., '

a. . .,

' S1

*> T* F(a' - 6*)

x (2(a2-68) (63-c3) (/>4

6. The proposition on which the above investigation depends was
first suggested to me by an analogous theorem given by MeCullagh,*
in connection with the surface of wave-slowness, f or, as he terms it",
the surface of refraction or index surface; in fact, the one may be
deduced from the other by reciprocating with respect to a sphere of
unit radius concentric with the surfaces.

I have since found that Zech^ has employed the same principle
for the determination of the rings of biaxial crystals, but his method
of dealing with the biquadratic equation is essentially different from
that given above, and leads only to the determination of the terms of
the second order.

My thanks are also due to Mr. J. L. S. Hatton for some useful
suggestions that led me to the adoption of the above methods of
approximation .

* ' Collected Works,' p. 46.

t The first pedal of the wave-surface is sometimes erroneously called the surface
of wave-slowness j but, as Sir William Hamilton calls the inverse of the wave-
velocity the wave-slowness, the inverse of this surface, or the polar reciprocal of
the wave-surface, is properly the surface of wave-slowness. That this was the
name given to the polar reciprocal of the wave-surface by Sir William Hamilton
appears from Lloyd's " Eeport on Physical Optics " (' Collected Works,' p. 122), and
from MeCullagh (' Collected Works,' p. 96), though in his papers he calls it the
surface of components of normal slowness.

J ' Fogg. Ann.,' vol. 97, j>. 129 ; vol. 102, p. 354.

Extension of Maxwell? & Electro-magnetic Theory of T^iglit. 91

<%An Extension of Maxwell's Electro-magnetic Theory of
Light to include Dispersion, Metallic Reflection, and Allied
Phenomena," By EDWIN EDSER, A.R.C.S. Communicated
by Captain W. *DE W. ABNEY, C.B., F.E.S. Received
February 18,— Read March 10, 1898.

(Abstract.)

A dielectric, like an electrolyte, is assumed to consist of molecules,
each comprising, in the simplest case, two oppositely charged atoms
at a definite distance apart. In a homogeneous medium, when not
subjected to electric strain, these molecules will be arranged in such
a manner that any elerrfent of volume will possess no resultant
electric moment. If a definite potential difference be maintained
between any two parallel planes in the medium, the positively
charged atoms will move to points of lower, and the negatively
charged atoms to points of higher, potential. Thus two kinds of
molecular strain are produced: firstly, a molecular rotation; and
secondly, a separation in the molecule of the constituent atoms.
Let P be the actual electromotive intensity at any point in the
medium, and D be the electric displacement other than that pro-
duced by the atomic charges. Then

where M is a constant depending on the nature of the medium. The
quantity ] +4?rM represents the specific inductive capacity of the
medium. The actual linear displacement of the atoms is shown to be
small when compared with molecular magnitudes.

Maxwell's equation, expressing that the line integral of the electro-
motive intensity round a closed circuit is equal to the rate of
decrease of the magnetic induction through the circuit, needs no
modification when the propagation of disturbances through the
above medium is considered. Maxwell's second equation is modi-
fied by adding to the total displacement current at any point the
expression 2.qvx, where q is the atomic charge, vx is the velocity of
that charge in the direction considered, and 2 denotes summation
for unit volume.

Subsidiary equations for the atomic vibrations (rotational and
separational) are given, and the refractive index is finally deter-
mined in the form

cV c'V

which is the most general form of Ketteler's dispersion formula.

92 Extension of Maxwell's Electro-magnetic Theory of Light.

p?x is found to be equal to the specific inductive capacity of the
medium, as previously determined.

For a medium which might be compressed without altering the
period of vibration of the constituent molecules, Gladstone and
Dale's law, in the modified form /r — lac density, would follow.

Double refraction, in case of a uniaxial crystal, is explained on the
assumption that the molecules are arranged with their axes parallel
to a certain direction. Electrical disturbances perpendicular to this
direction will produce a molecular rotation, whilst those parallel to
this direction will produce an inter-atomic separation. The doubly
refracting nature of a dielectric when subjected to electric strain is
thus explained ; and it is pointed out that Lord Kelvin was led to
postulate a crystalline structure similar to the above to account for
the pyro-electric properties of tourmaline, ,&c.

For infinitely quick vibrations the refractive index of the above
medium will be equal to unity, a result possibly explaining the
action of material bodies on Rontgen radiations.

Assuming a metallic or quasi-metallic substance to have a struc-
ture essentially similar to that described above, with the addition
that a viscous term is included in the equation for the atomic vibra-
tion, the refractive index of a metal is found in the form of a
complex quantity, the imaginary part of which is essentially positive.
The ordinary laws of metallic reflection, as deduced by Cauchy and
others, will therefore hold. It is shown that for those metals in
which the real part of the square of the refractive index is a large
negative quantity, the velocity of propagation of light will be in-
versely proportional to the molecular viscosity. Since Mr. Tomlin-
aon has shown that for those metals which he had examined the
order of magnitude of the specific electrical resistances was the same
as that of the molecular viscosities, a connection is established
between the velocity of light and the* electrical conductivity of a
metal, agreeing with that obtained experimentally by Kundt.

The initial assumptions in the above investigation are similar to
those made by Helmholtz in his papers on the "Electro-magnetic
Theory of Dispersion."* Some doubt has been expressed as to
whether Helmholtz's developments are in consonance with Maxwell's
theory .f In the present case the principle of Least Action is not
used. The dispersion formula obtained differs from that of Helm-
holtz, but bears a general resemblance to that obtained by Rieff in
his modification of Helmholtz's theory. J A more definite physical
significance is, however, given to the various constants introduced.

* < Wied. Ann.,' vol. 48, pp. 389—405, 723—725.

f O. Henviside, ; Electrician,' vol. 37, August 7, 1896.

J ' Wied. Ann.,' vol. 55, pp. 82—95.

Significance of Functional Metabolism in the Plant. 93

CROONIAN LECTURE. — " The Nature and Significance of Func-
tional Metabolism in the Plant" (Das Wesen und die,
Bedeutung des Betriebsstofwechsels in der Pflanze). By
WILHELM PFEFFER, Sc.D. (Cantab.), of the University of
Leipzig, For. Mem. R.S. Received March 9, — Read March
17, 1898.

(Translation of Author's Abstract.)

The fact that a mould fungus will thrive in a solution, from
which, with the exception of certain inorganic acids, it can obtain
nothing but sugar, affords proof that the elaboration of these food
substances in metabolism not only provides the numerous carbon com-
pounds which are concerned in the construction of the plant, but also
serves as a sufficient source of energy for the performance of its func-
tions. For in the plant, as in the animal, vital activity comes to
a standstill if the conditions and the energy necessary for the discharge
of its functions are not constantly provided by means of profound
•chemical decompositions. Just as in animals, a great amount of
internal and external work has to be accomplished, in order to carry
on and maintain the action of the organism. Hence the greater
part, and in the mature plant even the whole, of the food absorbed
is devoted to this functional metabolism, so that only a certain
fraction of the sugar which has disappeared from the solution is
to be found in the resulting crop of fungi, in the form of various
carbon compounds. The rest of the sugar has been burnt up to form
carbonic acid and water ; that is to say, it has been sacrificed to the
physiological combustion, which in these, as in most plants, is
indispensable for gaining an adequate amount of kinetic energy.

But, just as man is able to obtain driving power, not only from the
combustion of wood and coal, but also from the explosion of gunpowder
or dynamite, so there are certain of the lower plants which gain
their whole kinetic energy by means of chemical transformations and
decompositions, which go on without the participation of free
oxygen. Although the careful consideration of such organisms is
indispensable for any correct estimate of functional metabolism, yet
we may, in the first instance, limit our attention to oxygen-respira-
tion, i.e., to the functional metabolism of aerobic organisms.

In any case it is only after elaboration that food acquires its
significance for the construction and working of the organism.
With respect to the utilisation of the food, it is of no consequence
whence it comes, or by what means the organism obtains it.
Obvious as this consideration is, yet confusion between the elabora-
tion of food in structural and functional metabolism on the one

94 Prof. W. Pleffer. The Nature and

hand, and the operations adapted to the acquisition and absorption
of organic nutriment on the other, has led to a grave error, namely,
to the assumption that a difference in principle exists between the-
metabolism of plants and that of animals. The simple reflection
that an immense number of plants exist which are destitute of
chlorophyll, might at once have taught that the function of the chloro-
phyll apparatus — the production of food from carbonic acid and water
— only serves to provide nutriment for further elaboration, and to
introduce it in a peculiar and highly characteristic manner into the
organism. For the structural and functional metabolism of green
plants, however, the sugar prepared in the plant's own factory has
exactly the same significance as the sugar which a fungus obtains
from outside. In like manner it makes no difference to the utilisa-
tion and importance of sugar in the metabolism of man, whether a
sugar-baker obtains it from his own factory or another man has to
buy it at second or third hand.

Again, only those plants can dispense with a supply of albumin-
ous food substances which construct these bodies synthetically from
simpler compounds. In all plants, however, in close analogy with
the animal organism, albuminous substances not only serve as
permanent constituents of the body, but are in part again disinte-
grated in metabolism. Yet this process does not as a rule result in an
excretion of the nitrogenous products of decomposition, for the latter
are usually at once re-employed for the regeneration of albuminous
substances. This, however, cannot take place to a sufficient extent
in cases where a mould fungus is provided with protein substances
as its only food, so as to increase the transformation of albuminoids-
and at the same time to restrict their regeneration. Under these
circumstances a large amount of ammonium carbonate is actually
excreted, in oiher words, the same final product which also arises in the-
animal body, but which there at once undergoes condensation to form
urea. By this latter process the injurious effect which would result
from an accumulation of ammonium carbonate is avoided. In the case
of fungi such an injurious accumulation does not usually occur under
normal conditions of growth, while these plants also to some extent
possess the power of guarding against its deleterious influence by
neutralisation, owing to the fact that in the presence of alkaline
compounds oxalic acid is produced in increased quantity.

It constantly happens that all those processes which do not
form an essential part of the indispensable functional metabolism „
are regulated in such a manner as to be wholly or partly brought to-
a standstill without impairing other functions. Any excessive
accumulation of products always has this result, so that, for example,
the further formation of sugar or of protein bodies ceases, when
these substances have collected in the cell up to a certain limited

Significance of Functional Metabolism in the Plant. 95

amount. On the other hand, the inevitable final products of the
general functional metabolism must be continually formed, for it is
upon this chemical process that the maintenance of vital activity
depends, and these final products, in so far as they are not again
made use of, must also be constantly secreted and removed, for their
accumulation would render further activity impossible. In many
aerobic organisms, for reasons already indicated, only the excretion
of carbonic acid and water is in question. In the case of many fungi,
and some other plants, we find, however, in addition to these sab-
stances, organic acids, and other non- volatile final products, which are
secreted in great variety and amount, especially in the case of many
aerobic and anaerobic fermentations.

In order to avoid an accumulation in the cell, the final products
which are continually arising, as well as the food to be assimilated,
must necessarily be soluble and capable of diosmosis. Hence the
ejection of the undigested remains of food is usually impossible,
though, where it is possible, we find it in plants as well as in
animals, as, for example, in the Myxomycetes. Extracellular diges-
tion, which is employed on an extensive scale even in the vegetable
kingdom, is, broadly speaking, only a means by which substances
are rendered available for absorption and elaboration by the
living elements, but is no more an integral part of the actual func-
tional metabolism than is the digestion in the stomach of animals.
The same holds good with reference to respiratory movements, and to
all those operations and adaptations which provide for the access of
oxygen and the removal of carbonic acid. In plants, it is true, there
are no special active respiratory movements, but in all the larger plants
an extensive system of aeration serves to maintain, adequately,
the gaseous interchange of the internal cells. A loose combination
of oxygen, such as is found in the haemoglobin of the blood, is not
of general occurrence among plants, though present and efficient in
certain chromogenic bacteria.

If we leave out of consideration all subsidiary and preliminary
processes, there is no doubt that the true aerobic functional meta-
bolism is the same, in principle, in plants and in animals ; in fact
even from a formal point of view, no difference exists, if, as is fitting,
we select the lowest animal and vegetable beings for comparison.

In plants, which like animals perform a large amount of work,
vigorous respiration also takes place ; in specially active plants it
may even be actually greater than in warm-blooded animals. For
while in man, the carbonic acid produced in twenty-four hours amounts,
to about 1*2 per cent., in many mould-fungi it exceeds 6 per cent, of
the weight of the body ; in very active bacteria the consumption of
oxygen, referred to the same standard, may reach an amount 20(X
times as great as in man.

VOL. LXIII I

96 Prof. W. Pfeffer. The Nature and

Although such energetic physiological combustion involves a very
considerable production of heat, yet in consequence of the extensive
radiating surface, only a slight rise of temperature usually ensues.
The functional metabolism, in fact, as in poecilothermic organisms,
does not provide for the regulative maintenance of a definite body-
temperature. At the same time the plant is adapted to accom-
modate itself to temperatures, ranging for example, from 2° to
40° C., and to bear such oscillations of the body-temperature with-
out injury. Manifestly it is altogether expedient that, when the tem-
perature rises, tlie activity of growth and respiration should be simul-
taneously accelerated. On the other hand, the fact that when the
optimum temperature for growth has been exceeded, substances are
burnt up by respiration, in an ever increasing degree, while the pro-
cesses of growth, and movement are retarded or altogether stopped,
is a non-adaptive phenomenon, determined only by the absence of
any regulative check.

As long as the external conditions remain constant, however, respi-
ration is always regulated by the plant, and is in general increased,
as the activity of the whole organism automatically rises. This
happens, for example, when a plant begins to grow again, after com-
pleting the winter's rest, or when a traumatic reaction is called
forth in consequence of injury. Thus, if we cut a potato in pieces,
the production of carbonic acid gradually increases nine- or ten-fold,
in the course of twenty-four hours, owing to the respiratory process,
and then gradually diminishes again as the traumatic reaction passes
off. Here the plant falls as it were into a state of fever, for simul-
taneously with respiration, the production of heat is very considerably
augmented.

If we bear in mind that the essential office of functional metabo-
lism, consists in providing, by means of chemical transformations,
the necessary energy for vital action, we cannot be surprised that
this end is not always attained in the same way. Apart from the
fact that different carbon-compounds are consumed in respiration, and
that not only carbonic acid, but in certain plants oxalic acid, acetic
acid, citric acid, &c., arise as the final products of physiological
combustion, there exist even aerobic organisms in which kinetic
energy is no longer obtained by the oxidation of any carbon compounds
whatever. Among these are the nitrobacteria, some of which oxidise
ammonia to nitrous acid, while others oxidise nitrous to nitric acid ;
these remarkable organisms, with the help of the energy thus gained,
are at the same time capable of constructing their organic food
synthetically from carbonic acid. Again, in the respiratory process
of the sulphur-bacteria, the sulphuretted hydrogen undergoes com-
bustion, sulphur being first set free, and then oxidized to form sul-
phuric acid. Thus, in these organisms, sulphuric acid is secreted as

Significance of Functional Metabolism in the Plant. 97

the final product of physiological combustion, while in the nitro-
bacteria the same is the case with nitrous or with nitric acid. There
can be no question that as time goes on, yet other specific peculiarities
will be discovered. Thus it is conceivable that certain micro-
organisms may gain their chemical kinetic energy by the oxidation
of ferrous oxide, and others perhaps,* by the oxidation of hydrogen
or of the gaseous hydrocarbons.

Considered from the general point of view of energy, it is by no
means necessary that physiological combustion should proceed
along the same lines in all organisms. Indeed it was only in con-
sequence of an unjustifiable generalisation from observations on the
higher animal and vegetable organisms, that the belief arose that
organic life is impossible without the agency of free oxygen, i.e.,
without oxygen-respiration. Just, however, as man is able to
employ driving power, derived from such reactions as the explosion
of gunpowder or dynamite in a space free from oxygen, so must it
appear a priori possible, that organisms have been evolved on our
earth, in adaptation to special conditions and necessities of life, which
are able to live without making use of free oxygen.

As a matter of fact numerous anaerobic micro-organisms are now
known. Their existence, indeed, was established as long ago as
1861, by the investigations of Pasteur, and it was only the deeply
rooted belief in the absolute indispensability of oxygen-respiration
which caused the majority of the learned to remain sceptical, or to
endeavour to save the dogma of the necessity of oxygen by forced,
and often, frivolous interpretations.

Much, it is true, remains to be explained as to the details of meta-
bolism, both in aerobic and anaerobic organisms ; meanwhile this
at least is certain, that even in anaerobes, kinetic energy is gained
by means of a great variety of chemical transformations. This fact
is at once indicated by the various final products of functional meta-
bolism, in one organism consisting chiefly of alcohol and carbonic
acid, in another of butyric acid, lactic acid, or butyl-alcohol,
or of other very various volatile and non-volatile compounds,
which, however, often owe their origin in part to secondary pro-
cesses; considered from the standpoint of energy it is not neces-
sary that any gaseous products should arise, or even that oxygen
atoms should be transposed, or carbon compounds disintegrated.
It is true that the latter assumption holds good in all cases which
have as yet been minutely studied, but it is quite conceivable that
kinetic energy may be obtained by some other reaction (for example,
by the reaction between potassium nitrate and sulphur).

The anaerobia are, however, of great importance in the economy
of nature, for by their agency decomposition is carried on in the
interior of the cadaver, and generally in places where the conditions

i 2

98 Prof. W. Pfeffer. The Nature and

for oxygen-respiration are absent. Thus, in the case of facul-
tative anaerobes, in proportion as oxygen becomes deficient, aerobic
becomes replaced by anaerobic metabolism, while the obligatory
anaerobes now for the first time begin their growth and multiplica-
tion. This is correlated with the fact, that oxygen, even at low
tension, acts as a poison to them, and when air is so much com-
pressed that the oxygen is twenty or thirty times as dense as in
the atmosphere, all plants perish. All gradations of sensitiveness
towards oxygen occur, from the most resistant organisms down-
wards, and there are even obligatory aerobes, such as the sulphur-
bacteria, which can only exist when oxygen is of very low density.

Thus the different types are connected by intermediate links. For
any facultative anaerobe it is possible to prepare a nutritive sub-
stratum on which it can nourish only when able to respire free
oxygen. If, however, the oxygen be presented in sufficient dilution
it does not hinder the growth of the anaerobic organism, which,
under these circumstances, constantly draws the free oxygen into its
functional metabolism, and thus gradually consumes it in considerable
quantities. Further, a variable density of the free oxygen may be
endured by the same organism in accordance with the cultural condi-
tions under which it is placed. It has in fact been found possible, by
means of special nutrition, to cultivate the strictly anaerobic Bacillus
of symptomatic anthrax (B. carbonis) as an ae'robe. The habits of tho
nitrogen-assimilating Clostridium Pasteurianum are also evidently
modified by certain bacteria which usually live associated with it,
for in such svmbiosis Clostridium endures the free access of air,
while in the isolated condition it can only live anaerobically.

Even in the case of typical aerobes, however, the withdrawal of
oxygen does not bring the metabolic activity entirely to a standstill.
At first carbonic acid is still given off, being derived from the
intramolecular respiration, i.e., from chemico-physiological processes,
which in most plants further result in the formation of alcohol and
other products. This intramolecular respiration is thns a vital
action which is of importance for the maintenance of life even in
aerobes, but which in the latter does not suffice to maintain the whole
working of the organism after oxygen has been withdrawn. In the
anaerobes this capacity has been fully developed, but of course only
comes into play when suitable nutrition is provided. For, when differ-
ently fed, even the facultative anaerobe can only grow if fully supplied
with air, and behaves, when oxygen is withdrawn, just like a typi-
cally aerobic plant, for it then ceases to grow, and, sooner or later,
perishes altogether. By means of an appropriate food-mixture,
however, we can ensure that the facultative anaerobe continues its
growth and movements, but only for a certain time and to a certain
extent, thus appearing as a temporarily anaerobic organism. Such

Significance of Functional Metabolism in the Plant. 99

an organism, for example, is yeast (Saccharomyces cerevisice), which,
under the nutritive conditions hitherto tested, cannot live without an
occasional supply of oxygen, whereas certain bacteria are capable of
an unlimited anaerobic life.

It follows directly from what has been said, that among aerobes
life is maintained for a limited time by the action of intramole-
cular respiration. For it is only when intramolecular respiration
fails that the plant suffers in an atmosphere free from oxygen ;
the strictly aerobic mould-fungi keep alive much longer without
oxygen, when their aerobic respiratory activity is intensified by pro-
viding them with sugar. Thus there is every gradation and transi-
tion between those organisms which require free oxygen, and those
in which the anaerobic metabolic activity, which is exercised to a
certain degree in all organisms, is so far developed and utilised that
the functional metabolism suffices for a life without oxygen. Even
in aerobes a number of partial functions are carried on for a certain
time after the withdrawal of oxygen. Among these functions intra-
molecular respiration itself is included, as well as all the metabolic
changes with which it is linked. There are also certain processes of
growth and movement which are not at once brought to a standstill
when oxygen is withdrawn. Thus we know that nuclear division,
when it has once begun, still goes on in the absence of oxygen, and
under the same conditions the tentacles of the insectivorous Sundew
still carry out their movements when stimulated. The muscle of
animals can also be caused to contract when deprived of oxygen.

The relations of the organism to its conditions of life can be
demonstrated and understood, even though we do not possess any
deeper insight into the causes and the exact processes of functional
metabolism. We may also regard it as certain that functional
metabolism is indispensable to vital activity, on which in its turn it
depends and by which it is regulated, so that metabolism is afc once
extinguished when death ensues. Thus the realisation of functional
metabolism ensures the continuity of metabolism in general, just as
a blazing fire, by heating the wood, constantly creates and maintains
the conditions necessary for the continuance of combustion.

It is also certain that functional metabolism runs its course within
the living protoplasm, not merely on its surface or in particular portions
of it, but in and between all its constituent parts, as must necessarily
be the case in order that vital activity may be maintained. This can
be seen at once from the fact that those movements in the protoplasm,
or in any separate fragment of the protoplast, which are dependent
on aerobic respiration, come to an end on the withdrawal of oxygen,
even when the adjoining cells have access to oxygen and are in a
state of full activity.

From the dependence of functional metabolism on vital activity it

100 Prof. W. Pfeffer. The Nature and

directly follows that the consumption of the material to be elaborated,
as well as the absorption of free oxygen by the organism, is regu-
lated in accordance with its requirements. Consequently, when
these requirements are fully satisfied, an increased supply of food
material or of oxygen results in no essential acceleration of the func-
tional metabolism. For this reason plants do not breathe any more
vigorously in pure oxygen than in ordinary air, for even in the latter
much more oxygen penetrates into the cell than is consumed in
normal respiration.

If, however, the supply is not sufficient to fully satisfy the demand,
then the functional metabolism, and with it the whole activity of the
organism, is unavoidably reduced, just as a fire can no longer burn
properly when insufficiently supplied with fuel or with oxygen.
Most plants, however, can completely meet their demand for oxygen
in an atmosphere in which the proportion of oxygen (at ordinary
atmospheric pressure) is reduced to 5 — 8 per cent., so that on the
highest mountains vegetable organisms find a more than sufficient
density of oxygen. If its density be still further diminished, then,
after a transient disturbance, the respiration and the total activity of
the plant are depressed, so that in an atmosphere containing only 2 — 4
per cent, of oxygen the plant, though it survives, breathes and
works in a diminished degree.

Since functional metabolism depends on the vital activities, a satis-
factory causal explanation of the former will only be possible after
we have gained a sufficient insight into the latter. In general, how-
ever, we may say that the same processes which effect intramolecular
respiration also develop those affinities, by means of which free
oxygen, when supplied, is drawn into metabolism. For intra-
molecular respiration is at once stopped on access of oxygen, and
after the withdrawal of oxygen is immediately resumed. In much
the same way as the development of the spontaneously inflammable
phosphuretted hydrogen brings about the fixation of a certain
amount of oxygen, may physiological combustion be determined
and regulated through the continual formation of a single
autoxydable body. In respiration, however, we have evidently to do
with complicated reactions and reciprocal changes, which come into
play between the constituent parts of the protoplasmic body. And
further, the respiratory process must take a somewhat different form
when, instead of a carbon compound, ammonia or ammonium nitrite,
sulphuretted hydrogen or sulphur, forms the material for physiolo-
gical combustion.

We may be sure, however, that in the plant passive oxygen is
drawn into metabolism, and that oxygen is not brought into the
active state in order to accomplish physiological oxidation. For we
can prove with complete certainty that at no time does any such

Significance of Functional Metabolism in the Plant. 101

process of oxidation occur in the interior of vitally active protoplasm
(including the nucleus), as is brought about by even the feeblest
form of active oxygen (hydrogen peroxide). This still holds good
even if the reactions of active oxygen are obtained in the expressed
sap, i.e., after mixing bodies which in the plant are separate. If,
however, active oxygen ever plays any part at all, it is at most to be
regarded as one only of the means of which the organism avails
itself, and not as revealing the true and essential cause of functional
metabolism.

Side by side with the general process of functional metabolism,
many other chemical operations must necessarily come into play, in
order to provide the various compounds which are formed in the
organism, in order to build up its tissues, or otherwise. Although
these processes are not of necessity in continuous action, it is difficult
to separate them from the general functional metabolism. We are
placed with regard to the plant, somewhat in the position of a man
who, while he can control the raw material introduced into a factory
and the finished products turned out from it, is not permitted to
inspect the internal working. Unless the observer has a knowledge
of this from other sources, it is simply impossible for him to say
what is the nature of all the manifold operations carried on in a
chemical factory, whether simultaneously or successively, jointly or
separately. At the same time the observer may be quite aware that
all work in the factory is impossible if the fire be not burning under
the boiler, or if the driving power in general be not available, and he
may also know that the gaseous products of combustion, the ashes
and the slag, must be got rid of, simply in order to make room for
the work to go on. In the factory, however, just as in the plant, the
general driving power is not always utilised for the same purposes or
with equal efficiency. Indeed, when the steam-engine is at work but
the rest of the machinery is out of gear, the whole driving power is
wasted. No less is it true, in the case of the plant, that the relation
between the available kinetic energy and its utilisation for various
purposes, or in other words the economic coefficient, may vary
within very wide limits according to the stage of development and
the external conditions.

102 Dr. W. J. Russell. On the Action exerted by certain

BAKERIAN LECTURE.— « Further Experiments on the Action
exerted by certain Metals and other Bodies on a Photo-
graphic Plate." By W. J. RUSSELL, Ph.D., V.P.R.S. Re-
ceived February 10, — Read March 24, 1898.

In a paper read before this Society in June last* it was stated
that certain metals, alloys, and other substances such as picture
copal, printing ink, straw board, &c., were able to act even at a
distance on a sensitive photographic plate, producing effects similar
in appearance and developed in the same way as plates which had
been acted on by ordinary light. At that time sufficient 'experi-
mental evidence had not been obtained to determine the nature of
this action, or even to clearly indicate its general character, whether
in fact the action arose from vapour given off by the active body,
or whether phosphorescence was produced which acted on the plate.
That bodies so slightly volatile as zinc, aluminium, nickel, &c.,
should be able to give off at ordinary temperatures in a few days
sufficient vapour to act strongly on a photographic plate, and that
such vapour should be able to pass rapidly through media, such as
gelatin, celluloid, collodion, &c., seemed difficult to realise, although
many of the earlier experiments appeared to indicate that this was
the kind of action which took place. Later experiments confirm
the view that a vapour is given off, which is the cause of the action
on the plate.

Certain organic bodies, as well as metals, have been shown to act
on the photographic plate, and in endeavouring to ascertain the
nature of this action experiments with organic bodies were first
undertaken, as the results which they yield are more easily and
rapidly obtained than those with the metals, and if their mode of
action was determined it would probably throw light on the action
exerted by the metals. In the former communication it was stated
that printing ink and copal varnish are active substances, both when
in direct contact with a photographic plate and when at a distance
from it. Further it was found that the action which they exerted
was able to pass through different media. Although printing inks
and copal varnishes may vary considerably in composition, the
main constituents are constant, hence it was easy to determine that
boiled oil and turpentine were the bodies to which they owed their
activity, and that these bodies separately behaved in the same
way as did printing ink and copal varnish. Boiled oil — that is,
linseed oil which has been heated with oxide of lead — is an active
substance, and most of the following experiments have been made

* <Koy. Soc. Proc.,' vol. 61, p. 424.

Metals and other I todies on a Photographic Plate. 103

with the pale drying oil which is prepared by Messrs. Winsor
and Newton. Pure turpentine is also a very active substance, and,
owing to its volatility, in many experiments very useful. These
bodies can be used either as liquids in small dishes or by saturat-
ing Bristol board or other neutral and porous bodies, such as ignited
pumice stone, &c., with them. In the case of the drying oil it can
be painted on glass or cardboard and allowed to harden.

The experiments described in the former communication have been
repeated under the same and under slightly different conditions and
m another laboratory ; the results obtained with one exception con-
firm the previous statements. Glass, selenite, mica, even in very
thin layers, are absolutely opaque to the action, whereas gelatin,
celluloid, collodion, guttapercha tissue, tracing paper, parchment,
and paper are more or less transparent. Linseed oil and turpentine
may fairly be taken as typical examples of active organic bodies.
This property of acting on the photographic plate is far from
belonging to all volatile organic bodies ; for instance, although vege-
table oils have the power of acting, mineral oils, so far as they have
been tried, have not the power. Benzene, carbon disulphide, chloro-
form, &c., also are without this power of acting on the photographic
plate ; but the question of what substances are and what are not
active will be dealt with on another occasion ; at present it is simply
to consider the conditions under which linseed oil and turpentine act
on the photographic plate. The picture copal varnish which was
much used in the former experiments obviously owes its activity to
the turpentine and the oil it contains. Warm the varnish for some
length of time, these bodies are driven off and an inactive gum
remains. This experiment obviously suggests a vapour as the cause
of the action ; at the same time would such a vapour pass through
bodies such as gelatin, celluloid, &c. ? With regard, for instance, to
the thin-sheet gelatin, it appears to offer but very slight obstruction
to the action of these organic bodies; if the thickness of the gelatin
be increased still the action takes place, only the time of exposure
has to be considerably longer.* Another striking fact with regard
to this emanation from these active bodies is that it gives an accu-
rate picture of the surface from which it has come. A hard copal
surface on glass will give a picture showing every brush mark,
unevenness, and scratch on the surface, and if the action take place
through a thin sheet of gelatin, or even as many as six or more
sheets, still the picture of the scratches is distinct. The following
experiments are apparently strong evidence that the action on the
photographic plate is due to the vapour given oif from these organic
bodies.

A piece of Bristol board saturated with drying oil, or a piece of
* The thin gelatin is 0 02 mm. and the thick O'lfi mm. in thickness.

i 3

104 Dr. W. J. Russell. On the A ction exerted by cwtain

glass painted with it or with picture copal, is placed on the bottom
of an ordinary plate box and a photographic plate larger than the
active body is suspended above it with the film upwards ; light is
excluded from the box, and the arrangement is left for, say, a fort-
night, then the plate when developed will be found to have been
acted on irregularly round its edge, at some parts considerably more
than' at others, but everywhere shading off and evidently in the way
which would occur if a vapour had rolled round the edge. Another
experiment which showed this kind of action very satisfactorily was
carried out as follows: — A circular piece of the Bristol board was
saturated with drying oil, and at a little distance above it a smaller
circle of mica, which is perfectly opaque to the action, was placed,
and again above this was another piece of mica with a circular hole
smaller than the circular mica plate, and then the photographic
-plate was placed above. By this arrangement no direct action could
take place between the drying oil and the sensitive plate, but a
vapour could work its way between the mica plates and thus reach
the photographic plate; and this it did, for after an exposure of
three days, on developing the plate there was a dark ring formed
shading off towards the centre. Another and very simple experi-
ment illustrating this same point is to place a small circular glass
dish, with some drying oil in it, in the middle of a photographic plate,
and leave it there for a week. On developing the plate it will be
found that no action has taken place where the dish stood, but that
immediately beyond the outside of the dish much action has occurred,
and that the darkening gradually fades away. There is still another
way in which the action of these organic bodies has been tested, and
that is by transferring the active power of these bodies to a neutral
substance. If vapour be the immediate cause of the darkening of
the photographic plate, then it would be possible, if a piece of Bristol
board were suspended above drying oil, for instance, for the inactive
board to take up those vapours a,nd become photographically active.
This was found to take place. Bristol board of good quality is a
very useful substance in all these experiments, both as a screen and
as an absorbent. It is in itself an inactive body, and may be heated
in a water bath before using, to prevent the accidental presence of
any substance which might act on the plate. If a piece of the
Bristol board be suspended above drying oil, in the liquid or solid
state, or turpentine or picture copal for two or three days, or even
less, it becomes strongly active, and when placed in contact with a
photographic plate quickly darkens it. This action of the Bristol
board is well shown if a pattern be stamped upon it, which is easily
done by pressing against it a piece of white net (black net must not
be used as it is slightly active), then the charged Bristol board will
give an unmistakable picture. If turpentine be the active sub-

Metals and other Bodies on a Photographic Plate. • 105

stance used to charge the Bristol board the exposure need only be for
a few hours, but if after this charging it be exposed to the air for a
day or two, its activity will be found to have gone. There is
obviously no visible indication of this activity of the Bristol board,
and consequently if a device be cut out on a screen which is placed in
front of a sheet of cardboard, or any inactive paper, and it is exposed
to turpentine or to oil, or if the vapour of these bodies be in any
other way brought in contact with the paper, a dark picture of such
device, which is not visible, may be produced. Some unexpected and
curious cases of ghostly pictures thus formed have been met with, they
are, however, all produced in this way, and need not be described now.
The above experiments have been made at ordinary temperatures, but
if the temperature be increased the activity of these organic bodies is
also greatly increased. High temperatures cannot, of course, be used,
but a temperature of 55° C. does not appear to alter the photographic
plate. With drying oil — which is one of the most active substances
that has been used — it is easy to obtain a picture in thirty minutes at
the above temperature. The interesting pictures which in the former
communication it was shown could be produced simply by laying a
piece of dry wood or the section of the branch of a tree on a plate
are produced by the volatile matter contained in the wood. These
pictures appear at first sight very accurate and complete, but this is
not really BO, for some parts of the structure of the wood are not
shown and other parts are too strongly developed, depending on the
amount of volatile substance present in the different parts. It is,
however, very remarkable that so small a quantity of the volatile
body as exists in a piece of dry wood should be able to produce a
picture; the activity of the wood is increased by the pre2ence of
moisture. This property of acting on the photographic plate, pos-
sessed by the linseed oil, belongs apparently to the vapour and not to
the oil itself, for if a sheet of thin gelatin be placed on a photo-
graphic plate, and on it a thick glass ring nearly filled with oil, and
over the top of the ring another sheet of gelatin, not in contact with
the oil, and another sensitive plate, it will be found that after a
week's exposure no action has taken place below the oil, but that a
large amount has occurred above it where the vapour has penetrated
the upper sheet of gelatin. A similar result is also obtained by
simply floating a piece of the thin gelatin on a dish of oil and placing
a sensitive plate above. At the sides where the vapour can form and
get away there is action on the plate ; in the centre there is none.

In addition to glass, mica, and bodies of that kind, the action does
not take place through a layer, except it be very thin, of either gum
arabic or of paraffin. If a piece of Bristol board or a glass plate
has hardened drying oil on it, and be painted over with a strong
solution of gum arabic which is allowed to dry, then the delicate

100 Dr. W. J. Russell. On the Action exerted by certain

cracking which occurs can be very well shown on a photographic
plate.

Pure water does not act on the plate, neither does pure alcohol or
pure ether, but the ordinary commercial specimens of the last two
bodies do, and often to a considerable extent. Alcohol which, pro-
duces a dark picture will, after digestion with, lime and careful dis-
tillation, be entirely inactive, and ether after careful purification also
becomes inactive. Moisture, if present, does not affect this result ;
thus the presence of certain impurities, and they appear to be some
of the most common ones, can be readily photographed, and approxi-
mately their amount determined by the darkness of the picture formed,
so that by this means can be determined whether, for instance, a
purification process is working well and whether it has completely
done its work. The pictures are easily obtained by placing some of
the liquid to be tested in a small glass dish, and a sensitive plate
above it. Obviously it is only certain impurities which will be indi-
cated in this way, but the reaction is otherwise of considerable
importance, for it gives a simple method of determining what bodies
soluble in these liquids, are capable of acting on a sensitive plate.
This matter will be treated of in a separate communication.

That the vapour given off by these organic bodies is the imme-
diate cause of the action on the sensitive plate the above experiments
seem to show. At the same time it is remarkable that such a vapour
should readily pass through media such as gelatin, celluloid, &c., and
not by mere absorption, but in such a way as to produce a picture of
the surface from which it emanated.

Passing on to the action which certain metals exert on a photo-
graphic plate, results have been obtained which are strikingly similar
to those just described. Substitute a piece of polished zinc for a piece
of Bristol board saturated with linseed oil, and similar effects are
produced on a photographic plate ; the time of exposure must, how-
ever, be longer. Although both magnesium and cadmium are
slightly more active than zinc, this last metal is the most convenient
one to experiment with, and has been used in most of the following
experiments. In addition to the above three metals, nickel, alumi-
nium, lead, and bismuth have the same property, but not so strongly
developed, of acting, both when in contact and when at a distance, on
a photographic plate. Cobalt, tin, and antimony can also act in the
same way, but their action is considerably feebler, and undoubtedly
other metals can act in the same way, but require much longer
exposure. Mercury, which in the former paper was stated to be the
most active of all the metals which had been tried, is now found to be
quite inactive; the metal used in the former experiments was impure.
This matter will be explained further on.

As so strong a similarity exists between the effects produced by

Metals and other Bodies on a Photographic Plate. 107

the above-mentioned organic bodies and the metals, the question
which naturally presents itself is, do they also give off a vapour
which directly or indirectly acts on the photographic plate ? The
following experiments show that such an action does probably occur.
Zinc which has been long exposed to the air is inactive. An expo-
sure out of doors for only three or four days diminishes very con-
siderably its activity, but covered up in doors after three weeks it
will still give a tolerably dark picture. If it has a bright but per-
fectly smooth surface it is active, but not strongly so ; rub the zinc
with coarse sand or emery paper, and it is then obtained in its state
of greatest activity ; the same applies to all the metals. If, when in
this condition, any of the active metals be placed in contact with a
photographic plate, a beautifully sharp picture of the scratched sur-
face is obtained. The great increase of the fresh metallic surface
produced by the rubbing may account for the increase of activity
which the scratching produces. If the zinc plate be raised only
slightly above the photographic plate, a sharp picture of the scratches
is still obtained, and of course as the distance is increased, so is the
indistinctness of the picture increased, and at last it fades into a
general cloudiness, and in this form the zinc plate can easily be made
to act through the distance of an inch or more.

This action of the metals passes through the same media as do the
vapours from the organic bodies, and clear pictures can be obtained
through sheets of thin gelatin, &c. ; in fact what has already been
said with regard to the transmission of the activity of the organic
bodies applies to the metals ; gelatin, both thin and thick, allows the
action of the metal to pass through it ; celluloid and collodion do the
same, and so does gold-beaters skin and tracing paper. Reasoning,
then, from this strong analogy between the action of the organic
and the metallic bodies, it must be assumed that the above-mentioned
metals from a clean surface and at ordinary temperatures give off
vapour, and this vapour apparently acts when under the same circum-
stances in a like manner to the vapour given off by the drying oil. It
gives a clear picture of the metal surface from which it arose, and it
can permeate the same media as the organic vapours. The remark-
ably clear pictures of, for instance, a zinc surface, which can be
produced through a sheet, or even several sheets, of the thin gelatin
proves that the action is not one of mere absorption.

To gain further knowledge on this point and test the porosity of
these different media, the power of hydrogen to diffuse through them
was tried by cementing specimens of the different substances on
glass tubes, which were filled with hydrogen and placed over water.
The action is somewhat remarkable, but requires further confirma-
tion. With the thin gelatin ordinary diffusion does not occur,
and a hardly, if any, perceptible rise of the water in the tube

108 Dr. W. J. Russell. On the Action exerted by certain

occurs on starting the experiment ; but on standing for some length
of time, two or three days, the water begins to rise, and after
a week or more it will stand at a height of four or more inches
above the level in tho vessel, and there it remains at least for a
month or more. With the thick gelatin there is no evidence of any
diffusion occurring. Celluloid acts much in the same way as the
thin gelatin, a column of water gradually rises and remains there.
The action of the guttapercha tissue is to absorb the hydrogen ; the
diffusion tube completely fills up with water and remains full without
showing any tendency to fall for a couple of months, and then the
experiment was stopped. With tracing paper diffusion occurs in
the ordinary manner, and the same happened in the single experi-
ment tried with gold-beater's skin. That the rise of the water
in the diffusion tubes is not owing to a mere absorption of the
hydrogen by the gelatin or guttapercha has been proved by placing
a considerable quantity of these bodies in a tube sealed up at one
end, filled with hydrogen and inverted over water ; after several
weeks no rise of the water in the tube occurred. The above experi-
ments have been repeated with the same results, but further trials
are being made. Possibly the metallic vapour is in a still finer
molecular state than ordinary hydrogen, and thus is able easily to
permeate a medium which hydrogen can only slowly get through,
and air cannot get through. At all events, this may be looked upon
for the moment as a working hypothesis.

That the action of the metals like that of the organic bodies is
due to a vapour can be demonstrated by experiments exactly similar
to those already described. For instance, it' the thin mica plates be
arranged above a zinc plate, in the way already mentioned, so as to
cut off all direct action between the zinc and sensitive plate, a ring
of action is produced which can only be accounted for by supposing
a vapour present, which has worked its way between the sheets of
mica and thus gained access to the photographic plate. Again, a
piece of Bristol board can be made active by contact with, or mere
proximity to, a piece of polished zinc. A striking instance of this
arose in the following way : a piece of perforated zinc had lain
on the bottom of an ordinary plate box for a considerable length of
time, probably about two months ; the zinc was then taken away,
and a sensitive plate dropped into its place. On developing this
plate, a picture of the perforated zinc was obtained. Other experi-
ments of a similar kind have been made. If the Bristol board be
not in direct contact with the zinc ; if a screen, with holes cut out in
it, be interposed, it will be found that the Bristol board where
exposed to the direct action of the zinc will become active, and will
give an exact picture of the holes or whatever design it may be
which has been cut out on the screen. To produce this effect the

Metals and other Bodies on a Photographic Plate. 109

cardboard has to be exposed to the zinc for fully six weeks. This
changing of the Bristol board does not take place satisfactorily
above ordinary temperatures. With other metals than zinc, these
changing effects have not as yet been obtained.

Another experiment, which illustrates the way in which the
metals can act, is to take a piece of ordinary perforated zinc, polish
one side, and lay this polished side against a plate of plain glass in
a printing frame, then place the photographic plate against the dull
side of the perforated zinc, and leave it in the dark for three or four
days ; then, on developing the plate, a reversed picture is obtained,
that is, the holes in the zinc will be represented by dark spaces, and
the zinc itself by light ones. If the holes in the perforated zinc are
large, they are represented by shaded circles, so that these pictures
are produced by the vapour emitted by the polished zinc which has
crept into the open spaces and thus gained access to the photo-
graphic plate. It has already been shown that the action exerted
by zinc passes more readily down a glass than down a paper tube of
the same size ; this has been strikingly confirmed by taking two
pieces of glass tubing 1 inch long f inch in diameter ; inside one
a single coil of inactive paper was placed, and both tubes stood on
a sheet of polished zinc, and a photographic plate rested on the
top of them. They were then left for a week, and on developing the
plate, a black patch appeared above the tube without the paper,
and no action was visible above the one with the paper. Without
removing the paper, it was painted over with melted paraffin, and
again a photographic plate put on the top of the two tubes ; now
two circular dark patches were produced of equal intensity.

If the activity of the zinc depends on a vapour which it emits, it
seemed possible that it could be carried along by a stream of air.
In order to^try whether this was the case, a tube a foot long was
packed with zinc turnings which had been amalgamated, and a
stream of pure air Fent through it. The end of the tube was fixed
into the side of a dark box and a sensitive plate with a screen upon
it suspended above it, thus no direct action could be exerted by the
amalgamated zinc on the plate. The experiment was continued for
four days, then, on developing the plate, a picture of the screen
above where the tube entered the box was obtained, but at the other
end of the plate there was no action.

The presence of mercury in this experiment was unsatisfactory,
and might account for the result obtained, therefore an exactly
similar experiment was made, and zinc turnings alone were used and
a plate without a screen. The experiment was carried on for a week,
and it was then found that a black patch had been produced imme-
diately above the end of the tube. To be sure that this darkening
did not arise from the action of the air, the whole of the zinc was

110 Dr. W. J. Kussell. On the Action exerted ly certain

removed from the tube and again the air sent through it for a
week, the sensitive plate showed no signs of any action having taken
place.

To try whether any accumulation of the vapour, and hence an
increase of action could be brought about by an increase of zinc
surface, two small circular glass dishes were taken, about 1^ inches
in diameter and f inch in depth ; into one a single disc of bright
zinc foil was placed, and in the other twenty similar discs, then on
the top of both vessels a photographic plate was placed. The single
disc was raised on a piece of glass, so both end discs were at the same
distance from the plate. The discs were a little smaller than the
glass vessels, and, owing to their not being quite flat, there was a
space between each one. In two experiments there was no marked
difference between the density of the pictures produced, the single
disc produced as much effect as the twenty. A more direct way for
the passing off of the vapour was then made by catting a circular hole
f inch in diameter through the centre of all the zinc discs, and now
a very black central spot was formed by the twenty zincs, and of
course there was a white spot with the single disc, so that the
vapour accumulated to a considerable extent in this central space.

It has already been mentioned that the statement in the former
paper that mercury was the most active of the metals is incorrect.
The error arose from not suspecting that a trace of any impurity
would affect the activity of the mercury, and, consequently, not
taking special precautions to insure its perfect purity. On repeat-
ing the former experiments with another sample of mercury it was
found that no action occurred, which seemed very remarkable ;
moisture was added, the temperature was increased, but still no
action took place ; the addition of a little zinc to the mercury was
then tried, and it was found that this made the mercury excessively
active. The presence of a very small quantity of zinc is able to
effect this change, certainly less than 1 /300th per cent. It is
very remarkable that so small an amount of the metal can cause so
strong an action on the photographic plate, for the exposure to the
vapour given off by such an amalgam need not, even at ordinary
temperature, be longer than two to three days. If other active
metals are dissolved in pure mercury they act in the same way, at
all events, this applies to magnesium and to lead. If silver, on the
contrary, be added it does not render mercury active, nor does
sodium. This action of mercury, which contains zinc or lead, the
most common impurities, is so readily recognised that it becomes a
valuable test for its purity, and a very interesting means of follow-
ing the effect produced by any purifying process. A specimen of
mercury containing not more than l/300th per cent, of zinc gave a
very dark picture ; this mercury was then treated first with sulph-

Metals and other Bodies on a Photographic Plate. Ill

uric acid and afterwards, for three days, with, nilric acid, and the
picture it then gave was very faint, and on repeating this purifying
process no picture at all was produced. Again, a sample of mercury
containing zinc was carefully distilled. The distillate gave a very
faint but very distinct picture. Another sample of distilled mercury
also gave a faint picture.

Temperature, as might be expected, affects greatly this activity
of the metals ; at 4° or 5° C. zinc has but little action on a photo-
graphic plate. Most of the foregoing experiments have been made
at about 17° or 18° C., and some, as specially noted, at 55° C. The
Ilford special rapid plates have been used.

It appears, then, from the above experiments that certain metals
have the property of giving off, even at ordinary temperatures,
vapour which affects a sensitive photographic plate, that this vapour
can be carried along by a current of air, and that it has the power of
passing through thin sheets of such bodies as gelatin, celluloid,
collodion, &c., in fact, so transparent are these bodies to the vapour
that, even after it has passed through them, it is able to produce clear
pictures of the surface of the metal from which it came. That much
remains to discover with regard to this action of the metals is
obvious, the most active metals are not the most volatile. Nickel is
very active, cobalt only very slightly so, copper and iron are practically
inactive. I hope before long to be able to bring before the Society
further developments of these curious actions, both of metals and
organic bodies.

The foregoing experiments have been made in the Davy-Faraday
laboratory, and I beg to thank the managers of the Royal Institu-
tion for having allowed me to work in their laboratory. My thanks
are also due to my assistant, Mr. Block, for the very careful and
intelligent way in which he has aided me with the experiments.

March 24, 1898. — Additional experiments have been made with
active organic substances, in order to determine to what class of
bodies they belong. As already stated, linseed oil and turpen-
tine were the two substances first found to be very active organic
bodies, and following out these results it has been proved that
vegetable oils in general have more or less this property of acting on
a photographic plate. Linseed oil, for instance, is very active, olive
oil only very slightly so. Even samples of " pure " linseed oil ob-
tained from the different artists' colourmen vary considerably in the
amount of action which they exert. The boiled, or drying linseed oil,
has, at ordinary temperatures, the same activity as the ordinary
oil, but under other conditions it appears there is some difference in
their action. Another class of bodies, also called oils, namely the
essential oils, have been found to be very active substances.

112 Action of certain Metals, $-c., on a Photographic Plate.

Samples of commercial specimens of the following essential oils
have been tried : — Peppermint, lemons, pine, juniper, bergamot,
winter green, lavender, cloves, eucalyptus, cajeput, and cedrat,
and were all found to be active, and not only when used by
themselves, but also when dissolved in a large amount of pure
alcohol. It is well known that the active substances in the essential
oils are bodies known as terpenes, and I have to thank Dr. Tilden for
supplying me with pure specimens of these bodies ; they are all of
them remarkably active. Paraldehyde and benzaldehyde are also
very active bodies. Ordinary aldehyde and formaldehyde, as they
have been at present applied, are only slightly active. Guaiacum,
both when in powder and in alcoholic solution, is active, and so are
powdered cinnamon, sweet spirits of nitre, and eau de cologne.
Brandy is slightly so. Now the important property belonging to all
th,ese bodies is their reducing or oxygen-absorbing power, hence the
conclusion that it is this property which enables them to act on the
photographic plate. The mineral oils, purified petroleum spirit,
aloohol, ether, the esters, such as ethyl acetate, benzene, nitrobenzene,
are all, when pure, unable to produce any effect on a sensitive plate,
and even oxidised bodies nearly related to the terpenes, such as ter-
pinol and camphor, are not active, neither is thymol. Terebene is
an exceedingly active body. The difference of activity of the ordi-
nary oils seems to follow their oxygen-absorbing power, at all events it
is so with regard to linseed and olive oils, for the former is the most
active of the oils, and 1 gram of it is said to be capable of absorbing
186 c.c. of oxygen, while the same weight of olive oil can absorb
only 8*2 c.c. It is also interesting to note that, at least with some of
these active bodies, results can be obtained which correspond to
what photographers term solarisation or reversal, the action, when
modified, giving a black picture, when carried to its full extent a
white one.

It has already been stated that a mere trace of zinc makes mer-
cury active, but it is certainly equally curious and unexpected that
a trace of zinc should make alcohol active. It is only necessary to take
pure alcohol and place in it some strips of bright zinc foil, leaving
the metal in for three or four days. It will then be found that the
alcohol can act strongly on a photographic plate. The same happens
with ether and with ethylacetate, but not with benzene. In addition
to zinc, cadmium, magnesium, aluminium, and fusible metal can act
in the same way, whereas lead, nickel, tin, silver, sodium, and, as far
as experiments have gone, all the inactive metals, have no such
power. This reaction is still being investigated, but certain it is
that careful filtration does not remove this activity from alcohol, nor
does distillation entirely destroy it.

On Contact Electricity of Metals. 113

" On Contact Electricity of Metals." By J. ERSKiNE-MtJRRAY,
D.Sc., F.R.S.E., Heriot-Watt College. Communicated by
Lord Kelvin, G.C.V.O., F.R.S. Received August 4, 1897,
—Read November 18, 1898.

I. Introductory.
II. Method of Experiment.

III. Effects of Different Methods of Cleansing the Metallic Surfaces.
IT. Thin Solid Films of Oxides, Iodides, &c.
V. Atmospheric or Time Effects.
VI. Very Thin Liquid Surface Films on Metals.
VII. Thick Liquid Films on Metals.
VIII. Films formed from Gases.
IX. Temperature Variations.

X. Elimination of Metal- Air Potentials by Solid Non-conducting Films on the
Metallic Surfaces.

I. Introductory.

§ 1. The experimental investigation described in this communica-
tion had as its primary object the elucidation and measurement of
the variations of Volta contact electricity of a pair of conductors, due
to changes in ihe state of that portion of the surface of each
conductor which was separated from the other conductor by an insulating
medium.

§ 2. The discovery of contact electricity of dry metals in air by
Yolta at the beginning of the present century, extended a quarter of
a century later by Pfaff to dry varnished metals in other gases, has
been confirmed by many subsequent experimenters. The reality of
the electrostatic force in air near an interface between copper and
zinc, inferred as an obvious consequence from it by Lord Kelvin, was
experimentally demonstrated by him in 1861*. In the next twenty
years many investigations were made, the more important being
those of Hankel, Gerland, Clifton, Ayrton and Perry, and von Zahn.
In 1881 a paper of great importance was published by M. Pellat,f
and as the present communication is, in some respects, only an
amplification and extension of his work, it may be of advantage to
give a short resume of it before going further.

M. Pellat's most important results appear to be (1) his demonstra-
tion of the influence of the physical condition of the metallic surfaces
on their Yolta-potential ; thus he found that a sharply scratched
plate is positive to a more smoothly polished one of the same metal,
the metals being washed with alcohol after polishing in both cases
and allowed to dry before the measurement of their potential ; (2)

* ' Electrostatics and Magnetism,' § 400 ef seq.
f ' Ann. Chim. Phys.,' 1881.
VOL. LXIII. K

114 Dr. J. Erskine-Murray.

his measurements of the temporary variations of potential due to
change of temperature of a copper, iron, or zinc plate ; and (3) his
experiments which prove the smallness of the changes produced in
the potential-difference of copper and zinc by varying either the
pressure or the nature of the gas surrounding them.

§ 2a. I shall now give a short summary of the results detailed in
the present paper : —

(a) Metals covered with non-conducting solid films of wax or
glass, except at their point of contact, give nearly the same potential
as the bare metals in air. The substitution of wax for air next the
metal only causes a small change which may be in the same direction
and of approximately equal amounts for metals whose potentials in air
are very different ; e.gr., the Yolta-potential-difference between zinc and
copper when both are coated with solid paraffin wax is very nearly
the same as that between bare zinc and copper. In this connection
I may mention that I have measured the potential of sodium coated
with wax and glass, and find it to be about 3*56 volts positive to a
standard gold plate.

(6) A metal cleaned by careful polishing and scratching with
emery-paper or glass is less positive when its surface is in a sharply
scratched condition than when smoothed or burnished, the difference
frequently amounting to 0'2 or 0-3 of a volt.

This result is not in opposition to that of M. Pellat mentioned
above (§ 2 (1)), for the conditions were different, as his plates were
washed with alcohol after polishing, while mine were not (see
Chap. Ill, and also §§ 39 et seq.).

(c) The temperature variations, between 15° C. and 60° C., of the
Volta-potential of many metals have been determined, both for clean
dry metals in air and for metals coated with liquid or non-conducting
solid films ; and it has been found that they are of considerable
magnitude in both cases. The curves representing the variation of
potential with temperature appear as if they should meet at a point
below— 200° C., at a potential about 0'4 volt positive to a standard
gold plate at 16° C. ; this suggests that Volta-potential- differences
may possibly vanish at a very low temperature (see Chap. IX).

(d) A liquid film, even if of extreme thinness, may cause a consider-
able change in the potential of a dry polished plate, which continues
permanent for many hours and even days after the disappearance of
the film.

Two films of the same liquid opposed to one another on the surfaces
of two plates of different metals do not usually give zero potential-
difference, as solid conducting films of one material would do, but
give nearly the same potential-difference as the dry metals on which
they lie (see Chaps. VI and VII).

(e) A very thin film of oxide on a metal produces only a very

On Contact Electricity of Metals. 115

small change in the potential, and every increase in thickness of the
film is attended by a further change in potential until a limiting
value is reached, which is that of a mass of the oxide (see
Chap. IV).

(/) Exposure to the atmosphere at ordinary temperatures does
not, as a rule, produce any rapid change in Volta-potential, especially
if the air be comparatively dry and free from dust. The
ultimate change is usually in the negative direction (see Chap. V),

(0) I have extended Lord Kelvin's experiments on the effect of
temporary immersion of a metal in a gas to the cases of copper, zinc,
tin, and silver in oxygen, and find that copper, zinc, and silver
become temporarily positive, while tin becomes negative in consequence
of this treatment (see Chap. VIII).

The research, suggested by Lord Kelvin, was carried out in the
Natural Philosophy Laboratory of Glasgow University during the
Sessions 1893-94-95, and during 1895-96 in the Cavendish Laboratory
of Cambridge University. My thanks are due to Lord Kelvin for
many suggestions and much valuable advice, both in regard to
experiments and to the discussion of results, and to Professor
J. J. Thomson for similar kindnesses during my work in the
Cavendish Laboratory. A small portion of this investigation, on the
effect of Rontgen aj-rays on the contact electricity of metals, was
published in the ' Proceedings of the Royal Society ' for March, 1896.

I have also to thank Professor James Holm, M.A.* and Mr.
George E. Allan, B.Sc., for the part they took in the earlier portion
of the work.

II. Method of Experiment.

§ 3. The measurement of the natural potential-difference between
any pair of conductors was usually made, in air, by the null method
described very briefly by Lord Kelvin in the Report of the British
Association for 1880, p. 494. To make clear the exact circumstances
in which the potentials were measured it will be advantageous to
describe the apparatus and general method of experiment in detail.

§ 4. A circular disc of one of the metals, usually about 9 cm.
in diameter and O2 cm. thickness, is insulated and in permanent
connection with the insulated pair of quadrants of an electrometer.
A similar plate of the other metal placed parallel to the first, at a
distance of a few millimetres from it, is uninsulated and in connection
with the uninsulated pair of quadrants. While in this position they
are temporarily connected with one another through a simple form
of potential-divider in which a slope of potential is maintained by a

* When this was written last August, my friend and former fellow- worker was
Professor of Applied Mathematics in the South African College, Cape Town. He
died in October.

K 2

116 Dr. J. Erskine-Murray.

Darnell cell in the direction opposite to that given by the experi-
mental plates. The temporary connection is now broken and the
plates are separated. In doing so the capacity of the condenser is
reduced, hence if there be any electric charge on them it will be
indicated by a further deflection of the electrometer. This operation
is repeated with different values of the counterpotential until separa-
tion of the plates produces no change in the deflection of the
electrometer. Since it has annulled the charge, the counter-
potential must now be equal and opposite to the natural potential-
difference.

§ 5. During most of the experiments a piece of apparatus made
by Lord Kelvin in or about 1861 was used. In it the plates were
surrounded by a cylindrical zinc case. This was made in two parts
for convenience in manipulation, the lower fixed to a heavy cast-iron
base plate, while the upper stood upon small brackets attached to
the top edge of the lower part, its position being regulated by a
hole-slot-and-plane arrangement. Openings in the sides of the
upper part facilitated the adjustment of the experimental plates, but
these were closed by a sliding cover during a measurement of
potential.

The lower plate was supported by an insulating glass stem which
was kept dry by means of pumice and sulphuric acid. On the top of
this stem was a brass cap screwed to fit the sockets which were
soldered to the backs of the plates, and from the brass cap a stiff
wire passed out through a hole in the case and formed the connection
between fche insulated plate and the electrometer.

A piece of platinum foil was soldered round a part of this wire to
give a clean contact for the temporary connection between the plates
through the potential-divider, and the wire from the divider had
likewise a platinum end piece.

The upper plate hung, by a ring at the centre of its back, on a
hook at the lower end of a vertical metal rod, which could be drawn
up so as to increase the distance between the plates. A small disc
fixed on the rod at right angles to it just above the hook had three
screws passed through it and pressed against the plate, holding it
firmly in the hook ; by this means the upper plate can be set parallel
to the lower one in a very short time. This apparatus, which is the
same as that used by Lord Kelvin in his experiments many years
ago, was found to be very convenient, the arrangements enabling us
to take out and replace a plate very rapidly, a matter of great
importance when observing temporary variations, while at the same
time both plates were firmly attached to their supports when in
position.

§ 6. The divider, whose total resistance was about 2400 ohms,
was made to divide the potential-difference between its outer

On Contact Electricity of Metals. 117

terminals into 100 equal parts. The potential applied was
usually that given by a Daniell cell of Lord Kelvin's gravity type,
and was tested frequently by comparison with a standard Clark cell,
or by means of a standard resistance and a current balance.

§ 7. The permanent connections were as follows : — (1) The lower
plate to the insulated pair of quadrants of the electrometer; (2)
the terminals of the Daniell cell to the ends of the divider (there
was a reversing plug in this circuit) ; (3) one end of the divider to
the upper plate and uninsulated quadrants of the electrometer.

The temporary connection (§ 5) was from the sliding contact piece
of the divider to the lower plate.

§ 8. Each experiment was as a rule begun by polishing a metal
plate on clean glass-paper or emery cloth. Its contact potential
with a standard plate, generally of electrolytically deposited gold
washed some hours previously with alcohol, as used by M. Pellat,
was then measured. The plate was next subjected to some particular
treatment ; for instance it was filed, or burnished, or polished on
leather or paper, or washed with water, alcohol, or turpentine, or
heated in air and oxidized, or not oxidized, or exposed to steam, or
oxygen, or fumes of iodine or hydrogen sulphide, or simply left to
alter under the influences of the atmosphere and its own molecular
forces. Its potential with the same standard plate was again
measured, and the change due to the treatment its surface had
undergone noted.

§ 9. The metal which requires to be joined to the zinc end of the
battery, in order to effect a balance, will be called positive. Thus
aluminium is positive to zinc and zinc positive to copper. Also,
when a plate becomes more positive its potential will be said to rise ;
when more negative, to fall. When the " potential " of a plate is
mentioned, without other qualification, its contact potential- difference
with a standard plate (§ 8) is meant.

§ 10. The results given are not in the order in which they were
obtained, but are classified in such a way as to show more clearly
their true import, and those of many experiments, which are not
mentioned in the text, will be found in the tables.

III. Effects of different Methods of Cleansing the Metallic Surfaces.

§ 11. It seems probable that the very conflicting results obtained
by different experimenters for the potential-difference of any given
pair of metals, in air, must be due, to a large extent, to differences
in the methods by which the surfaces have been prepared. In order
to obtain a metallic surface as free as possible from all contamination
it is clear that a hard polishing agent, such as a clean steel file, or
emery-cloth, or glass-paper, must be used, as a softer material leaves

118 Dr. J. Erskine-Murray.

more of itself on the plate. A liquid is quite unsuitable, since every
particle of the metal probably retains particles of the liquid adhering
to it. Thus the smell of a liquid remains long after the plate appears
to be quite dry ; and it has been found that such a film as must exist
to cause the odour is quite sufficient to alter the potential very
considerably.

§ 12. In order to obtain uniformity of action the clean glass-paper
or emery-cloth used to polish a plate was fixed on a wooden roller
made to revolve with circumferential velocity of about 100 cm.
per second. Care was taken to hold the plate so that the scratches,
caused by the polisher, should all be parallel. Thus little or no grit
could lodge in the surface, which would have occurred had the
scratches crossed one another. A record was kept of the nature of
the polishing agent in every case. A piece of glass-paper, or other
polisher, was seldom used more than once or twice, and was never
used for any different metal.

§ 13. M. Pellat found that every change in the smoothness of a
surface is accompanied by a change in its contact potential ; but as
his experiments were limited to metals washed with alcohol, it was
of interest to extend them to more general cases. Thus a plate of
zinc which had been polished on clean glass-paper, and had therefore
a surface sharply scratched in parallel lines, was found to be

0'70 volt

positive to the standard gold plate. It was next burnished with a
tool of hardened steel, and with the same standard plate it now gave

0-94 volt,
Two hours later the same plate gave

0-92 volt,

showing that the effect is nearly permanent. By burnishing the
plate again a finer polish was obtained. With the same standard the
potential is now

1-00 volt,

still further burnishing giving

1-02 volt.

If the zinc be now polished on glass-paper it returns to its original
potential. Now steel, of which the burnisher was made, is negative
to zinc ; hence this rise cannot have been due to particles of steel on
the zinc, but must have been caused by some change involved in the
smoothing process to which the zinc had been subjected, possibly by
a hardening of the surface layer.

On Contact Electricity of Metals.

§ 14. Intermediate states of polish give intermediate j values of
potential. For instance, if a zinc plate be filed it will bot be so
sharply scratched as it would be by glass-paper, and of course not so
smooth as if burnished. Its potential is also found to be between
those of scratched and burnished zinc. Each polishing, with any
material, was usually sufficiently thorough to efface the effects of all
previous polishings : the potential observed thus depended only ou
the state of surface produced by the polisher used just before the
observation. The results of experiments show that the smoother
the surface the more positive it becomes.

§ 15. The generalization given in § 14 is supported by the results
of over 100 similar experiments, with a number of metals.
The actual results are given in Table I ; it will be well, however,
to discuss some of these in greater detail than is possible in tabular
form.

§ 16. In order to eliminate the use of different polishing agents,
I tried the effect of producing different states of surface by rubbing
the plate against another of the same metal. Two. copper plates
which had been polished on glass-paper gave

(a) +0-01 volt,

(6) +0-04 „

with the standard plate. They were next gently rubbed together
until parts of each were shiny and now gave, with the same
standard,

(a) +0-07 volt,

(&) +0-07 „

In another experiment two coppers which had been polished on
medium emery-cloth (Davies's No. !•£) gave, with the standard
plate,

(a) -O'll volt.
(6) -0-06 „

When slightly burnished by rubbing them together, they gave

(a) —0-02 volt.
(6) -0-02 „

Thus, smoothing by mutual friction made both more positive. The
amount of the change is not great, either in potential or in smooth-
ness, as it is very difficult to polish copper on copper, but the direction
of change is the same as previously found, namely, a smooth surface
is more positive than a sharply scratched one.

§ 17. On account of the difficulty of obtaining a burnished surface
by simply rubbing two pieces of the same metal together, I tried
another form of experiment in which the possible effect of the

120

Dr. J. Erskine-Murray.

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material of the polishing agent is eliminated by using the same tool
to produce different states of surface. Thus a copper plate was
scratched very roughly with a steel tool, and gave

-0-07 volt

with the standard plate, then burnished slightly with the same tool
it gave

-0-02 volt.

It had thus risen O05 volt on account of the alteration produced
in smoothing its surface. Thus these results also confirm the con-
clusion given in § 14

§ 18. It should be noticed that although individual results
occasionally appear to conflict, the average value of the potential of
any given metal when polished with a certain agent is almost always
in proportion to the smoothness of the surface produced. However
much one may try, it is impossible to get exactly the same state of
surface over again, but by taking the average of a considerable
number of experiments with one polishing agent, a general value is
got which represents the potential given by the plate in a certain
state of polish. It is so arranged that the sharply scratched surfaces
come at the head of the table, and each succeeding polishing agent
in the list produces a smoother surface.

§ 19. It should be observed that with soft metals such as tin,
different polishers produce but little change in the contact potential.
This, though at first sight apparently contrary to the results for
harder metals, is really in accordance with them, for different
polishers do not produce appreciably different states of polish on a
soft metal. This remark applies equally to the fact that a smaller
variation was observed with " high conductivity " copper than with
the old copper plate, as the old plate was found to be considerably
harder than the purer "high conductivity " copper.

§ 20. It is probable that the variation described in this chapter
is not directly due to roughness or smoothness, but rather to altera-
tion, either by change in the outer layer of the metal, or in the film
of condensed air which no doubt exists on it, of the interface between
metal and air.

IV. Thin Solid Films of Oxides, Iodides, fyc.

§ 21. Among the earlier experiments were many in which the
changes due to films of oxide of different thicknesses were studied ;
indeed this was the primary object of investigation suggested by
Lord Kelvin. But constant difficulties and ambiguities presented
themselves, hindering the interpretation of even the simplest

On Contact Electricity of Metals. 123

experiments, and it was found necessary to enlarge the scope of the
research in order to remove or explain them.

§ 22. The experiments detailed below are among the most definite
of those carried out. They show large changes in potential on
account of very thin films of oxide, and prove that the amount of
change is dependent on the thickness of the film when below a
certain limit.

§ 23. Two plates of cast zinc, which had been carefully polished
on medium glass-paper the day before, gave with one another

+ 0-02 volt,

the upper plate being positive. The upper plate was now taken out
and heated on the back by means of a very small blowpipe flame. Its
face became slightly blistered, but not much discoloured, and when
cold it gave with the other, which had not been altered in any
way,

— 0-44 volt,

the " minus " indicating that the upper is now negative. This shows
a permanent fall of O46 volt due to heating in air.
§ 24. A plate of rolled zinc, which gave

—0-04 volt

with another plate of the same material, was heated as in the last
experiment, but to a higher temperature, very nearly to its melting
point. Its face became a streaky yellowish-brown, slightly purple
towards the centre (the brown parts turn purple if moistened).
When compared, cold, with the clean plate it now gave

-0-79 volt,

;a f all of O75 volt. Thus this oxidized zinc plate has practically the
same potential as copper. This great fall of potential does not take
p!ace by exposure to the atmosphere at ordinary temperatures, unless
possibly after the lapse of many years, for the potential of zinc
plates which have been left unpolished for many months is only two
or three tenths of a volt below that of clean zinc (see § 34).

§ 25. Similar experiments were made with copper. The film of
oxide was gradually increased in thickness by repeatedly heating the
plate, and the potential measured in each stage of oxidation, the plate
being cold. There was a change of about 0*03 volt in the negative
direction before the oxide-film became visible, and further increase in
the thickness of the film was judged by the gradual change of colour,
until the well-known dull purplish -black of massive copper oxide
was attained. The potential, measured each time when the plate
was cold, gradually fell until it reached a limit of about O30 volt

124 Dr. J. Erskine-Murray.

negative to a standard gold plate, which value may therefore be
taken as the potential of a mass of copper oxide at 15° C. It may
be remarked that there are good reasons, which will be given in
Chapter IX, for supposing that oxidation does not commence in air
unless the temperature of the plate be raised above 80° C.

§ 26. A plate of copper which had been polished on glass paper
and then on wash-leather gave

+ 0-20 volt,

with a standard gold plate, and was next held in iodine vapour for a
short time. It looked moist at first, but quickly became dry. In
this state it gave

-0-34 volt,

with the same standard, a change of 0 54 volt in the negative
direction. The surface had a dull colour with a whitish " bloom "
on it, the tint resembling that of clean copper, though rather darker.
Exposure to iodine vapour thus makes the surface of copper
nearly as negative as continued exposure to the atmosphere at a
high temperature.

§ 27. The potential of a clean zinc plate fell about 0*12 volt when
it had been exposed to iodine vapour.

§ 28. The iodine compounds formed on the metallic surfaces were
not stable, as the appearance and potential of the plates altered con-
siderably during twenty hours' exposure to the atmosphere.

§ 29. The effects of sulphur fumes, hydrogen sulphide, &c., were
tried, but though in most cases considerable changes were observed,
the results obtained were not satisfactory.

V. Atmospheric or Time Effects.

§ 30. A small variation of the potential is usually found to take
place during a short time after the plate has been polished, and before
it has settled down to a more or less permanent value. This is partly
due to the fact that the plate has been slightly warmed during
polishing, and takes some time to come to the atmospheric temperature
(see Chap. IX). As regards changes which are not due to variation
of temperature, I shall give some typical experiments in the following
sections of this chapter.

§ 31. Two plates of "high conductivity" copper were polished on
fine glass-paper, and several experiments by burnishing them by
mutual friction were then made (see § 16). Forty-seven minutes
after the original polishing, their potentials with the standard plate
were

(a) +0-035 volt.
(6) + 0-045 „

On Contact Electricity of Metals. 125

The plate (a) was left in the apparatus all night, that is to say, in a
position sheltered from dust, and in air partially dried by the
sulphuric acid in the lower part of the case; the potential next
morning, 20 hours 3 mins. after the measurements given above, was

+ 0-045 volt

with same standard plate. It was thus nearly constant. The plate
(&) was left in a rack in the laboratory without special protection,
with the result that next morning the potential, owing to exposure to
the air of the room for about 20 hours, had fallen to

-0-056 volt,

a change of — O'OOl volt. The plate (5) was now placed in the
apparatus, and remained nearly constant for 2 hours at least. Plate
(a) was left in the rack, and its potential fell 0"065 volt in about 2
hours. It is thus evident that at ordinary temperatures in a rather
dry atmosphere, and in a place protected from dust and light, the rate
of variation of the contact-potential of copper is very small ; in an
exposed place, however, it is no means negligible.

§ 32. A plate of block tin was polished on glass-paper. Its
potential varied with time as follows, the time being counted from
the completion of the polishing : —

Hours. Mins. Yolts.

0 22 +0-515

0 27 +0-520

0 46 +0-535

1 4 +0-535

1 23 +0-515

3 18 +0-495

4 6 +0-495

4 42 +0-495

• 71 12 +0-465

The plate was kept in the apparatus all the time and its potential
taken with a standard gold plate.

§ 33. In another experiment a tin plate polished on the finest
glass-paper gave, after 0 hours 15 mins.,

+ 0-525 volt.
After 23 hours 30 mins. it gave

+ 0-535 volt.

This experiment was made in June, while the previous onejwas
made in December. Hence probably the greater rate of variation in
the former was due to a moister and less pure atmosphere.

126 I)r. J. Erskine-Murray.

§ 34-. An old zinc plate which had probably not been polished for
many years gave

+ 0-37 volt

with the standard gold plate. It was next polished on glass-paper,
and gave

+ 075 volt

with the same standard. This shows that the ultimate effect of
exposure is to make the potential of zinc fall. I have found that in
some cases this fall is preceded by a slight rise, as in the case of tin
(§§ 32, 33) ; but the ultimate effect is in the negative direction.

§ 35. The potential of a silver plate which had been polished on
glass-paper remained constant for an hour. The experiment was not
continued further.

§ 36. Aluminium becomes gradually negative in air. In one case
the potential fell about 0*18 volt in a week. The time-change of this
metal, mainly on account of its large temperature-variation (see
Chap. IX), is rather difficult to determine.

§ 37. An iron plate which had not been cleansed for two months
rose O05 volt when polished. Hence the effect of exposure had been
to. make its potential fall slightly.

§ 38. I have included these results, for which, as for many others
like them, I can as yet give no definite explanation, in the hope that
they may serve as a basis for future experiment and generalization.
The great difficulty in all such experiments on contact electricity is
to define the circumstances and,, with .them, the causes of any given
variation.

VI. Very Thin Liquid Films on Metals.

§ 39. In the earlier experiments it was found that, as a rule, copper
polished on glass-paper or emery-cloth was about 0*20 volt negative to
the standard alcohol- washed gold plate.

On comparing this value with M. Pellat's results* I found that his
value for copper was about 0'20 positive to the same standard. I at
once determined to try his method of cleansing the plate so as to find
if the difference (0'40 volt) were due to that alone. For this purpose
a copper plate was carefully polished on glass-paper. It gave, with
the standard,

—0-20 volt.

It was then washed with alcohol and allowed to dry in air. It now

gave

+ 0-22 volt

with the same standard. The change due to the treatment is there-
fore -f 0'42 volt, and continues permanent many hours.
* « Ann. Chim. Phys.,' 1881.

On Contact Electricity of Metals. 1 2 7

§ 40. A plate of thickly oxidized copper giving, with, the standard
plate,

-0-24 volt

gave, after it had been washed with alcohol, and allowed to dry,

O'OO volt,

a rise of 0'24 volt.

§ 41. A zinc plate, when cleaned on glass paper, gave

+ 0-61 volt.

It was then washed with alcohol, and when apparently quite dry
gave

+ 0-94 volt,

remaining constant at this value for many hours. The rise in this
case is 0*33 volt.

§ 42. The results of many similar experiments made with .alcohol
and other liquids on gold, silver, zinc, copper, iron, tin, lead, and
aluminium will be found in Table II. It is notable that in almost
every case the contact-potential of a metal which has been polished
on a hard dry material rises at least O'l5 volt in consequence of
alcohol washing, and that this change is nearly permanent for many
hours after the plate appears to be quite dry.

§ 43. It may be remarked that, as M. Pellat appears to have;
invariably washed the metal with alcohol before making a measure-
ment of its potential, his results do not apply directly to metals which
have been cleaned by means of a hard dry agent only. Even in the
experiment which he gives on pp. 79 — 80 of his paper as a proof that
alcohol-washing does not permanently alter the potential of a clean
gold plate, he appears to have used a plate which had already been
washed with alcohol ; his result, therefore, does not prove that
alcohol-washing makes no change in the contact-potential of a clean
plate, but only that subsequent washings do not alter the state of
surface, i.e., that the effect is nearly permanent. This agrees with
the results given above and in Table II.

§ 44. The alcohol film, whether in combination with the metal or
not, must in any case displace the air from the surface of the plate.
Other liquids seem to leave films in much the same way, though the
change of potential is different for each liquid ; in some cases, e.g.
turpentine on zinc and copper, it is in the positive direction for the
positive metal and in the negative for the other.

VII. Thick Liquid Films on Metals.

§ 45. In experimenting with films of sensible thickness the liquid
was usually placed on a flat metal plate, its surface-tension being

128

Dr. J. Erskine-Murray.

Table II. — Permanent Changes produced in Contact-potential of
Metals by washing with Alcohol and drying in Air.

Metal.

Previous treatment.

Potential with standard
gold plate.

Before.

After.

Change.

Copper .

yy '
» •
» •

» •

Gold

volt.
-0-20
+ 0-09
+ 0-02
-0-13
-0-24

+0-10

+ 0-08
+ 0-17

+ 0-61
+ 0-56
+ 0-61

+ 1-05
+ 1-04
+ 1-13
+ 1-11

volt.
+ 0-22
+ 0-29
+ 0-14
+ 0-14

o-oo

+ 0-20

+ 0-16
+ 0-29

+ 0-80
+ 0-66
+ 0-94

+ 1-10
+ 1-07
+ 1-28
+ 1-26

volt.
t-0-42
+ 0 -20
+ 0-12
+ 0-27
+ 0-24

40-05

+0-10

+ 0-08
+ 0-12
+ 0-17
+ 0-14

+ 0-19

+0-10

+ 0-33

+ 0-05
+ 0-03
+ 0-15
+ 0 09

Filed

Oxidised

Polished with dry "plate powder"

Silver

Iron ..... i .

» j> ..»«••«.

Scraped thoroughly with a knife

Lead

Tin

Aluminium
»
»
»

sufficient to retain it if its depth were not more than 0'3 or 0'4 cm.
In other cases a shallow metal dish was used. The behaviour of
water puzzled me for some time, and made me realize the extreme
difficulty of obtaining a clean liquid surface. After some preliminary
experiments I found that distilled water which has not been exposed
to the atmosphere gives fairly constant results when lying to a depth
of 0'2 cm. on one of the standard gold plates. When water on gold
formed the one plate and a dry standard gold plate (see § 8) the
other, the value found was O'lO volt, the water being negative. Thus
clean water in contact with gold is about O'lO volt negative to it.
The value found is quite different if the water has been exposed to the
air for some time, and is usually positive instead of negative to the
standard plate.

§ 46. Air expelled from the lungs produces a very marked change
in the contact-potential of water. By blowing through a fine glass

On Contact Electricity of Metals. 129

tube which dipped under the surface of a layer of distilled water on a
gold plate, the potential was changed from

—O'lO volt
with the standard plate to

+ 0-16 volt,

and remained at this latter value for more than half an hour, showing
that the change was not due to a rise in temperature. The curious
point is that the change seems to be only in the surface of the liquid ;
for when most of it was shaken off the potential fell to

-0-05 volt

although the plate was still wet all over. This appears as if the
alteration were due to a surface film of oily or dusty matter on the
water. It was found that distilled water which had been exposed to
the air of the room for some time gave the same value as water which
had been breathed through.

§ 47. A lead plate and a flat circular leaden dish were scraped
clean with a knife, and next morning, when compared with each
other, they gave

+ 0-10 volt,

the plate being positive to the dish. Water was now poured into the
dish until it was nearly full, 0'4 cm. deep, the potential remaining
the same; i.e., the lead plate gave with the water in the leaden dish,

+ 010 volt,

water in leaden dish being negative.

§ 48. The plate and dish were again scraped, and this time they
gave

+ 0-05 volt,

the plate being positive. Water was next poured into the dish,
which gave, with th.e dry lead plate,

+ 0-09 volt,

the water in the dish being negative as before. The dish was now
removed, and a standard gold plate put in its place j with this the
lead plate gave

+ 0-52 volt,

the lead being positive. Thus water in contact with lead is about
0*9 volt negative to dry lead.

§ 49. Turpentine seems to produce opposite effects on zinc and
copper, i.e., copper becomes more negative, and zinc more positive,

VOL. LXIII. L

130 Dr. J. Erskine-Muiray.

when wet. Thus copper and zinc which had been dry-polished gave
with one another

077 volt,
zinc positive.

With the zinc wet with turpentine,

0-96 volt.

And with both zinc and copper wet about

1-20 volts.

Their potential difference increased somewhat as the turpentine
dried up ; and when apparently quite dry its value was still at least

1-20 volts,

the plates, however, smelt strongly of turpentine, showing that an
invisible layer remained on their surfaces.

§ 50. A crystal of copper sulphate gave, with a standard gold

plate

+ 0-02 volt,

copper sulphate positive. This result was obtained in connection
with some experiments on the contact-potential of an aqueous solu-
tion of copper sulphate. It was found that such a solution in a
copper dish gave about + 0'07 volt with a dry standard gold plate,
the solution being positive. Blotting-paper saturated with copper
sulphate gave about +0*10 volt with the same standard plate. As
no special precautions were taken in these experiments to obtain
a perfectly pure liquid surface, one cannot, especially in view of the
changes described in § 46, be quite certain that they represent the
true potential of copper coated with a solution of its sulphate. They
agree, however, with Professors Ayrton and Perry's values for satu-
rated and non-saturated solutions.

§ 51. One of the standard gold plates which had been polished
with Hollis's plate powder used dry gave, with a similar plate which
had a layer of alcohol on it,

-0-13 volt.

When the alcohol had dried up the value was

-0-05 volt,

the polished plate being negative as before.

§ 5*2. The conclusion which I draw from the experiments described
in this and the preceding chapter and in the tables is, that a layer of
liquid on a metallic surface does not give, with a metal separated
from it by air, a definite potential-difference of its own, as in similar
circumstances a solid conducting film would do, but merely adds a

On Contact Electricity of Metals. 13 f

certain amount to that of the plate on which it lies. Thus two differ-
ent metals coated with layers of the same liquid do not, as a rule in
air, give zero potential-difference, but usually give nearly the same
potential-difference as the dry metals. For instance, the potential of
lead with an alcohol layer O'l cm. deep on it is about 0'13 volt higher
than that of dry lead, while that of wet copper is about the same
amount higher than the average value for dry copper. There is no
tendency shown for a liquid film to take up a definite potential inde-
pendent of that of the metal on which it lies, with any metal sepa-
rated from it by a dielectric, as a solid conducting film would do.
This seems to be the most important distinction between solid and
liquid conductors, and it is in accord with what is known of voltaic
cells; for if the potential-differences in the chain copper-water-zinc
were equal and opposite to that of zinc-copper, as copper-iron-zinc is-
to zinc-copper, we should have no electromotive force in the circuit,
when the materials are all at one temperature. In most of my
experiments the type is copper- water-nonconductor (air) -water-zinc,,
and not copper- water-zinc ; the members of the first and last pairs'
are in contact, while a non-conductor intervenes between the two free
water surfaces, these being able to take up their natural contact-
potential-differences with the metals they touch ; but the sum of the
potentials, copper- water and water-zinc, is not equal to copper-zinc,
thus proving that the two free surfaces of water are not at the same
potential. This is directly demonstrated by the experiments of
Professors Ayrton and Perry, and by the results given in Chaps. VI,
VII, and X of this communication.

If the intervening layers of non-conductor be removed by joining
the liquid surfaces so that there is but one mass of liquid between
the plates, conduction at once tends to reduce the whole liquid to the
same potential, leaving the contact-potential differences, now un-
balanced by the removal of the non-conducting medium which was
capable of sustaining the stress, to act as external electromotive
force. This then shows the connection between contact-potentials,
measured electrostatically by the method described in this paper, and
the electromotive force of a voltaic cell.

§ 53. The con tact- potential of a liquid with a metal is clearly, if
the air-potentials be neglected, the difference between the potential
of the dry metal and that of the metal when wet with the liquid ; the
same standard plate being used as zero of potential in both cases.
The results given in the tables must no doubt be in some cases com-
plicated by the formation of solid compounds in the interface between
liquid and metal, so that the liquid is no longer in contact with clean,
metal, and the liquid must also displace any film of condensed air
which may exist on the metal. The. latter influence will be discussed
in Chaps. VIII and X.

L 2

132

Dr. J. Erskine-Murray.

Table III. — Potential of Metals covered with visible layer of

Alcohol.

Metal.

State of surface.

Potential with standard gold
plate.

Dry.

Wet.

Change.

Copper ....
Gold

Filed • wet with alcohol

Tolt.

-0-13
+ 0-10

volt.
+ 0-19

+ 0-18
+ 0-19

+ 0-74
+ 0-74

volt.
+ 0-32

H-0-13

+ 0 -08
+ 0-09

+ 0-13
+ 0-13

Dry-polished ; wet with alcohol
Q"lass-paper polished. .... .

Silver

Lead

Wet, 0'05 cm deep

+ 0-61

Table IV. — Change in Contact-potential of Zinc and Copper due to
Layers of Turpentine, Rosin Oil, and Indiarubber Solution.

Potential, volts.

Liquid.

Metal.

Remarks.

Change.

Wet with turpen-

Copper, polished on

-O'll

Note.— The plates

tine

glass-paper

were compared

Zinc, polished on

,.

+ 0-20

with one another,

glass-paper

and not with the

standard plate.

Wet with rosin oil

Copper, polished on

-0-12

Hence only the

glass-paper
Zinc, polished on

..

-0-02

change of poten-
tial is given.

glass-paper.

Wet with india-

Copper, polished on

, ,

+ 0-02

rubber solution

glass-paper
Zinc, polished on

+ 0-07

glass-paper

VJII. Films formed on Metals by Gases.

§ 54. The potential of a metal is usually altered by soaking the
plate in a gas other than air. If the gas be oxygen, this alteration
is as a rule only temporary, and apparently depends on the formation
of a surface film, or rather on a cjiange in the film which doubtless
already exists. It will be shown that the change of potential of zinc

On Contact Electricity of Metals. 133

due to soaking in oxygen is nearly equal to that o£ copper ; hence
the film of oxygen acts like a liquid film (Chap. VII), but its effect
is less permanent. Previous experimenters, except Lord Kelvin,
appear to have neglected the existence of these films, and to have
looked only to the nature of the body of gas between the plates. Of
course I do not here allude to the " double-layer " which has been
offered as an explanation of the phenomenon, but to a layer in
mechanical and electrical contact with the metal. If the contact-
potential of two metals immersed in a gas were the sum of the
potential-differences between each metal and a skin of gas close to it,
we should have no slope of potential in the body of the gas between
the plates. That a slope does exist, however, is proved by Lord
Kelvin's earliest experiments with the divided ring of copper and
zinc. In this connection Dr. Bottomley's research on contact-
electricity in high vacua * is of great importance as showing that
the volta-potential of metals is not sensibly different in different
gases so long as the metals are not chemically affected, and is not
sensibly altered by a great reduction of pressure. The body of the
gas may possibly have some influence, but the variations which have
frequently been attributed to it may usually be more satisfactorily
explained as being due to change in the film in contact with the
metallic surface. In the case of a gas which acts vigorously on the
metal at ordinary temperatures, the film is permanent, and is
probably a solid compound ; in other cases it is not permanent, and
hence probably not solid.

§ 55. In * Nature ' for 1881, Lord Kelvin describes some very
important experiments on this subject. As these appear to be but
little known I shall give some extracts from his paper before
describing my own results. Under the date November 23, 1880,.
Lord Kelvin says : — " I have found that a dry platinum disc, kept
for some time in dry hydrogen gas, and then put into its position in
dry atmospheric air in the Volta-condenser, becomes positive to
another platinum disc which had not been so treated, but had simply
been left undisturbed in the apparatus. The positive quality thus
produced by the hydrogen diminishes gradually, and becomes in-
sensible after two or three days. P.S. — On December 24, 1880, one
of the platinum plates in the Volta- condenser was taken out ; placed
in dried oxygen gas for forty-five minutes ; taken out, carried by
hand, and replaced in the Volta- condenser at 12.30 on that day. It
was then found to b$ negative to the platinum plate, which had been
left undisturbed. The amount of the difference was about 0'33 of a
volt. The plates were left undisturbed for seventeen minutes in the
condenser, and were tested again, and the difference was found to
have fallen to 0'29 of a volt. At noon on the 25th they were again
* ' Brit. Assoc. Report,' 1885.

134 Dr. J. Erskine-Murray.

tested, and the difference found to be O18. The difference had been
tested from time to time since that day, the plates having been left
in the condenser undisturbed in the intervals. The following table
shows the whole series of these results : —

Electric difference between surfaces of a
platinum plate in natural condition,
and a platinum plate after 45 mins.
Time. exposure to dry oxygen gas.

Dec. 24, 12.30 P.M 0'33 of a volt.

„ 24,12.47 „ 0-29

„ 25, noon k 0'18

„ 27, „ 0-116 „

„ 28, 11.20 A.M 0-097

„ 31, noon 0-047 „

Jan. 4, 11 A.M 0042

„ 11, 11.40 A.M 0-020 „

After detailing some experiments in which the plates "were coated
with the gases by electrolysis, Lord Kelvin concludes : " Thus in the
case of polarization by oxygen, as well as in the case of polarization
by hydrogen, the effect of exposure to the dry gas was considerably
greater than the effect of electroplating the platinum with the gas by
the electromotive force of one volt."

The large effects on contact-potential produced by films formed
from gases are clearly shown in these experiments of Lord Kelvin's.
It is well known that platinum and other metals have the property
of occlnding large quantities of gas in their surface layers, and that
the condensed gas is possibly in the liquid state, which would account
for the similarity between the effects of liquids and of gases on
metals.

§ 56. The plates with which my first experiments on this subject
were made were of " high conductivity " copper. They had been
polished on fine glass-paper 5 hours before, and their mutual
potential had remained constant at

0-02 volt

for 4 hours. The lower plate was then put into a glass vessel, into
which oxygen gas was admitted from a cylinder, and the oxygen,
which was of Messrs. Brin's manufacture, guaranteed 93 — 95 per cent,
oxygen (nitrogen is usually the only impurity), was allowed to stream
through the glass vessel containing the plate for some minutes, and
the exit and inlet of the vessel were then closed. Forty-five minutes
later the plate was taken out and its potential again measured with
the other plate, which had remained in air during the interval.
Counting time from the moment at which the plate was taken out of

On Contact Electricity of Metals. 135

the oxygen, the potential varied as shown below, the oxygenized
plate being positive to the other in all cases : —

Time. Contact-potential.

Hrs. Mins. Yolt.

0 3 0-12

0 19 0-08

0 30 0-06

17 20 0-03

Thus the effect of increasing the proportion of oxygen in the surface
film was to make the copper more positive.

§ 57. This variation is in the opposite direction to that found by
Lord Kelvin for platinum which has been soaked in oxygen. In
order to make sure that this difference was not the effect of some
impurity in the oxygen, I repeated his experiment, obtaining the
same result as he had obtained. This shows that the result given
above was not likely to be due to an impurity which had influenced
the action of the oxygen.

§ 58. Without any further treatment the same copper plate was
placed in the bell-jar and the oxygen admitted. After 45
minutes it was taken out and its potential again measured by com-
parison with the other plate. The results are given in the following
table, time being counted from the moment the plate was taken out of
the oxygen : —

Time. Contact-potential.

Hrs. Mins. Yolt.

0 2 0-13

0 10 0-08

0 21 0-07

0 29 0-06

The experiment was discontinued before the plate had returned to
its original value ; but it would no doubt have done so in a few hours,
for the amount of change, and its rate, are almost exactly the same as
in the former experiment (see § 56).

§ 59. In the following experiment the conditions were somewhat
varied. A copper plate was polished on glass-paper. It gave, with
a standard copper plate,

-0-05 volt.

A jet of oxygen was now sent against its surface for 2 or 3
minutes, and with the same standard plate it now gave

-0-06 volt.

It was then left in oxygen for 25 minutes, and on being taken out
gave

136 Dr. J. Erskine-Murray.

Time. Contact -potential.

Hrs. Mins. Volt.

0 4 -t-0'060

0 13 +0-035

which shows that its immersion had raised its potential 0"12 volt. I
now warmed ifc with a soldering-bolt applied to its back. When
about 47° C. (see Chap. IX) it gave

Time. Contact-potential.
Hrs. Mins. Yolt.

0 16 +0-020

It was again warmed slightly, and when at about 30° C. gave

Time. Contact-potential.

Hrs. Mins. Volt.

0 42 -0-010

When 16° C.,

4 48 -0-040

its potential thus coming back to very nearly the original value.

This experiment shows : (1) that the change requires considerable
time ; for even a fairly strong jet of oxygen playing on the plate for
2 or 3 minutes produces no appreciable effect, while 25 minutes
in still oxygen causes a rise of 0*20 volt; (2) that gentle heating
does not produce a rise, as it would do with clean unoxygenized copper
(see Chap. IX), but it must be remembered that the copper was,
when heat was applied, already above the potential to which heat
alone would have raised it; hence this experiment does not show any
connection between temperature- variation and density of oxygen
film, as might at first sight be supposed.

§ 60. A zinc plate which had been polished on glass-paper gave
with a standard copper plate

0'81 volt, zinc positive.

It was then put into oxygen and left for 15 minutes. After being
taken out, its potential was again measured with the same standard
plate, and was as follows : —

Ti
Hrs.

0
0

4
4

me.
Mins.
2

Contact-potential.
Volt.
0-89

10

.... 0-87

18

0-86

35..

. 0-85

This shows that zinc also is more positive after immersion in oxygen.
§ 61. The same zinc plate was again polished on glass-paper and
gave

+073 volt

On Contact Electricity of Metals. 137

with the standard copper. A short time later it gave

+ 070 volt.

It was now put into oxygen for 10 minutes, and after being taken
out gave

Time. Contact-potential,

Hrs. Mins. Volt.

0 3 +0-80

0 13 +078

17 1 +074

§ 62. A tin plate was polished on clean glass-paper, and gave with
a copper plate

+ 0-40 volt,

tin being positive. Fifteen minutes later the potential of the plates
had not altered. I now put the tin into the bell-jar and turned on
the oxygen. After it had soaked for 47 minutes it was taken out and
compared with the same copper plate. It gave

Time. Contact-potential.

Hrs. Mins. Yolt.

0 5 +0-32

0 13 +0-32

0 35 +0-35

Thus the variation of tin appears to be in the negative direction, like
that of platinum.

§ 63. A silver plate, polished on glass-paper, gave with a standard
copper plate

-0-04 volt,

and remained constant during an hour. It was then put into oxygen
for 15 minutes, and when taken out its potential was found to be

Ti
Hrs.
0
0
0
0
0

me.
Mins.
3

Contact-potential.
Yolt.
... +0'02

19

... — O'Ol

40

... —0-02

45

... —0-02

59..

, -0-03

Thus by immersion in oxygen for 15 minutes it had risen O'OG
and had fallen to nearly its original value in an hour in air.

§ 64. Silver polished on clean "fine" glass-paper gave with a
standard copper

—0-095 volt.

133 Dr. J. Erskine-Murray.

After it had been 24 minutes in oxygen it gave in air-

+ 0-015 volt,
and 12 minutes later

+ 0-010 volt,

showing that the potential had in 24 minutes in oxygen become 0*110
more positive.

§ 65. It is noticeable that the amount of change in these experiments
on silver is to some extent proportionate to the time of exposure to
oxygen. Thus, in § 63, 15 minutes in oxygen caused a rise of 0'06
volt; while, in § 64, 24 minutes in oxygen caused a rise of O'll volt,
but there is no doubt a limit to the change.

§ 66. In searching for an explanation of the temperature-
variations described in Chapter IX, I compared them with those given
above. In the case of copper, the oxygen-film variation is in the same
direction as the temperature-variation of copper in air, which suggests
the possibility of the latter being caused by an increase of the pro-
portion of oxygen in the film at higher temperatures on account of a
greater attraction between the elements. The same reasoning holds
as regards zinc and tin, but the results for silver are in direct
opposition ; while the further experiments described in Chapter X,
which show that the temperature- variations exist in cases where air
is entirely excluded from the metallic surface, render such an ex-
planation very doubtful. Probably, therefore, the temperature-
variation is the more general of the two, it being a change in contact-
potential of the metals, which, if they are exposed to a gas, may be
complicated by alteration of the surface- film.

IX. Temperature Variations.

§ 67. A large number of determinations were made of the variation
of contact- electricity with the temperature of the conductor. This
was done by heating one plate while the other was kept cool, and
their potential- difference was measured from time to time as the
warm plate was cooling, their temperatures being observed at the
same time. In the diagrams, the abscissae represent temperature
and the ordinates potential ; each curve, therefore, shows the tem-
perature-variation of the contact-potential of a particular metal.
For instance, the potential represented by the point which corre-
sponds to 16° C. on the gold line is called zero in this and the other
chapters of the present communication. Thus a standard gold plate
(see § 8) at 40° C. is 0'04 volt negative to one at 16° C., and an
aluminium plate at 40° C. is O'lO volt, positive to aluminium at 16° C.,
or 1-20 volts positive to a gold plate at 16° C.

It must be remembered that unless stated otherwise these varia-

On Contact Electricity of Metals.

tions are for metals in air. In the experiments described in Chapter
X, however, the metallic surfaces were protected by solid non-
conducting films, and were not in contact with the atmosphere ;
nevertheless, temperature-variations were found, which in the case
of silver were actually larger than those which took place in air.

§ 68. One of the copper plates used was hollow and could be
filled with water and a thermometer inserted, but with the other
plates other methods of measuring temperature had to be adopted.
In some cases the temperature was measured thermo-electrically,
while in others a simpler and more rapid mode of measurement was
used, which, though not very accurate, is quite reliable within
certain limits.

§ 69. By touching the back of the plate I found that its tempera-
ture could be judged as "tepid," "slightly warm," "warm," "very
warm," and so on. It was found experimentally that these terms
correspond to constant temperatures ; or rather that each term
denotes a small range of temperature, the middle point of which
may be taken as corresponding to the term. In determining the
values of these terms a plate was used in which a thermometer was
inserted. One observer touched the plate with the tips of the
first and second fingers and judged its state, naming it by one
of the terms, "warm," "tepid," &c. ; the other observed the ther-
mometer, and the temperatures found to correspond to each term are
as follows : —

Cold 16° C.

Quite cool 24

Cool 28

Rather cool 30

Tepid 35

Slightly warm 40

Warm 47

Very warm 50

Hot 53

Very hot 57

Too hot to touch continuously 63

Too hot to touch for more than one second . . 73

This method of measuring temperature is rough and ready, but
since the possible errors are within limits of a very few degrees, one
only requires to take the average of a considerable number of results
in order to arrive at a very fair approximation to the true values.
In experiments on contact electricity in air there are so many possible
causes of disturbance that extremely accurate measurement of the
temperature is of little use, especially if it require that much time be
spent over each reading.

140 Dr. J. Erskine-Murray.

§ 70. As a rule the upper plate was heated, in order that the
lower plate might not be affected by draughts of hot air, as would
have been the case if the lower had been hot and the- up per cold.
Sometimes, during the time of cooling, the upper part of the
apparatus, including of course the upper plate, was removed after
each observation and was replaced only the moment before the next.
In other experiments the upper plate was merely drawn up as far as
possible (about 10 cm.) to prevent its warming the lower one. The
temperature of the lower plate was also observed, but as a rule it
varied only a very few degrees.

§ 71. At first I used to apply a hot soldering bolt to the back of
the plate in order to heat it, but latterly I heated two or three small
blocks of tinned copper and placed them on the back of the
upper plate. By this second method it was possible to observe the
variation of the potential during the rise as well as the fall of
temperature.

§ 72. In attempting to determine the temperature- coefficient of
copper we were long baffled by curious anomalies. Sometimes the plate
was positive when hot, other times negative, and occasionally it did
not vary at all. The clue to this was found in observing that during
one experiment while the copper was cooling it was at first positive,
then negative, and then it gradually became positive again, though
never quite reaching its original value.

Now it had been found that copper oxide is negative to copper,
and that it became temporarily more negative when hot ; hence it
was guessed that the successively positive and negative variation
must be due to hot clean copper being positive to cold copper, but
that it had finally become oxidized and therefore negative whether
hot or cold, the small permanent change being due to the thin
coating of oxide formed.

§ 73. The copper was heated much more gently next time, and
gave the expected result that clean copper becomes rapidly more
positive as its temperature rises, and that, on cooling, its potential
returns to its original value unless the temperature has exceeded a
certain limit. If this limit has been exceeded its potential rapidly
becomes negative and does not return to its original value.

§ 74. At ordinary atmospheric temperatures the surface of clean
copper remains for a long time almost unaltered either visibly or
electrically (see § 31), and the film which ultimately forms on the
surface cannot be pure copper oxide, because the potential of tarnished
copper is higher than that of copper oxide obtained by neating in
air. If, however, the temperature of the copper is raised to about
80° C. it immediately begins to oxidize, though heating to a tempera-
ture below this limit does not rapidly produce any permanent change.
Thus there is, as it were, an ignition point for copper and oxygen in

On Contact Electricity of Metals. 141

air; below it, little action takes place; above it, combination
proceeds vigorously.

§ 75. I snail now give a specimen experiment. The two standard
gold plates gave

—0-02 volt,

the minus sign indicating that the upper plate is negative. I now
heated the upper: when "tepid," i.e., about 35° C., it gave with the
gold plate

-0-045 volt.

It was next heated farther until " very hot " (57° C.) and gave

—0-06 volt.
When it had cooled down to " tepid " (35° C.), it gave

-0-04 volt.
When "cool" (28° C.),

-0*03 volt.

Some hours later, when both plates were cold, they gave as at first

-0'02 volt.

Hence the potential of gold which has been washed with alcohol
and allowed to dry falls temporarily about 0'0016 volt per degree
centigrade rise of temperature.

§ 76. Most of the temperature experiments on copper were made
with the hollow plate previously mentioned, which was filled with
hot water in which the bulb of a thermometer was placed. In many
of the experiments on zinc, and also on aluminium, a thermo-electric
arrangement was used, and the results obtained with it do not differ
materially from those obtained by the above method (§ 69). These
and other details are noted on the diagram.

§ 77. The diagram gives the temperature-variations of all the sub-
stances studied. The curves in it are plotted by taking the results
for each metal of those experiments which are most free from all
complication or cause of doubt. If the curves be prolonged in the
direction of lower temperature they appear to meet somewhere below
— 200° C., and probably asymptotically to the line representing O4
volt positive to standard plate at 16° C. Within their range they
show contact-potential-differences diminishing with lowered tem-
perature. The only apparent exceptions are clean copper, and
silver coated with glass ; but both their curves are distinctly bent
between 16° C. and 50° C., so that probably they are directed towards
the same point as the others at lower temperatures. Thus it appears
that at about —200° C. the coutact-potential-differences of metals

142

Dr J. Erskine- Murray.

1

+A5

+/-0
+9
+-3
+•7

flt*

-a-

1

SO" OO

Temper&Gure , Centigrade.

oO"

On Contact Electricity of Metals.

143

may vanish, and that a plate of any metal at that temperature would
be about 0'4 volt positive to a standard gold plate at 16° C.

§ 78. The approximate numerical values of the temperature -
variations are given in the following table : —

Table V.

Metal.

Approximate
range of
temperature.

Potential of
metal with
standard
gold plate.
Both at 16° C.

Variation of
potential per
1*C. Standard
plate kept
always at 1 6° C.

Aluminium, polished on glass-paper

°C.
16—50
16—40
16—47
15—62
16—75
16—33
16—55
16-65
16—60
16—70
16—30
30—50
16—30
30—60
16-60
16 65

volts.
+ 1-10
+ 0-98
+ 1-30
+ 0-73
+ 0-58
+ 0-52
+ 0-20
+ 0-28
+ 0-12
+ 0-16
-0-05

-t-0'04

o-oo

-O'll

volts,
-i- 0-0043
+ 0-0032
+ 0-0045
+ 0-0013
+ 0-0016
About -0-0010
-0-0022
-0-0007
-0-0007
-0-0004
About -0-0035
About -0-01 10
very small.
A.bout + 0'0015
-0-0016
-0-0016

„ alcohol- washed, dry . .

Tin polished on glass-paper ••••••

Iron polished on emery-cloth. . . . .

Silver, polished on gla*s-paper ....

Copper, polished on emery-cloth . .
» » » • •

Oxidised copper.

It must be clearly understood that these are true temperature-
variations and not permanent changes in the plate caused by exposure
to a high temperature.

X. Elimination of Metal- Air Potentials by Solid Non-conducting Films
on the Metallic Surfaces.

§ 79. As very great differences of opinion seemed to exist as to
the part played by the layer of air which is close to the metallic
surface, I devised a method in which it should be removed and a film
of solid non-conducting material of a very different chemical nature put
in its place. A copper plate which had been polished on glass-paper
was filed with a clean dry file which had not been used for any other
metal. Its potential with the standard gold plate being

+ 0-045 volt.

A zinc plate was prepared in an exactly similar way, and with the
copper plate gave

+ 0-655 volt.

144 Dr. J. Ei-skine-Murray.

The copper plate was now gently heated with a bolt until it was hot
enough to melt paraffin-wax ; the temperature, ahout 50° C., required
for this is not sufficient to cause sudden permanent change of the
copper surface (see § 74). Paraffin-wax was then poured on, and
the plate was filed with its own file while covered with molten wax.
Thus the fresh surface exposed by the filing came directly into
contact with the wax. More wax was poured on and the filings
drained off, the plaife remaining well covered with wax all the while.
Ifc was then allowed to cool, and gave with the bare zinc plate

+0-555 volt,

zinc being positive as before. Thus the change due to substituting
paraffin-wax for air next the copper is not more than + O'lOO volt.
I now waxed the zinc in exactly the same way. When it was quite
cool it gave with the waxed copper

+ 0-602 volt,

showing that waxing the zinc had raised its potential

+0-047 volt.

So, on the whole, the substitation cf wax for air on both copper and
zinc had only decreased their mutual potential by

+ 0-053 volt

and the potential of the waxed plates remained nearly constant for
several hours. The changes due to waxing the plates as given above
were confirmed by the independent comparison of each plate with the
standard gold plate. It does not follow that even the small changes
which did occur were due solely to the substitution of wax for air, for
they may have been caused by slight changes in the surface on account
of the filing.

§ 80. An aluminium plate was coated with wax in the way
described in § 79, a knife being used to scrape the surface under the
molten wax. When cold, this waxed plate gave with a bare zinc one

+ 0-36 volt,

which is about the usual value for bare aluminium and zinc. The
removal of the air had therefore not appreciably altered the potential.
§ 81. I now warmed the waxed aluminium slightly. Its potential
with the zinc varied as follows : —

47° C +0-41 volt.

35° C +0-37 „

28° C +0-35 „

This gives a variation of about

0'0032 volt per degree centigrade,

On Contact Electricity of Metals. 145

which is nearly the same as the temperature-variation of bare
aluminium in air.

§ 82. A plate of silvered glass used with the glass side facing a
standard plate gave almost the same potential as clean silver in air.
This plate, which was practically silver coated with glass, gave a
temperature-variation larger than that of silver in air. In this case
we have glass in contact with the silver surface instead of air, but
the change does not alter the potential. It may be mentioned that
the back of the silver film was painted black, and not coated with
glass ; but this is of small consequence, since it has been proved by
experiment that the condition of the back of a plate does not sensibly
affect the volta contact-potential ; or, more generally, that if parts of
a plate be in different conditions, the potential observed will be the
mean of the potentials of the different parts, the importance of each
part being proportional to its capacity.

§ 83. On account of the great attraction of sodium for oxygen, it
seemed of interest to measure its potential in circumstances which
excluded that gas from the surface of the metal. In order to effect
this two pieces of thin sheet-glass, each about 6 cm. square, were put
into a dish of melted paraffin-wax together with some clean sodium,
and a large drop of the sodium was put between the plates of glass
and squeezed out into a small plate of 2 or 3 square cm. area. The-
glass plates, with sodium between them, were taken out of the melted
wax and allowed to cool. Since the glass plates were of much
larger diameter than the sodium, the edges of the latter were pro-
tected by the wax which filled up the space between the plates not
occupied by sodium. The flat faces of ihe sodium were apparently
in contact with the glass. The sodium was connected to the elec-
trometer by a fine copper wire. The greater part of the sodium
surface was bright or only slightly tarnished, and it remained in
almost the same condition for many days, being protected by the
glass plates and by the wax which filled the space between them
unoccupied by sodium. The first measurements gave sodium

2'86 volts

positive to a tarnished zinc plate, i.e., about

3'56 volts

positive to the standard gold plate. This potential gradually de-
creased.

§ 84. Experiments were made to make sure that the result was
not due to temporary electrification of the glass. For instance I
breathed on the glass, causing a conducting layer of impure water to
form on its surface. Repeated measurements, made by the usual
method, showed that the potential at once fell to a small fraction of

VOL. LXIII. M

146 Prof. J. C. Bose. On the Rotation of Plane of

a, volt, but slowly rose again to nearly its original value as the film
evaporated. This shows that the electrification was not a temporary
one of the glass surface, for that would not have returned to a
definite value. Heating the plate by radiation or washing the glass
with benzol caused the potential to rise further, but in no case was
the potential quite so high as when the plate was first formed. An
even more convincing proof that the potential measured was really
that of the sodium, was found in the fact that the sensibility of the
apparatus was such as would be given by a plate the size of the
sodium. If the electrification had been on the whole surface of the
glass, the sensibility, on account of the larger surface, wonld have
been at least ten times as great as that observed.

§ 85. The experiments described in this chapter show that (i)
when two metals are coated with the same non-conductor, such as
wax or glass, their potential is not sensibly different from that of the
bare metals in air ; (ii) that temperature-variation still takes place,
though air be excluded. These results seem to prove that gaseous
•films play no essential part in the phenomenon.

4< On the Rotation of Plane of Polarisation of Electric Waves
by a Twisted Structure." By JAGADIS CHUNDER BOSE,
M.A., D.Sc., Professor of Physical Science, Presidency
College, Calcutta. Communicated by Lord RAYLEIGH,
F.R.S. Received February 1 4,— Read March 10, 1898.

In my previous papers* I have given accounts of the double
refraction and polarisation of electric waves produced by various
crystals and other substances, and also by strained dielectrics. An
account was there given of the polarisation apparatus with which
the effects were studied. In the present investigation effects had
to be studied which were exceedingly feeble. The apparatus had,
therefore, to be made of extreme sensitiveness ; but the secondary
disturbances became at the same time more prominent, and the great
difficulty experienced was in getting rid of these disturbances.

In one of my communications I alluded to the fact that these
secondary disturbances are to a great extent reduced when the radia-
tors are made small. The advantage of a large radiator is the com-
parative ease with which the receiver can be adjusted to respond to
the waves, but this advantage is more than counterbalanced by the
increased difficulty with the stray radiation and other disturbances.

* "On the Polarisation of the Electric Kay by Double-refracting Crystals,"
* Journal of the Asiatic Society of Bengal,' May, 1895, and "On a New Electro-
polariscope," ' The Electrician/ December 27, 1895.

Polarisation of Electric Waves by a Twisted Structure. 147

On the other hand, with small radiators, the difficulty is in the
proper adjustment of the receiver. It then becomes necessary to
have very exact adjustments of the receiver, both as regards the
pressure to which the sensitive spirals are subjected and the E.M.F.
acting on the circuit. It is only after some practice that the
peculiarity of each receiver is properly understood, when it becomes
easy to make the necessary adjustments by which the receiver
becomes quite certain in action. For various reasons the radiations
emitted by small radiators are more favourable for work requiring
great delicacy.

In order that the surface of the radiator should be little affected
by the disintegrating action of the sparks, I use a single spark for
producing a flash of radiation. There used to be, however, some
uncertainty from a discharge occasionally failing to be oscillatory.
The cause of this uncertainty is ascribed to the deposit of dust on the
sparking surface. For greater certainty of action some observers
immerse the radiator in oil. The use of oil is under any circum-
stances troublesome. This is specially so in polarisation experiments,
when the radiator has to be placed in different azimuths. I have for
these reasons avoided the oil-immersion arrangement, and have tried
to secure certainty of oscillatory discharge without this expedient.
Attention was specially paid to the coil and the primary break.
A radiator has also been constructed which is found to be extremely
efficient. It consists of two platinum beads, each 2 mm. in diameter,
separated by 0*3 mm. spark-gap. There is no interposed third ball.
This radiator, though kept exposed for days without any protecting
cover, was yet found to give rise to a succession of effective
discharges without a single failure. I even went so far as to pour a
stream of dust on the radiator, in spite of which severe treatment,
the sparks were found to be quite effective in giving rise to electric
oscillation.

The receiver, too, is perfectly certain in its action, and various
degrees of sensitiveness may be given to it. In the following
experiments, the sensitiveness had to be very greatly enhanced, and
this, as alluded to above, was secured by proper adjustments. The
secondary disturbances were got rid of by careful screening. But
one serious difficulty was encountered at the very outset, in the
failure of the polariser to produce complete polarisation. In my first
experiments on polarisation (the receiver then used not having been
very sensitive), polarisers made of wire gratings were found effective.
But in my later experiments with still more sensitive receivers,
I found that, owing probably to the want of strict parallelism of the
wires and the difficulty of exactly crossing the analyser and polariser,
it was impossible to produce total extinction of the field. I then
made a polariser and analyser by cutting parallel slits out of two

M 2

148 Prof. J. C. Bose. On the Rotation of Plane of

square pieces of thick copper. When the square pieces were adjusted
with coincident edges, the analyser and polariser were either exactly
parallel or exactly crossed. This improvement enabled me to carry
out successfully some of the more delicate experiments. In the
present course of investigation the sensitiver.ess of the receiver had
to be raised to a still higher extent, and it was found that the
polariser hitherto found efficient failed to produce complete polarisa-
tion, so that even when the polariser and the analyser were exactly
crossed the non -polarised portion of radiation was of sufficient
intensity to produce strong action on the receiver.

In the paper " On the Selective Conductivity exhibited by some
Polarising Substances "* I described a book-form of polariser, when
an ordinary book was shown to produce polarisation of the trans-
mitted beam, the vibrations parallel to the pages being absorbed, and
those at right angles transmitted in a polarised condition. The
advantage of this form of polariser was that the extent to which the
rays were polarised depends on the thickness of the polarising
medium. The rays could thus be completely polarised by giving the
medium a sufficient thickness, this thickness being determined by the
intensity of the radiation used and the sensitiveness of the receiver.
The necessary thickness of the book-polariser may be materially
decreased by making the book consist of alternate leaves of paper and
tinfoil. The book being then strongly compressed, blocks of suitable
size are cut out to form the polariser and the analyser. Each of these
blocks is then enclosed in a brass cell, with two circular openings on
opposite sides for the passage of radiation. The size of the polariser
I use is 6 X 6 cm., with a thickness of 4'5 cm. ; the aperture is
4 cm. in diameter. These polarising cells I find to be quite efficient ;
when two such cells are crossed, the field is completely extin-
guished.

Polarisation apparatus. B, the radiating box ; P, the pclariser ; A, the
analyser ; S, S', the screens ; It, the receiver.

* * Eoy. Proc. Soc.,' vol. 60.

Polarisation of Electric Waves by a Twisted Structure. 149

The diagram explains the general arrangement of the apparatus,
mounted on an optical bench. The spark gap of the radiator is
horizontal. The polariser, with the leaves vertical, is placed on a
shelf attached to a screen of thick brass plate 35 x 35 cm. In the
centre of the plate there is a circular opening 4 cm. in diameter ;
this aperture may be varied by a series of diaphragms. There is a
second similar screen with a shelf for the analyser, which is placed
with th.e leaves horizontal. Behind the analyser is the receiver.

In the space between the brass plates is placed the substance to be
examined. Previous tests are made to see whether all disturbing
causes have been removed. The sensitiveness of the receiver is
occasionally tested by interposing one's fingers at 45° between the
crossed polariser and analyser; this should, by partially restoring
the field, produce strong action, provided the receiver is in a fairly
sensitive condition.

Care should be taken that there are no metallic masses between
the screens, as reflection from metals is found to produce " depolari-
sation," the rajs being then elliptically polarised. The substance to
be examined should not, for very delicate experiments, be held by the
hand, owing to the disturbing action of the fingers. It is preferable
to have the substances supported on stirrups made of thin paper.
The above are some of the main precautions to be taken in carrying
out the following experiments, where the effects to be detected are
very small and therefore likely to be masked unless all disturbing
causes are carefully excluded.

I have in a previous communication made mention of the double
refracting property of fibrous substances like jute. The field is
restored when a bundle of jute is placed at 45° between the crossed
polariser and analyser. There is, however, 110 depolarisation effect
when the axis of the bundle is parallel to the direction of the ray.

I now took three similar bundles, A, B, and C, of parallel fibres of
jute 10 cm. in length and 4'5 cm. in diameter. No change was made
in the bundle A, which was kept as a test one. The bundles B and
C were then twisted, B in a right-handed direction and C in a left-
handed direction.

The interposition of the untwisted bundle A between the crossed
polariser and analyser did not produce any effect, but strong
action was produced in the receiver when the bundles, twisted to the
right or to the left, were so interposed. It thus appeared as if the
twisted structures produced an optical twist of the plane of polari-
sation.

The further experiments to be described below may be of some
interest in connection with the optical rotation produced by liquids.
Here two different classes of phenomena may be distinguished : —

(1) The rotation induced by magnetic field ; this rotation among

150 Prof. J. 0. Bose. On the Rotation of Plane of

other things is dependent on the direction and intensity of the
magnetic field, and is doubled when the ray is reflected back.

(2) The rotation produced by saccharine and other solutions,
when the rotation is equal in all directions and simply proportional
to the quantity of active substance traversed by the ray ; the rota-
tion in this case is neutralised when the ray is reflected back.

The difficulties in the way of explaining the rotation produced by
liquids are summarised in the following extract.

" It is, perhaps, not surprising that crystalline substances should^
011 account of some special molecular arrangement, possess rotatory
power, and affect the propagation of light within the mass in a
manner depending on the direction of transmission. The loss of this
power when the crystalline structure is destroyed, as when quartz is
fused, is consequently an event which would be naturally expected,
but the possession of it in all directions by fluids and solutions, in
which there can not be any special internal arrangement of the mass
of the nature of a crystalline structure, is not a thing which one
would have been led to expect beforehand. To Faraday it appeared
to be a matter of no ordinary difficulty, and I am not aware that any
explanation of it has ever been suggested. It is just possible that
the light, in traversing a solution in which the molecules are free to
move, may, on account of some peculiarity of structure, cause the
molecules to take up some special arrangement, so that the fluid
becomes as it were polarised by the transmission of the light, in a
manner somewhat analogous to that in which a fluid dielectric is
polarised in a field of electrostatic force."*

In order to imitate the rotation produced by liquids like sugar
solutions, I made small elements or " molecules " of twisted jute, of
two varieties, one kind being twisted to the right (positive) and the
other twisted to the left (negative). I now interposed a number of,
say, the positive variety, end to end, between the crossed polariser
and analyser; this produced a restoration of the field. The same was
the case with the negative variety. I now mixed equal numbers of
the two varieties, and there was now no restoration of the field, the
rotation produced by one variety being counteracted by the opposite
rotation produced by the other.

To get complete neutralisation, it is necessary that the element
should be of the same size, and that the two varieties should be
twisfced (in opposite directions) to the same amount. The experi-
ment was repeated in the following order, to avoid any uncertainty
due to the possible variation of the sensitiveness of the receiver.
The receiver is adjusted to a particular sensitiveness, and as long as
it is not disturbed by the action of radiation, the sensitiveness re-
mains constant. A mixture of opposite elements is first interposed,
* Preston, ' On Light,' 2nd ed., p. 421.

Polarisation of Electric Waves by a Twisted Structure. 151

the receiver continuing to remain unaffected. From the mixture of
positive and negative varieties, one set, say the negative, is now
rapidly withdrawn, and an equal number of positive substituted.
The receiver which has not been disturbed since its first adjustment
is now found to respond, all the elements conspiring to produce
rotation in the same direction. It will be seen that the two experi-
ments are carried out under identical conditions.

In the above, we have electro-optic analogues of two varieties of
sugar — dextrose and levulose. There is also the production of an
apparently inactive variety by the mixture of two active ones.

FIG. 2. — Jute elements.

It is to be noted that there is no polarity in the elements, in the
sense we use the term in reference to, say, magnetic molecules.
There is nothing to distinguish one end of the jute element from the
other end ; indeed a right-handed element would appear right-handed
when looked at from either end. It thus happens that if the rotation is
determined by the direction of the twist, two molecules of the same
variety will always conspire, whether they are arranged as ab, cd,
or, to take the extreme case, as afc, dc (with the second molecule
reversed). The assumption of any particular arrangement of
molecules is thus not necessary in explaining the rotation. The
average effect produced by a large number of active elements inter-
spersed in an inactive medium will thus be the same in all directions,
and proportional to the number of molecules traversed by the ray.
As there is no polarity in the molecule, a right-handed element will
always produce the same kind of rotation, say, to the right of an
observer travelling with the ray. The rotation produced when the
ray is reversed by reflection will thus be in an opposite direction, and
the two rotations will neutralise each other.

But if the molecules exhibit any polarity, that is to say, if the
effects produced by the two ends of the same molecule are opposite,
the resultant effect produced by a number of such molecules arranged
in haphazard directions, will be zero. In order that the effects pro-
duced by the molecules may conspire, it is necessary that they should

15*2 Prof. J. C. Bose. On the Production of a " Dark

take up a special arrangement like the disposition of molecules in a
magnetised rod. It is seen that in this case the rotations of the
direct and the reflected rays are in the same direction, and the
resultant rotation is therefore doubled. There is some analogy
between the action of such polarised molecules and of substances
which, when placed in a magnetic Afield, rotate the plane of polar-
isation.

" On the Production of a ' Dark Cross ' in the Field of Electro-
magnetic Radiation/' By JAGADIS CHUNDER BOSE, M.A.,
D.Sc., Professor of Physical Science, Presidency College,
Calcutta. Communicated by Lord RAYLEIGH, F.R.S.
Received February 14,— Read March 10, 1898.

A circular piece of chilled glass when interposed between crossed
nicols produces a dark cross. A similar effect is produced by
crystals like salicine where there is a radial disposition of the
principal planes.

I have been able to detect a similar phenomenon in the field of
electric radiation by the interposition of an artificial structure
between the crossed polariser and analyser.

I have in a previous communication described the polarisation
produced by the leaves of a book. For the following experiment, a
long strip of paper was rolled into a disc. A roll of Morse's tape
serves the purpose very well. The diameter of the disc is 14 cm.
and its thickness 2 cm. It will be observed that here we have a
single axis passing through the centre, and that all planes passing
through the centre are principal planes.

The effect produced by the interposition of the structure may be
studied by keeping the disc fixed and exploring the different parts of
the field by means of the detector; or the detector may be kept
fixed (opposite the analyser) and the disc may be moved about so
that the different parts of the field may successively be brought to
act on the detector. This latter plan was adopted as being simpler
in practice.

The arrangement of the apparatus is the same as in fig. 1 of my
paper " On the Rotation of Plane of Polarisation of Electric Waves
by a Twisted Structure." The polariser is vertical and the analyser
horizontal. The paper disc is interposed between the screens with
its plane at right angles to the direction of the ray.

The receiver is fixed on the prolongation of the line (which I shall
call the axis), joining the centres of the polariser and the analyser.

On the supposition that the interposition of the disc produces a
•dark cross, the arms of the cross (with the particular arrangement

Cross" in the Field of Electro-magnetic Radiation. 153

of the polariser and the analyser) will lie in the projections of the
vertical and the horizontal diameters of the disc, and will move in
space with the movements of the disc. When the centre of the disc
is on the axis the intersection of the cross will be superposed on the
receiver, and there should then be no action. If the disc be moved
up and down, the centre remaining in the vertical line passing
.through the axis, the vertical arm of the cross will slide over the
receiver. If the disc be moved laterally, with its centre in the
horizontal line passing through the axis, the horizontal arm of the
cross will slide over the receiver. In this, as in the last case, there
should be no action on the receiver. But if the disc be displaced
so that the centre does not lie in either the horizontal or the vertical
line passing through the axis (the axis now cutting the disc at points
such as a, 6, c, or d), the arms of the cross will not fall on the
receiver, and there should be a response in the receiver.

The experiments were now arranged as follows : — The disc was at
first placed with its centre on the axis, the plane of the disc being

FIG. 1. — The paper disc. AB, CD are the vertical and horizontal diameters.

perpendicular to the axis. There was now no action on the receiver;
but as soon as the disc was tilted, however slightly, an action was
immediately produced on the receiver.

The disc was now mounted on a stand, between the two screens.
By means of sliding arrangements the disc could be raised or
lowered, or moved laterally.

In the next experiment, the centre of the disc was first adjusted
on the axis, and the disc moved vertically up and down. No effect
was produced when this was being done.

The centre of the axis was again adjusted on the axis, and the
disc moved laterally on the horizontal slide. In this rase, too, there
was no action.

By adjusting the vertical sliding rod the centre of the disc was
next placed vertically above or below the axis. The disc was then
moved laterally either to the right or to the left. In this way the

154 "Dark Cross" in the Field of Electromagnetic Radiation.

FIG. 2.— The holder for the disc. D, the paper disc. V, L are the vertical and

horizontal slides.

field could be displaced, and the quadrants a, Z>, c, or d (see fig. 1)
placed opposite to the receiver. In all these cases, even with small
displacements, very strong action was produced on the receiver.

From experiments carried out in the manner described above, the
outline of a dark cross projected in space was distinctly made out.

A disc of wood, with concentric rings, would probably show the
effect equally well. I shall in a future paper send an account of the
action of crystals cut perpendicular to the axis placed in convergent
or divergent beams of electric radiation.

Some of the investigations on the rotation of the plane of polar-
isation will, perhaps, be facilitated by an observation of the rotation
of the cross. By a modification of this method I am at present
trying to detect the rotation produced in a magnetic field.

Addendum, 16th March, 1898.

The production of a dark cross can also be demonstrated by in-
terposing between the crossed polariser and analyser concentric
rings of tin-foil mounted on a thin sheet of mica. But greater
interest is attached to the exhibition of the phenomenon by double
refracting substances, where the axes of elasticity are disposed in
radial directions. From the peculiar stresses present, I surmised
that woody stems with concentric rings would exhibit the phenome-
non above described. Through the kindness of Dr. Prain, I obtained
from the Government Botanical Gardens, Sibpore, stems of Pinus
longifolia, Swietenia niahogani^ Araucaria Cunninghamii, Mangifera
indica, Casuarina equisetifolia, Cupressus torulosa and Dalbergia
sissoo. The ring systems present in some of these were very regular,

Relations between Marine Animal and Vegetable Life. 155

I was, however, at first disappointed in failing to obtain the results
anticipated. But this failure, I subsequently found, was due to the
general opacity of the wood which was freshly cut, and which?
though apparently dry, contained large quantities of sap in the
interior. I then carefully dried some of the specimens, when the
stresses present became quite apparent by numerous cracks starting
in radial directions. The results obtained with these dried specimens
were quite satisfactory.

I now tried to devise some experiments strictly analogous to the
optical experiments with chilled glass. For this purpose I cast a
cylinder of paraffin wax in a metallic mould surrounded by a freezing
mixture. Owing to the great contraction produced by solidification,
a hollow depression was formed in the centre, and this produced a
distortion of symmetry. It would, therefore, be better to build up a
cylinder by successive dippings, the deposited molten layer contract-
ing on the solid core. I obtained, however, extremely good results
with a cylinder of cast ebonite, in which the stresses present are
exactly similar to those in a circular piece of unannealed glass.

The next series of experiments were undertaken with mineral
specimens. I here acknowledge with thanks, the kind help I received
from Mr. Hayden, B.A., and Mr. Blyth, of the Geological Depart-
ment, in obtaining suitable specimens for my experiments. One
very interesting specimen obtained from Egypt was formed by ringed
concretion of flint round a central nodule. This specimen exhibited
the cross with great distinctness. I also obtained fairly satisfactory
results with stalactite. The concretion of calcium carbonate formed
inside a pipe by deposits from temporarily hard water flowing through
it, would also be found to exhibit this phenomenon.

" The Relations between Marine Animal and Vegetable Life."
By H. M. VERNON, M.A., M.B. Communicated by Professor
BURDOX SAKDERSON, F.R.8. Received December 8, 1897,—
Read January 24, 1898.

(From the Zoological Station, Naples.)
(Abstract.)*

The object of this research was to determine how the nitrogenous
matter excreted by marine animals into the water is removed, and
what parts the various forms of vegetable life play in the process.
Thus this subject is of interest from its practical bearing on ques-
tions relating to the efficient maintenance of marine aquaria, as well

* The full paper will be published in the ' Mittheilungeu aus der Zoologisclien
Station zu Neapel.'

156 Mr. H. M. Vernon. The Relations betiveen

as from the theoretical standpoint of the changes taking place under
natural conditions in the open sea.

The method of investigation was a triple one, viz., chemical, physio-
logical, and bacteriological. The chemical procedure consisted in
carefully determining the free and albuminoid ammonia present in
the various specimens of water by means of the well-known method of
Wanklyn, Chapman and Smith. In certain cases also the nitrites
were determined by the metaphenylenediamine reaction. The water
was tested physiologically by allowing the fertilised ova of the sea-
urchin, Strongylocentrotus lividus, to develop in it, and by determining
the change produced in the size of the larvae after eight days'
growth under various conditions. The larvae were in each case
measured under the microscope in groups of fifty. In addition also
the proportion of ova arriving at the eight days' larval stage was
always determined. The bacterial quality of the water was tested by
counting the number of colonies obtained by gelatin plate culture.

With reference to the purifying effects of vegetable life on the water, .
it was found that green weeds such as Ulva, will, when placed in
Aquarium tank water, rapidly remove the free ammonia present,
though they slowly increase the albuminoid ammonia. Thus in one
case 62 per cent, of the free ammonia was removed after two days,
and 95 per cent, after ten days, whilst the albuminoid ammonia was
increased by respectively 22 per cent, and 27 per cent. If the water
be in addition exposed to sunlight, the free ammonia is removed less
rapidly than before, but the albuminoid ammonia increased more
rapidly. Sea-urchin larva? grown in water thus purified are, as a rule,
increased in size, this increase being in one case 14'4 per cent. Larvae
allowed to develop in direct contact with the alga were, as a rule,
found to be slightly diminished in size, although analyses of the
water made at the end of the experiments showed that the albuminoid
ammonia had been appreciably diminished, as well as the free
ammonia. It would seem, therefore, that the alga is able to absorb
the albuminoid ammonia when it is present in considerable amount.
The proportion of fertilized ova developing to the full larval stage
was considerably greater in these experiments than when no alga had
been added to the water, hence the effect of the weed would seem on
the whole to have been a favourable one.

Red weeds, such as Gelideum, when kept in Aquarium water, cause
a considerable increase in the albuminoid ammonia, and as a rule
also increase the free ammonia. Larvae grown in water thus treated
are diminished in size, but when allowed to develop in direct contact
with smaller quantities of the weed, may be increased in size. Small
quantities of red and green weeds combined cause an increased
number of the ova to reach the larval stage, and may also cause an
increase in the size of the larvae.

Marine Animal and Vegetable Life. 157

On filtration of water through sand which had been taken from
erne of the tanks in the Aquarium, it was found that 94 per cent, of the
free, and 18 per cent, of the albuminoid, ammonia had been removed.
This great purification was due to the thin layer of algse and diatoms
with which the grains of sand were covered, for on heating some-of
this sand to 70° C., and subsequently washing it to remove the vege-
table debris, the ammonia in the water filtered through it was con-
siderably increased in amount. Also on filtering water continuously
for some weeks through a layer of sand 16 cm. deep, which contained
small quantities of vegetable matter, a half the free and an eighth
of the albuminoid ammonia were at first removed. After a week,
however, 58 per cent, of the free and 21 per cent, of the albuminoid
ammonia were absorbed, and after a fortnight respectively 96 per cent,
and 51 per cent. This marked increase of purification was due to the
deposition in the sand of the small quantities of algaa and diatoms in
suspension in the water, and to their subsequent multiplication.

This vegetable filter was found to act most efficiently with the
water flowing through at its maximum rate. This, in the present
experiment, was at 1 litre in three minutes through a superficial
area of sand of 177 sq. cm. When, by clamping the exit tube, the
rat-e of flow was diminished to a litre in fifty minutes or more, there
was no longer any purification, but the amount of free ammonia in
the water was increased some threefold, whilst the albuminoid
ammonia remained practically unaltered. Also, on discontinuing
the current of water through the filter for twenty-four hours and
then renewing it, its purifying efficiency was greatly diminished in
respect of the albuminoid ammonia, only 9 per cent, of this being
now absorbed. In the course of a few days, however, the purifying
power began to increase again. The filter was then covered up so
as to totally exclude the light, and thereby kill off the chlorophyll-
containing organisms. About 90 per cent, of the free ammonia was
still absorbed, but never more than 20 per cent, of the albuminoid
ammonia, even after twenty-five days more of continuous filtration.
This purification must have been due to bacterial agency. Such a
" bacterial " sand filter reacts to changes in the rate of flow of the
water quite differently to the chlorophyll-containing one. Thus the
purification remained practically as great on diminishing the rate of
flow to 1 litre in two hours fifty minutes, and the water flowing
through immediately after the current had been entirely stopped for
ten hours had 93 per cent, of its free ammonia removed.

In another experiment, sand which at first contained no vegetable
matter at all was found to have practically no purifying power.
On allowing a current of water to flow through it continuously,
however, this gradually developed and increased in amount as in
the above experiment.

158 Mr. H. M. Vernon. The Relations between

Larvae grown in water purified by this filtration through sand are
increased in size some 4'2 per cent., whilst as a rule the percentage
of ova reaching the full larval stage is considerably increased.

On keeping sea water in diffuse light the free ammonia soon begins
to 'disappear, owing to the multiplication of the small quantities of
algae and diatoms in suspension in the water. Thus, in one instance,
after ten days 40 per cent, of the free ammonia had disappeared, and
after twenty-five days 92 per cent. ; the albuminoid ammonia had,
on the other hand, increased by respectively 28 and 101 per cent.
Larvae grown in water thus purified were on an average increased in
size by 13*4 per cent.

On keeping water in direct sunlight for some days, the free
ammonia is somewhat diminished, and the albuminoid ammonia
considerably increased, probably owing to the formation of vegetable
growth. Larvae grown in water which had been exposed four or
more days to the sun and air in a covered glass jar were on an
average unaffected in size, though only 11 per cent, of the fertilized
ova employed reached the larval stage. On the other hand, with
water exposed four or five days to the sun in a flask, whereby very
little surface was open to the air, nearly the normal number (i.e.,
66'6 per cent.) of ova developed to larvae, and these larvae were no
less than 16*7 per cent, larger than the normal. Bacteriological
examination failed to establish any constant differences in the number
of germs in these two different kinds of water, but they confirmed
the germicidal action of sunlight on the water. It was found,
however, that water in which most of the germs had been killed
by several days' exposure to sunlight, contained very many more
germs than were originally present, if it were subsequently
kept in diffuse light. Thus in the subjoined experiment, the
water was exposed ten and a half days to direct sunlight, the
number of colonies developing after forty-eight hours' incubation
being reduced to 70 per c.c. After two days' exposure to diffuse
light, however, the number had enormously increased. It will be
noticed that the number also increased between the first and fourth
days of exposure. This was owing to the fact that there was very
little direct sunlight at the time.

A -•"'•' ! i / 3»5(>0

Original water j ^

After 1 hour 2,260

„ 3 hours 1,360

„ 6± „ 1,450

„ 3| days 5,500

„ 7* „ 150

„ 10J „ 70

„ 12| „ 320,000

Marine Animal and Vegetable Life. 159

On keeping Aquarium water in darkness for three or more weeks,
it undergoes great purification. Thus in one case after twenty-five
days there remained only 2 per cent, of the free and 48 per cent, of
the albuminoid ammonia originally present. There was no further
purification on keeping an additional twenty-nine days. This purifi-
cation is due to bacterial action, as it is greatly delayed if the water
be previously heated to 100°, and is stopped by adding corrosive
sublimate to the water. The amounts of free and albuminoid
ammonia present after this purification are in some cases no greater
than those found in pure open sea water. The physiological purity is
not so great, however, as larvae grown in open sea water are increased
in size by 16'0 per cent., and those grown in water kept in darkness
by, on an average, 7'5 per cent. Also with this latter water the
percentage of ova reaching the full larval stage is slightly smaller
than the normal. Water kept in darkness contains considerably
fewer germs than normal water, and the longer the water is kept the
smaller is the number.

A very considerable purification of the Aquarium water is effected by
the layer of bacterial slirne coating the inside of the pipes which con-
duct the water from the reservoirs to the rooms. Thus water drawn
off at the rate of a litre in ten seconds contained 26 per cent, less
free, and 25 per cent, less albunlinoid, ammonia than the reservoir
water, and that drawn off at a litre in two hours and forty minutes
respectively 82 per cent, and 16 per cent. less. Larva3 grown in such
water were, moreover, some 7'8 per cent, larger than the normal.

On filtering water through asbestos, the albuminoid ammonia is
somewhat increased, but larvae grown in the filtered water are some
12*6 per cent, larger than the normal.

Larvae grown in water previously heated to 50°, 76°, or 100° are
increased in size by some 6'2 per cent., and the proportion of ova
reaching the larval stage is also increased. This is probably due to
the removal of bacteria and other forms of life from the water,
though after the first day or two the water contains more bacteria
than unheated water.

Ordinary tank water gave about 1500 colonies per c.c. after
twenty-four hours' incubation at 25°, and about 3000 after forty-
eight hours. Filtration through sand at first diminished the number
of germs, but when this became impregnated with vegetable growth
they were largely increased. Through sand kept in darkness, very
slow filtration increases the number of germs, but a fairly fast one
diminishes them. The addition of algae to the water increases the
number of germs.

Larvae grown in water previously fouled by fish, crabs, molluscs,

and Holothurians are increased in size on an average by 4'1 per cent.,

• but with water fouled by sea-anemones and medusae are slightly

160 Relations between Marine Animal and Vegetable Life.

diminished in size. The increase in size appears to depend roughly
on the amount of contamination of the water. Fish and crabs appear
to effecb about ten times as much contamination as molluscs and
Holothurians.

On the other hand, if the water be previously fouled by the sea-
urchins StronglyocentrotuS) Sphcerechinus, and Echinus, a decrease
amounting on an average to 6'9 per cent, is effected ; but with
Arbacia and Dorocidaris there is on an average an increase of 3 per
cent. There is indeed considerable evidence to show that an organism
exerts a special adverse influence on the members of its own species.
The fouling products do not seem to be of the nature of ptomaines,
as larvae grown in water fouled by dead sea-urchins were in some
cases increased in size, though on an average they were slightly
diminished. These dead sea-urchins were found to effect about ten
times as much contamination of the water as did the various living
animals examined. In connection with these results, reference may
be made to some previous experiments,* in which it was found that
the addition of small quantities of uric acid and urea to the water
caused an increase in the size of the larvae, this increase amounting
in one instance to 12*2 per cent. Also it was found that the addition
of considerable quantities of C02 to the water excited a positive
rather than a negative effect on the* size of the larvae.

Larvee grown in water in which another batch of larvaa had already
developed were on an average diminished by 6*9 per cent.

The evidence as to whether a plutens reacts more to its own pro-
ducts of metabolism than to those of other species of plutei was too
variable to afford a definite conclusion either way. With water fouled
by plutei, the proportion of fertilised ova reaching the full larval stage
is as a rule considerably less than the normal ; with that fouled by
living Echinoids it is slightly less ; with that fouled by various other
animals about the same, and with that fouled by dead Echinoids
it is greater than the normal.

Ammonium chloride exerts a very fatal action on larval growth.
Thus with water containing 1 part in 25,400 of the salt, the larvae
were diminished 19'0 per cent, in size, and only 28 per cent, of the
ova reached the larval stage. Potassium nitrite, if kept below about
0*3 gram per litre, and potassium nitrate, if kept below 1 gram, have
practically no action.

Larvee grown in sea water which had been aerated by prolonged
agitation were on an average increased by 0*65 per cent. The bac-
terial quality of the water seemed practically unaffected by the
aeration.

After keeping water several weeks in darkness the nitrites origin-
ally present are much diminished, or disappear altogether. After
* 'Phil. Trans.,' B (1895), p. 595.

Report of the Kew Observatory Committee. 161

filtration through, sand impregnated with vegetable growth, and after
adding algae to the water, the nitrites are increased. The growth of
larvae in a water is as a rule accompanied by an increase of nitrites,
though the nitrification does not seem to be increased on the addition
of either ammonium salts or nitrates to the water, or on fouling the
water by animal excretions.

The arm-lengths of the larvae are not specially affected by vege-
table growth, though by water filtered through sand impregnated
with algae and diatoms they are somewhat diminished. They are
considerably increased on development of the larvae in water purified
by being kept in darkness, and in aerated water. They are greatly
diminished in water previously heated to 100°, but not in that heated
to from 50° to 77°. In water exposed to sunlight they are also
diminished. They are increased in water fouled by most animals
and by dead Echinoids, but in that fouled by living Echinoids are
diminished.

During a period of seven months the specific gravity of the
Aquarium water was found to vary from 1-02859 to T02964 at
15*56° C. The specific gravity was on an average about 0'00040
greater than that of the open sea water. The free ammonia varied
from 0*185 to 0*350 milligram per litre, and the albuminoid from
0-111 to 0-182 milligram,

Report of the Kew Observatory Committee for the Year
ending December 31, 1897.

The operations of The Kew Observatory, in the Old Deer Park,
Richmond, Surrey, are controlled by the Kew Observatory Committee,
which is constituted as follows : —

Mr. F. Galton, Chairman.

Captain W. de W. Abney, C.B.,

E.B.

Prof. W. G. Adams.
Captain E. W. Creak, R.N.
Prof. G. C. Foster.
Prof. J. Perry.
The Earl of Rosse, K.P.

VOL. LXI1T.

Prof. A. W. Riicker.

Mr. R. H. Scott.

Mr. W. N. Shaw.

Lieut. -General Sir R. Stracher,

G.C.S.I.
Rear Admiral Sir W, J. L.

Wharton, K.C.B.

162 Report of the Kew Observatory Committee.

The work at the Observatory may be considered under the fol-
lowing heads: —

1st. Magnetic observations.
2nd. Meteorological observations.
3rd. Solar observations.

4th. Experiments and Researches in connexion with any of the
departments.

«5th. Verification of instruments.

6th. Hating of Watches and Marine Chronometers.

7th. Miscellaneous.

I. MAGNETIC OBSERVATIONS.

The Magnetographs have been in constant operation throughout
the year, and the usual determinations of the Scale Values were made
in January.

The ordinates of the various photographic curves representing
Declination, Horizontal Force, and Vertical Force were then found
to be as follows : —

Declinometer : 1 inch = 0° 22''04. 1 cm. = 0° 8'7.

Bifilar, January 20, 1897, for 1 inch £H = O0280 foot grain unit.

„ 1 cm. „ = 0-00051 C.G.S. unit.
Balance, January 21, 1897, for 1 inch oV= 0'0274 foot grain unit.

„ 1 cm. „ = 0-00050 C.G.S. unit.

During the past year the magnetic curves have been free from any
very large fluctuations. The principal variations that were recorded
took place on the following days : —

January 2; February 4, 25—27; March 9—10; April 2, 20,
23—24 ; May 17 ; June 16—17 ; July 31 ; October 1—2, 28 ; Novem-
ber 17; December 11, 20—21.

The hourly means and diurnal inequalities of the magnetic elements
for 1897, for the quiet days selected by the Astronomer Royal, will
be found in Appendix I.

In the present year a correction has been applied for the diurnal
variation of temperature, use being made of the records from a
Richard thermograph as well as the eye observations of a thermo-
meter placed under the Vertical Force shade.

The mean values at the noons preceding and succeeding the selected
quiet days are also given, but these of course are not employed in
calculating the daily means or inequalities.

The following are the mean results for the entire year : —

Mean Westerly Declination 17° 6''4.

Mean Horizontal Force 0'18342 C.G.S. unit.

Mean Inclination 67° 19''6.

Mean Vertical Force . . 0'43906 C.G.S. unit.

Report of the Kew Observatory Committee. 163

Observations of Absolute Declination, Horizontal Intensity, and
Inclination have been made weekly, as a rule.

As in 1896, a table of recent values of the Magnetic Elements at
the Observatories whose publications are received at Kew was con-
tributed to ' Science Progress,' and appeared in the August number.
A similar table, but containing more recent data, will be found in
Appendix IA to the present Report.

In July, M. Moureaux, of the Pare Saint-Maur Observatory, near
Paris, paid a visit, and a comparison was made of his and the Kew
magnetic instruments, a detailed report of which has been drawn up
by the Superintendent, and published in the Royal Society's Pro-
ceedings, vol. 62, p. 156.

The magnetic instruments lent to the Jackson-Harmsworth Polar
Expedition have been returned, and in October some observations
were taken with them by Mr. Albert Armitage, the Magnetic
Observer in the expedition, and the Observatory Staff, with a view
to standardizing the Arctic Observations.

Dr. van Rijckevorsel spent some time at the Observatory, in
March and April, comparing his magnetic instruments with the Kew
unifilar and dip circle.

Information on matters relating to various magnetic data have
been supplied to Dr. E. Atkinson, Professor Arnold Lupton, and
Captain Schiick, and the latter gentleman compared his instruments
with the Observatory standards.

II. METEOROLOGICAL OBSERVATIONS.

The several self-recording instruments for the continuous registra-
tion of Atmospheric Pressure, Temperature of Air and Wet-bulb,
Wind (direction and velocity), Bright Sunshine, and Rain, have been
maintained in regular operation throughout the year, and the
standard eye observations for the control of the automatic records
duly registered.

The tabulations of the meteorological traces have been regularly
made, and these, as well as copies of the eye observations, with .
notes of weather, cloud, and sunshine, have been transmitted, as usual,
to the Meteorological Office.

With the sanction of the Meteorological Council, data have been
supplied to the Council of the Royal Meteorological Society, the
Institute of Mining Engineers, and the editor of ' Symons' Monthly
Meteorological Magazine.'

On June 21, observations with the Campbell sunshine recorder, of
the original wooden bowl pattern, were suspended, by direction of the
Meteorological Council.

Hjlectrograph. — The auxiliary battery of 60 chloride of silver cells

1 64 Report of the Kew Observatory Committee.

used witli this instrument was received back from the makers on
January 11.

Before restarting the instrument, the Clifton Quadrant Electro-
meter was taken entirely to pieces, all parts thoroughly cleaned and
dried, and new sulphuric acid put in the inner jar.

The battery was tested, each row of cells being examined and the
voltage determined.

The electrograph was started on January 19, and has been in con-
stant operation since, with the exception of one or two short stoppages
due to freezing of the water jet, or other accidental causes. Owing
presumably to the changes introduced last year, there has been a
great improvement in the behaviour of the apparatus. There are
still, however, one or two directions in which further improvement is
desirable.

On September 29, one-third of the cells in the battery were taken
off, to make a corresponding contraction in the scale values, which
was expedient in view of the high potentials usually recorded during
the winter months.

Notwithstanding this, several hours' record have been lost owing
to the trace being off the sheet. It is difficult at present td see how
such loss can be avoided, without either duplicating part at least of
the apparatus, so as to get two curves, one showing ordinary and the
other extraordinary potentials (positive and negative), or else by
risking possible loss of negative trace by shifting the position, on
the sheet, of the zero line.

The scale value was determined, by direct comparison with the
Portable Electrometer, White, No. 53, on January 19, May 4, and on
September 29, before and after the change above referred to.

The comparisons showed that up to the date of the change the
scale value had remained practically constant.

Inspections. — In compliance with the request of the Meteorological
Council, the following Observatories and Anemograph Stations have
been visited and inspected : — Fleetwood, Stonyhurst, Armagh,
Dublin, Valencia, Falmouth, and St. Mary's (Scilly Isles), by
Mr. Baker; Radcliffe Observatory (Oxford), Yarmouth, North
Shields, Alnwick Castle, Fort William, Glasgow, Aberdeen, and
Deerness (Orkney), by Mr. Constable.

III. SOLAR OBSERVATIONS.

Sun-spots. — Sketches of Sun-spots have been made on 165 days, and
the groups numbered, after Schwabe's method.

Particulars will be found in Appendix II, Table IV.

Taking into consideration the elaborate photographic work now
done elsewhere, the Committee consulted the Solar Physics Com-

Report of the Kew Observatory Committee. 165

mittee and other eminent astronomers on the subject, with the result
that they decided that the eye observations should cease at the end of
1897.

IV. EXPERIMENTAL WORK.

Fog and Mist. — The observations of a series of distant objects,
referred to in previous Reports, have been continued. A note is taken
of the most distant of the selected objects which is visible at each
observation hour.

Atmospheric Electricity. — The comparisons of the potential, at the
point where the jet from the water-dropper breaks up, and at a fixed
station on the observatory lawn, mentioned in last year's Report,
have been continued, and the observations have been taken nearly
every month.

A comparison of these observations with the corresponding results
from the electrograms encourages the belief that there has been no
progressive change of insulation in the electrograph, such as was met
with prior to the late alterations and improvements.

Advantage was taken of the occurrence of some very thick fogs in
November, to carry out six sets of observations of the potential at
various heights from the ground to 70 feet above.

Aneroid Barometers. — The experiments referred to last year have
been continued, and a considerable number of interesting conclusions
have been arrived at. It is hoped that the results will be ready for
publication in the course of the present year.

Platinum TTiermometry . — In accordance with the arrangement
alluded to in last year's Report, Dr. J. A. Harker came to the
Observatory in January to do some work in platinum thermometry.
The authorities of the International Bureau of Weights and Measures
at Sevres having consented with the greatest readiness and courtesy
to a comparison by Dr. Harker, in their laboratories, of the scales of
the hydrogen and platinum thermometers, the Committee decided
to do all in their power to make the scheme successful. It had been
from the first the hope of the Committee that platinum thermometry
would prove a valuable auxiliary in direct comparison of mercury
thermometers, especially at temperatures outside the range 0° to
100° C., and the opportunity of a comparison with the standard gas
thermometer of the Bureau International thus occurred very oppor-
tunely.

After Dr. Harker's arrival at Kew it was found that somewhat
extensive alterations would be required to fit the existing resistance
box for the work at Sevres, and it also appeared undesirable that
the Observatory should be deprived for some months of the means of
using platinum thermometers. A new resistance box was accordingly
ordered from Messrs. Crompton & Co., embodying the alterations

166 Report of the Kew Observatory Committee.

suggested by the experience of Dr. Harker and the Observatory staff.
On its completion, this box was taken to Sevres by Dr. Harker in
July, together with two or three of the platinum thermometers pre-
viously in use at the Observatory, and some new ones of higher
resistance. Since then Dr. Harker has been engaged on the proposed
research in co-operation with Dr. Chappuis of the International
Bureau. It is expected that the investigation, so far as practicable
at present, will be concluded in a few months.

The inconsistencies in the behaviour of the Callendar-Griffiths
resistance box, referred to last year, having been proved to arise prin-
cipally from the uncertainties of the plugs, it was sent to the makers
(the Cambridge Scientific Instrument Company) for readjustment.
They made use of the opportunity to introduce, at their own expense,
a new system of plugs. In it the plugs are isolated, so that manipu-
lating one leaves the tightness of the others unaffected. Another
source of trouble proved to be thermo-electric currents generated
in the patent thermo-electric key; the key accordingly has been
enclosed, at the suggestion of Mr. W. N". Shaw, in a box, and the
defect though still existent appears much reduced .

Experiments have been continued on the fixity of zero of platinum
thermometers and the degree of consistency in the results obtained
with them. Further attention has also been given to the comparison
of platinum and mercury thermometers at high temperatures. This
is a subject of increasing urgency in view of repeated requests for
direct high temperature verifications which cannot as yet be satis-
factorily dealt with.

Mercury Thermometry. — To assist in perfecting a method of high
temperature verifications, some high range thermometers of the Jena
glasses 16m and 59m have been ordered from Berlin. They are to
be verified at the Reichsanstalt before delivery.

At the request of Messrs. Powell & Sons, Whitefriars, experiments
are being made as to the therniometric properties of different kinds
of glass. Particulars of the chemical composition of the glass
will be published, with the results obtained, when the experiments are
completed.

An apparatus for the comparison of meteorological maximum and
minimum thermometers in the horizontal position has been designed
by Mr. Casella, and is at present under construction.

Y. VERIFICATION OF INSTRUMENTS.

The subjoined is a list of the instruments examined in the year
1897, with the corresponding results for 1896 : —

Report of the Kew Observatory Committee. 167

Number tested in the year
ending December 31.

1896. ~~1897?

Air-meters 5 5

Anemometers » 12

Aneroids •...„„.„ 113 77

Artificial horizons. . . . s 21 17

Barometers, Marine 84 167

Standard 72 101

„ Station 40 30

Binoculars 455 661

Compasses 51

Deflectors 4

Hydrometers 374 292

Inclinometers 8 5

Photographic Lenses 14 10

Magnets 4 2

Navy Telescopes 546 707

Rain Gauges 17 27

Rain Measuring Glasses 26 31

Scales 1

Sextants 591 694

Sunshine Recorders 2 10

Theodolites 5 29

Thermometers, Avitreous, or Immiscli's 7 5

Clinical 13,772 17,270

„ Deep sea 74 119

High Range 52 37

,, Hypsometric 34 30

„ Low Range 62 71

Meteorological 4,098 2,874

„ Solar radiation 2

Standard 69 117

Unifilars 3 4

Vertical Force Instruments 4

Declinometers . — 3

Total. 20,566 23,457

Duplicate copies of corrections have been supplied in 85 cases.
The number of instruments rejected in 1896 and 1897 on account
of excessive error or for other reasons was as follows : —

1 68 Iteport of the Kew Observatory Committee.

1896. 1897.

Thermometers, clinical 161 1 56

,, ordinary meteorological 56 38

Sextants 79 98

Telescopes 30 66

Binoculars — 28

Various 43 56

Two Standard Thermometers have been constructed during the
year.

There were at the end of the year in the Observatory undergoing
verification 12 Barometers, 680 Thermometers, 24 Sextants, 12
Telescopes, 10 Binoculars, 20 Hydrometers, and 3 Sunshine Re-
corders.

VI. RATING OF WATCHES AND CHRONOMETERS.

The high standard of excellence to which attention was drawn in
last year's Report has been maintained. Although the number of
marks obtained by the watch standing first on the list is slightly
lower than last year, yet the general average is as good, and no less
than 108 movements have obtained the highest possible form of
certificate (the class A especially good), which involves the attain-
ment of 80 per cent, of the total marks.

The 680 watches received were entered for trial as below : —

For class A, 492 ; class B, 144 ; class C, 16 ; and 28 for the subsi-
diary trial. Of these 17 passed the subsidiary test, 161 failed from
various causes to gain any certificate ; 7 were awarded class C
certificates, 109 class B, and 386 class A.

In Appendix III will be found a table giving the results of trial
of the first 51 watches which gained the highest number of marks
during the year. The highest place was taken by Messrs. Usher and
CoJe, of London, with a keyless going-barrel, Karrusel lever- watch,
No. 29,106, which obtained 88'4 marks out of a maximum of 100.

The class C trial having been of late years but little called for.
the Committee decided early in the year to suspend the further issue
of class C certificates, and this rule came into operation on April 1.

The number of watches obtaining the class A certificate "espe-
cially good " having during the past few years largely increased, con-
siderations of space forbid the publication of the rates and marks, of
all of them. Attention was drawn to this proposed change in the
Report for 1896.

Appendix III embraces watches gaining 82'5 marks and upwards-,
the remaining 57, which obtained the distinction "especially good,"
ranging from 82'3 to 80'0 marks.

Various representations having been made that changes are

Report of the Kew Observatory Committee. 161)

desirable in the system of marks and in the dating of certificates,
a circular has been issued to ascertain the general opinion of watch
manufacturers and others interested in the matter.

Marine Chronometers. — During the year, 65 chronometers have been
entered for the Kew A and B trials ; of these 49 gained certificates,
and 16 failed to pass.

The present box for the "cold" test of chronometers proving
inadequate, it is intended during the winter of 1897-98 to fit up a
larger and much improved chamber to hold a considerable number
of movements. This, it is expected, will remove much of the diffi-
culty and expense of maintaining the low temperature of 45° during
the summer months.

The relay of the chronograph working in circuit with the standard
mean-time clock " French " having proved rather uncertain in its
action daring the latter part of May, it was decided to have the
entire apparatus overhauled. This was carried out in June by
Messrs. E. Dent & Co., and an improved relay and new armatures
were fitted. It has since performed well. During the interval the
time signals were recorded on a galvanometer (P.O. pattern).

VII. MISCELLANEOUS.

Paper. — Prepared photographic paper has been supplied to the
Observatories at Hong Kong, Mauritius, St. Petersburg, Toronto,
Oxford (Kadcliffe), and Stonyhurst, and through the Meteorological
Office to Aberdeen, Batavia, Fort William, and Valencia.

Anemograph and Sunshine Sheets have also been sent to Hong Kong
and Mauritius, and papier Saxe to Coimbra, and a number of Campbell-
Stokes sunshine recorders to St. Petersburg. At the request of the
India Office, a drum chronograph with best frictional governors, to
be used for astronomical and transit work, was made by Messrs.
Thomas Cook and Sons, of York, and, after erection and examination
at Kew, was forwarded to the Colaba Observatory, Bombay.

Exhibition at the Crystal Palace. — Specimens of the curves from
the various self-recording apparatus and cloud photographs were
lent for exhibition at the Crystal Palace and safely returned.

Ships' Compasses. — With the kind assistance of Captain E. W.
Creak, R.N., F.R.S., regulations have been laid down for the separate
verification of old or additional cards for compass bowls previously
tested.

Travellers1 Azimuth Compasses. — After the conclusion of the special
experiments mentioned last year, a report was submitted to tho
Royal Geographical Society.

Painting of the Building. — The whole exterior of the building was
painted in April and May by H.M. Office of Works.

Seismograph. — An application for a grant of £60 for the purchase

170 Report of the Kew Observatory Committee.

and erection of a seismograph was favourably entertained by the
Government Grant Committee. The instrument has been ordered
from Mr. R. Munro, but has not yet been delivered.

National Physical Laboratory Committee. — A committee having
been appointed by Government " to consider and report upon the
desirability of establishing a National Physical Laboratory for the
testing and verification of instruments for physical investigation,
for the construction and preservation of standards of measurement,
and for the systematic determination of physical constant and
numerical data useful for scientific and industrial purposes ; and to
report whether the work of snch an institution, if established, could
be associated with any testing or standardising work already per-
formed wholly or partly at the public cost," the Chairman and the
Superintendent gave evidence before it.

It is also proposed that the National Physical Laboratory Com-
mitttee should visit Kew Observatory at an early date.

Library. — During the year the library has received publications
from

21 Scientific Societies and Institutions of Great Britain and

Ireland,
102 Foreign and Colonial Scientific Establishments, as well as

from several private individuals.
The card catalogue has been proceeded with.

Audit, 8fc. — The accounts for 1897 have been audited by Mr. W. B.
Keen, Chartered Accountant, on behalf of the Royal Society, and
by Professor Perry on behalf of the Committee.

The balance sheet, with a comparison of the expenditure for the
two years, 1896 and 1897, is appended.

PERSONAL ESTABLISHMENT.

The staff employed is as follows : —

C. Chree, Sc.D., F.R.S., Superintendent.

T. W. Baker, Chief Assistant.

E. G. Constable, Observations and Rating.

W. Hugo, Verification Department.

J. Foster „ „

T. Gunter

W. J. Boxall „

G. E. Bailey, Accounts and Library.

E. Boxall, Observa.tions and Rating, and seven other Assistants.

A Caretaker and Housekeeper are also employed.

(Signed) W. GRYLLS ADAMS,

pro Chairman.
March 29, 1898.

Report of the Kew Observatory Committee. 171

Comparison of Expenditure during the Years 1896 and 1897.

Expenditure.

1896.

1897.

Increase.

Decrease.

Administration : —
Superintendent

£ s. d.
500 0 0

£ s. d.
500 0 0

£ s. d.

£ s. d.

First Assistant • . .

273 18 0

331 18 0

58 0 0

Office

105 12 1

119 6 1

13 14 0

Kent, Fuel, Lighting, &c.

88 13 3
68 18 0

88 9 2
70 4 6

166

041

Incidental Expenses ....

149 18 2

113 2 3

36 15 11

1186 19 6

1223 0 0

73 0 6

37 0 0

Normal Observatory: —
Salaries — Observations,
&c

301 17 8

320 2 10

18 5 2

Incidental Expenses ....
Prop. Adm. Expenditure
Researches : —
Salaries ........... .

77 1 4
237 0 0

48 1 4
244 12 0

110 0 0

7 12 0
110 0 0

29 0 0

Purchase of Apparatus,

153 6 1

209 11 1

56 5 0

Prop. Adm. Expenditure

Tests :—

355 10 0

812 3 6

366 18 0
898 11 6

11 8 0
86 8 0

Incidental Expenses ....
Prop. Adm. Expenditure
Commissions : —
Purchases for Colonial
Institutions, &c
Prop. Adm. Expenditure
Purchase of Stock

189 14 11

475 19 6

185 6 3
118 10 0
471 1 0

203 0 6
489 4 0

398 18 2
122 6 0

13 5 7

13 4 6

213 11 11
3 16 0

471 1 0

Gross Expenditure. . . .
(showing an increase of
£33 15*. 2d.).

3377 10 3

3411 5 5

533 16 2

500 1 0

Extraordinary Expenditure.
Researches : —

110 0 0

110 0 0

Purchase of Apparatus,
&c

150 4 2

206 0 7

55 16 5

Commissions : —
Purchases for Colonial
Institutions &c ......

185 6 3

398 18 2

213 11 11

471 1 0

471 1 0

806 11 5

714 18 9

379 8 4

471 1 0

Leaving for Ordinary Nett

2570 18 10

2696 6 8

154 7 10

29 0 0

(showing an increase of
£125 7*. Wd.).

172

Report of the Kew Observatory Committee.

^ C-l 00 -<t CO Jo
^ ^CO Ciri

t 1

£
500
451
88
183

ndent
stant,Li
Jl, &c
:, Repairs, &c

;sss

« I §

ilslffi

||

I

Report of the Kew Observatory Committee.

173

cs •* co •-* o oo

2 : i

tH rt I -^

"!»

1

174

Report of the Kew Observatory Committee.

List of Instruments, Apparatus, &c., the Property of the Kew
Observatory Committee, at the present date out of the custody of
the Superintendent, on Loan.

To whom lent.

Articles.

Date
of loan.

G-. J. Symons, F.R.S.

The Science and Art
Department, South
Kensington.

Professor W. G-rylls
Adams, F.R.S.

Lord Rayleigh, F.B.S,

Radcliffe Observa-
tory, Oxford,

Portable Transit Instrument ,

Articles specified in the list in the Annual
Report for 1893

Unifilar Magnetometer, by Jones, No. 101,

complete

Pair 9-inch Dip-Needles with Bar Magnets . . .

Standard Barometer (Adie, No. 655)
Black Bulb Thermometer in vacua . .

1869
1876

1883
1887

1885
1897

Report of the Kew Observatory Committee. 175

APPENDIX I.

MAGNETICAL OBSERVATIONS, 1897.

Made at the Kew Observatory, Old Deer Park, Rich-
mond, Lat. 51° 28' 6" N. and Long. Oh lm 15s'l W.

The results given in the following tables are deduced from tho
magnetograph carves which have been standardised by observations
of deflection and vibration. These were made with the Collimator
Magnet K.C. I. and the Declinometer Magnet marked K.O. 90 in tho
9-inch Unifilar Magnetometer by Jones.

The Inclination was observed with the Inclinometer by Barrow,
No. 33, and needles 1 and 2, which are 3J inches in length.

The Declination and Force values given in Tables I to VIII are
prepared in accordance with the suggestions made in the fifth report
of the Committee of the British Association on comparing and
reducing Magnetic Observations.

The following is a list of the days during the year 1897 which
were selected by the Astronomer Royal, as suitable for the deter-
mination of the magnetic diurnal inequalities, and which have been
employed in the preparation of the magnetic tables : —

January 6, 9, 22, 23, 26.

February 2, 9, 17, 18, 20.

March 14, 15, 16, 18, 20.

April ...... 3, 11, 12, 15, 22.

May 8, 9, 12, 16, 28.

June 8, ,9, 10, 12, 30.

July 1, 9, 13, 18, 26.

August 4, 5, 6, 24, 31.

September 13, 18, 19, 26, 28.

October 5, 9, 13, 20, 21.

November 7, 8, 12, 23, 30.

December 8. 13 26, 27, 28.

176

Report of the Kew Observatory Committee.

Table I. — Hourly Means of the Declination, as determined from the

Hours

^Preceding
noon.

Mid.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

(17° +) West Winter.

1897-

'

Months.

Jan. ..

11 -4

7-9

8-0

8-2

8'4

8-3

8-2

8'2

8-0

7'8

7-8

8'9

10-2 ll

Feb. ..

11 -6

8-3

8-6

8-6

9-0

8-9

8-8

8-4

8-0

8-0

7-8

7-8

10-1 1

March .

11-6

6-8

6-9

7'2

7-1

7-0

6-8

6-9

6-1

4-7

4-7

6'2

8-7.I

Oct. ..

8-9

3-9

3-8

3-9

4-2

3-9

3-7

3-3

2-5

1-9

2-1

3-6

6-6 1

Nov. ..

7'2

3-0

3-2

3-7

3-9

4-3

3-8

3-7

3-7

3-6

3-6

4-5

5-9 1

Dec. ..

4*7

2-4

2-8

3-3

3-3

3-3

3'4

3-2

3-1

3-1

2-9

3-3

3-8 1

Means

9-2

5-4

5-6

5-8

6-0

6-0

5-8

5-6

5-2

4-9

4-8

5-7

7'6

Summer.

April . .

13-3

7'6

7'4

7-5

7-2

6-9

7-0

6-1

4-8

3-6

3-8

5-4

8-1 1

May ..

32-3

7-6

7-4

7-1

6-8

6-4

5-5

4'5

3-5

3-0

4-2

6-3

9 -5 ,

June . .

10-4

5-9

5-9

5-5

5-2

4-7

3-1

2-3

2-3

2-4

3-4

6-0

8-0

July..

9-8

5-1

4-8

4-7

4-2

3-5

2-3

1-3

1-8

2-2

2-8

4-9

7-7 ;

Aug. . .

9-8

4-2

4-3

4-3

4-1

3-8

3-0

2-2

1-6

2-0

2-9

5-1

7-7 1

Sept. . .

9'5

3-4

3'2

3-3

3-2

2-7

3'6

3-2

2-7

2-2

3-1

4-5

6-5

Means

10-8

5-6

5'5

5-4

5-1

4-7

4-1

3-3

2-8

2-6

3-4

5'4

7-9

Table II. — Diurnal Inequality of the

Hours

Mid.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

Summer Means.

-0-7

-0-8

-0-9

-1-2

-1-7

-2-3

-3-1

-a'.

-3-8

-3-0

-1-0

4-1-6

Winter Means.

-i-o

-0-8

-0-6

-0-4

-0-4

-0-6

-0-8

-1-2

-1-5

-1-6

-0-7

+ 1-2

Annual Means.

t
-0-9

-0-8

-0-8

-0-8

-1-1

-1-4

-1-9

-2-4

-2-7

-2-3

-0-8

+ 1-4

NOTE. — When the sign is + the magnet

Report of the Kew Observatory Committee. 177

selected quiet Days in 1897. (The Mean for the Year = 17° 6' '4 West.)

Noon.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

Mid.

Succeeding

noon.

Winter.

ll'l

11-5

10-2

9-4

9-5

9-5

9-0

8-5

8'1

7-9

7-6

7-9

8-0

11*8

11-4

12-0

11-9

11-3

10-2

10-0

9-6

9-5

9-0

8-5

8-2

8-0

8-1

12-2

1 12-0

13-6

13 9

12-5

10-7

8-9

8-3

77

78

7-9

76

7-1

7-0

12-0

7-9

8-1

7-7

6-5

5-2

4-9

4-8

4'2

4-1

3-8

3-4

3-7

3-6

8-5

6-8

7-2

6-3

5-6

5-4

5-3

4-6

4'3

4-0

3-2

2-7

2 8

2-8

7-6

4'5

4-6

3-8

3-8

3-7

3-3

3-0

2-8

2-6

2-5

2-2

2-5

2-5

4-6

9-0

9/5

9-0

8-2

7-5

7-0

6-6

6-2

5-9

5-6

5-3

5-3

5-3

9-5

Summer.

11-6
1 9 -1

13-7

-i 9 ,K

13-5

U.Q

12-0

10-5

9-1

8-1

7-8

8-1

8-2

8-1

7-9

7-5

12-5

9-8

10-5

y

10-5

i(j (J
9-9

0 D

8-7

7 7
7-8

4

7-4

7-0

6-8

6-8

6-6

5-8

1
5-5

y
10-9

9-7

10-6

10-4

9-7

8-1

6-7

5-6

6-0

5-9

5-6

5-8

5-3

5-1

10-4

10-3

11-5

11-2

9-6

7-7

6-2

5-2

4-9

5-0

5-1

4-9

4-8

4-6

10-4

8-3

9-1

8-9

8-2

7-0

6-4

6-4

5-7

4-9

4-7

4-4

4'4

3-8

9-1

10-3

11-3

11-1

9-9

8-4

7'3

67

6-5

6-4

6-3

6-2

5-9

5-6

10-9

Declination as deduced from Table I.

Noon

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

Mid.

Summer Means.

/

+ 4-0

/

-t-5-0

/

+ 47

/
+ 3-6

/

+ 2-1

+ 1-0

/
+ 0'4

/

+ 0-1

/

o-o

/

o-o

/

-o-i

/

-0-5

/

-0-7

Winter Means.

/
+ 2-G

/
+ 3-1

/
+ 2-6

/

+ 1-8

/
+ 1-1

/
+ 0-6

/

+ 0-2

/
-0-2

/
-0-5

/

-0-8

/
-1-1

/

-1-1

/
-1-1 '

Annual Means.

+ 3-3

/

+ 4-1

/

+ 3-7

/

+ 2-7

/
+ 1-6

+ 0;8

/
+ 0-3

/
o-o

/
-0-2

/
-0-4

/
-0-6

/
-0-8

/

-0-9

Joints to the west of its mean position.
OL. LXIII.

178

Report of the Kew Observatory Committee.

Table III. — Hourly Means of the Horizontal Force in C.Gr.S. units (corrected

(The Mean for the

Hours

Preceding
noon.

Mid

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

0-18000 + Winter.

1897.

Months.

1

Jan. . . .

320

326

327

327

329

331

332

333

333

328

324

319

317

Feb. ...

: 324

335

335

334

334

335

336

335

336

334

330

326

325 j

March . .

319

337

337

337

337

338

339

340

340

335

326

320

319

Oct. ...

332

350

348

347

347

349

349

349

346

340

333

328

330

Nov. . . .

339

345

345

344

347

349

351

351

349

348 j 343

337

338

Dec. . . .

346

347

348

347

.351

353

355

355

354

355 j 354

349

346

Means. .

• 330

340

340

339

341

342

344

344

343

340

335

330

329

Summer.

.

April . . .

300

331

331

331

329

331

333

336

331

325

316

307

302

May ...

331

345

345

344

345

344

343

340

334

328

324

322

325

June . . .

332

350

349

348

348

348

345

341

337

333

329

331

331 1

July ...

329

354

354

352

351

351

349

346

341

334

329

323

325 1

Aug. . . .

331

348

348

347

347

346

345

342

338

330

327

327

330 |

Sept

341

358

358

358

357

357

357

356

353

346

339

336

340

Means. .

327

348

347

347

346

346

345

343

339

333

327

324

325

Table IY. — Diurnal Inequality of tl

Hours

Mid.

i-

2.

3.

4.

5.

6.

7.

I
8. 9.

10.

11.

Summer Means.

j 4- '00004

+ -00003

+ -00003

+ -00002 '+ '00002

+ -00001 - -00001

1

- -00005

-•000 11

- -00017

- -00020

1

-•000191

I

Winter Means.

•00000

. -ooooo

- -00001

+ -ooooi

+ -00002

+ -00004

+ -00004

+ -00003

•OOOOO - -00005

- -00010

-•coon

Annual Means.

+ -00002

+ -00002

+ -coooi

+ -00001

+ -00002

+ -00002

+ -00002

- -00001

- '00006

- '00011

- -00015

- -000151
J-

NOTE.— When the sign is +

Report of the Kew Observatory Committee.

171)

for Temperature) as determined from the selected quiet Days in 1897.
Year = 018342.)

Noon.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

Mid.

Succeeding
noon.

Winter.

319

325

329

328

328

330

331

332

331

331

328

32ft

327

321

329

333

333

333

333

334

334

335

335

337

338

338

337

321

323

327

329

331

334

337

337

341

343

343

341

342

%340

323

337

344

346

347

346

348

350

354

353

354

352

354

353

339

340

343

344

342

344

349

350

349

•349

348

348

350

348

343

350

354

354

354

353

354

354

354

354

354

353

353

352

351

333

338

339

339

340

342

343

344

344

344

343

344

343

333

Summer.

307

312

320

327

333

337

338

342

340

340

341

342

341

310

330

340

343

318

348

352

355

357

355

354

350

353

350

331

338

341

341

344

346

351

354

360

359

359

357

356

353

340

332

340

346

354

354

359

361

362

363

363

360

359

356

339

334

336

340

344

348

352

351

357

355

355

352

351

351

342

347

351

355

357

357

358

359

363

364

363

364

362

362

342

331

337

341

346

348

351

353

357

356

356

355

354

352

334

i

lorizontal Force as deduced from Table III.

Soon 1. 2.

4. 5,

7. 8.

10. 11. Mid.

Summer Means.

•00002-

•00013 - -00007 - -00003 + -00002 + -00004 + -00007 + '00009 + '00013 + '00012 + -00012 + -00011 + -00010 + -00008

Winter Means.

•00007 - -00002 - -00001 - -00001 -00000 + -00002 + -00003 + -00004 + -00004 + -00004 + -00003 + -00004 + -00003

Annual Means.

•00010 - -00005 - -00002 -CCOOi + -00002 + '00005 + '00006 + -00008 + -00008 + '00008 + -00007 + -00007 + -00006

ading is above the mean.

o 2

180

Report of the Kew Observatory Committee.

Table Y. — Hourly Means of the Vertical Force in C.G.S. units (corrected

(The Mean for the

Hours

Preceding

Mid.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

noon.

0-43000 + Winter.

1897.

Months.

Jan. . , .

896

911

912

912

912

913

912

912

913

913

911

909

909

Feb. ...

928

925

925

926

926

926

926

925

925

924

923

920

918

March . .

937

948

948

947

947

946

946

946

946

946

943

938

933

Oct. ...

863

882

882

882

882

881

880

881

882

832

879

875

873

Nov. . . .

883

887

836

886

885

885

886

885

885

835

885

884

883

Dec. ...

892

886

886

887

888

888

889

888

888

888

887

687

886

Means

902

906

906

907

907

906

.906

906

906

906

905

902

900

Summer.

April . . .

879

897

897

893

894

893

895

895

896

895

889

883

876

May ...

891

917

917

915

915

914

915

914

912

909

906

897

890

June . . .

900

920

919

919

920

920

922

922

921

918

914

911

907

July ...

891

908

906

906

905

905

907

905

905

902

899

898

893

Aug. . . .

896

914

915

915

914

914

916

917

916

914

907

901

898

Sept. ...

893

904

904

904

903

903

903

903

903

899

896

894

892

Means

892

910

910

909

908

908

910

909

909

906

902

897

893

Table VI. — Diurnal Inequality of th

Hours Mid. 1. 2. 3. 4. 5.

7. 8. 9. 10. 11.

Summer Means.

+ 'OOC04

1
+ -000031 + '00002

+ -00002

I
+ •00002!+ -00003

+ -00003

+ -00002

•00000

- -00005 '--00009,- -00014

Winter Means.

•OCOOO -00000 -00000 -00000 -OOOCO -00000 -00000 -00000 -OOOCO - -00002 - -00004 - -00001

Annual Means.

+ -00002 + -00002 + -00001 + '00001 + '00001 + -00002 + '00001 + '00001 -00000 - -00003 - -00007 - '0001

NOTE.— When the sign is + tl

:

Report of the Kew Observatory Committee.

r Temperature), as determined from the selected quiet Days in 1897.
Year = O43906.)

.Noon.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

Mid.

Succeeding
noon.

Winter.

910

911

916

916

915

915

915

915

914

914

913

913

912

918

921

923

929

932

933

932

931

929

928

926

925

923

924

912

933

933

939

946

950

952

951

951

950

950

949

949

949

926

875

878

880

883

884

883

883

883

883

883

882

880

879

875

886

887

890

892

892

891

889

889

889

890

888

888

888

879

886

887

888

888

888

888

888

887

887

8S6

887

887

887

875

902

903

907

909

910

910

909

909

908

908

907

906

906

898

Summer.

874

877

883

890

893

895

895

897

896

895

894

895

894

872

892

897

904

910

912

917

918

919

917

917

917

917

914

888

808

911

913

918

922

923

924

925

927

926

924

924

922

903

894

895

901

907

913

915

916

915

914

913

911

910

908

887

895

898

903

911

914

915

917

915

914

913

911

910

910

896

892

894

896

901

905

904

905

905

905

905

905

904

904

897

892

895

900

906

910

911

912

913

912

911

910

910

909

891

Vertical Force as deduced from Table Y.

Noon 1. 2. 3. 4. 5. 6. 7. 8. 9. 10 11. Mid.

Summer Means.

- '00014

-•00011

- -00006

•00000

+ -00003

+ -00005

+ -00006

+ -00006

+ -00006

+ -OOOOS

-r -00004

+ -00004

+ -00002

Winter Means.

- -00005

- -00003

•00000

+ -OC003

+ -00004

+ -00004

+ -00003

+ -00003

+ -00002

+ '00002

+ -ooooi

•ooooo

•ooooo

Annual Means.

- -00009

- -00007

- -00003 + -00001

-00003

•00004

•00004

+ -OC004

•00004

+ '00002

+ -00002 + -C0001

•coding is above the mean.

182

Report of the Kew Observatory Committee.

Table VII. — Hourly Means of the Inclination, calculated from the Horizontal

Hours

Preceding

Mid.

1.

2

3.

4

5.

6.

7.

8.

9.

10.

11.

noon.

67° + Winter.

1897.

Months.
Jan

20-8

20-8

20-8

20-8

20-6

20-5

20-4

20*4

20-4

20-7

21-0

21-2

21-4

Feb

21-4

20-6

20-6

20'7

20-7

20-6

20-6

20-6

20-6

20-7

20-9

21-1

21-1

March . .

22-0

21-1

21-1

21-1

21-1

21-0

20-9

20-9

20-9

21-2

21-7

22-0

21-9

Oct

19*2

18-4

18-6

18'6

18-6

18-5

]8-'4

18-5

18-7

19-1

19-5

19-7

19-5

Nov. . . .

19-3

18-9

18-9

18-9

18-7

18'6

18-5

18-4

18-6

18'6

19-0

19-3

19-2

Dec

19-0

18-7

18-7

18-8

18-5

18-4

18-3

18-3

18-3

18-3

18-3

18-6

18-8

Means . .

20-3

19-8

19-8

19-8

19-7

19 '6

19-5

19-5

19-6

19-8

20-1

20-3

20-3

Summer.

,

April . . .

21-7

20-1

20-1

20-0

20-1

20-0

19-9

19-7

20-1

20-4

20-9

21-3

21-5

May....

19-9

19-8

19-8

19-7

19-7

19-7

19-8

20-0

20-3

20-6

20-8

207

20-3

June . . .

20-1

19-5

19-5

19-5

19-6

19-6

19-9

20-1

20-4

20-5

20-7

20-5

20-4

July....

20-1

18-9

18*8

19-0

19-0

19-0

19-2

19'3

19-7

20-0

20-3

20-6

20'4

Aug. ...

20-1

19-4

19-5

19-5

19-5

19-6

19-7

19-9

20-2

20-6

20-7

20-5

20-2

Sept

19-3

18-5

18-5

18-5

18-5

13-5

18'5

18-6

18-8

19-2

19-5

19-7

19-4

_

Means . .

20-2

19-4

19-4

19-4

19-4

19-4

19-5

19-6

19 9

20-2

20-5

20-6

20-41

Table VIII. — Diurnal Inequality of the

Hours

Mid.

1.

2.

3.

4.

5.

6.

7.

8.

9.

10.

11.

1 S

Summer Means.

-0-1

-o-i

-o-i

-o-i

-o-i

o-o

+ 0-1

+ 0-4

+ 0-7

+ 1-0

+ 1-1

+ 0-9

Winter Means.

o-o

o-o

+ 0-1

-o-i

-0-2

-0-2

-0-2

-0-2

o-o

+ 0-3

+ 0-6

+ 0-6

Annual Means.

-O'l

-o-i

o-o

-o-i

-0-2

-o-i

-o-i

+ 0-1

+ 0-4

+ 0-7

+ 0-8

+ 0'7

NOTE. — When the sign is -f

Report of the Kew Observatory Committee. Itf3
and Vertical Forces (Tables III and Y). (The Mean for the Year = 67° 19

'•6.)

Noon.

1.

2.

3.

4.

5.

O*

7.

8.

9.

10.

11.

Mid.

Succeeding
noon.

Winter.

21-3
21-2
21-5
19-0
18-8
18-2

21-3
20-9
21-6
19-1
19-2
18-5

20-9
207
21-4
18-7
19-0
18-3

20-8
20-9
21-4
18-6
19-0
18-3

20
20
21
18
19
18

•8
•9
•5
•6
•2
•3

20-8
21'0
21-4
18-7
19-1
18-3

20-7
20-9
21-2
18-6
18-7
18-3

20-6
20-8
2L-2
18-4
18-6
18-3

20-5
20-7
21-0
18-2
18-7
18-3

20-6

20-7
20-8
18-2
18-7
18-3

20*6
20-5

20-8
18-2
18-8
18-3

20
20
20
18
18
18

•7
•4
•9

•7
•4

20-7
20-4
20-8
18-1
18-6
18-4

20-8
20-5
21-0
18-1
18-7
18-4

20-1

19-8

19-8

19

•9

19-9

197

19-6

19-6

19-6

19-5

19-6

19-5

19-6

20-0

Summer.

19-6
19-1
19-3
18-6
19-3
18-5

19-3
19-3
19-3

18-7
19-1
18'2

20-8
19 '8
19-7
19-3
19-3
19-4

21-1
20-0
19-9
19-9
19-8
18-9

20-8
19-5
19-8
19-4
19-8
18-7

20-4
19-5
19-9
19-2
19-7
18-5

20-2
19-3
19-8
18-9
19-6
18-5

19-9
19-4
19-8
19-0
19-4
18-6

19-6
19'3
19-5
18-7
19-2
18-5

19'0
19-0
18-5
18-9
18-2

19-5

19-1
19-1
18-5
19-0
18-2

19-4
19-1
19-1

18-4
19-0
18-2

19-3
19-4
19-1
18-5
19-1
18-1

19-3
19-2
19-1
18-6
19-1
18'2

19-9

19-7

19-5

19-4

19-4

19-1

19-1

18-8

18-9

18-9

18-9

18-9

19-0

19-7

Inclination as deduced from Table YIT.

Noon

1.

2.

3.

4.

5.

6.

7. 8.

9. 10.

11.

Mid.

Summer Means.

+ 0-4

+ 0-2

o-o

-o-i

-o-i

-0-4

-0-4

-0-7 -0-6

-0-6 -0-6

-0-6

-0-5

Winter Means.

+ 0-3

+ 0-1

+ 0-1

+0-1

+ 0-1

o-o

-o-i

-0-2 -0-2

-0-2 -0-2

-0-3

-0-2

Annual Means.

+ 0-4

+ 0-1

+ 0

7

•1

o-o

o-o

-0-2

-0-3

-0-4 -0-4

-0-4 -0-4

-0-4

the reading is above the mean.

I

184 Report of the Kew Observatory Committee.

APPENDIX IA.

MEAN VALUES, for the years specified, of the Magnetic Elements at Observatories
•whose Publications are received at Kew Observatory.

Place.

Latitude.

Longitude.

Year.

Declination.

Inclination.

Hori-
zontal
Force.
C. G. S.
Units.

Vertical
Force.
C. G. S.

Units.

Pawlowsk . i . .

59 41 N

30 29 E.

1895

o /

0 15 '7 E

70 42 '4 N

•16478

•47072

Katharineuburg
Kasan

56 49 N.
55 47 N

60 38 E.
49 8E

1895
1892

9 43 -3 E.

7 30' 8 E

70 39 -8 N.
68 3d "2 N

•17808
•18551

•50750
•47345

Copenhagen . . .
Stonyhurst ....
Hamburg
Wilh elmsharen

55 41 N.
53 51 N.
53 34 N.
53 32 N.
52 23 N.

12 34 E.
2 28 W.
10 3E.
8 9E.
13 4E.

1894
1896
1896
1896
1896

10 41 -3 W.
18 31 -2 W.
11 36 -7 W.
12 46-8 W.
10 14 -3 W.

fi8 57-7 N.
67 38-8 N.
67 51 -7 N.
66 38 -4 N.

•17373
•17202
•18061
•17994

•18747

•44726
•43921
•44229
• 43404

Irkutsk

52 16 N

104 16 E.

1895

2 6'6E.

70 11 -1 N.

•20132

• 55872

Utrecht ..,,..

52 5 N

5 HE.

1895

14 15 -5 W.

67 7-4 N.

•18435

•43691

Kew

51 28 N.

0 19 W.

1697

17 6 -4 W.

67 19-6 N.

•18342

•43906

Greenwich*. . . .

Uccle (Brussels)
Falmouth . « « . .

51 28 N.

50 48 N.
50 9 N

0 0

4 21 E.
5 5W

1896

1896
1896

16 56 -5 W.

14 32-5 W.
18 47 -5 W.

J67 10-0 N.\
\67 9 -3 N.J
66 23-5 N.
67 5 '0 N.

•18367

•18925
•18554

j -43622
\ -43598
•43300

•43888

Prague .

50 5 N

14 25 E

1896

9 25-5 W

• 19858

Pare St. Maur
(Paris)

48 49 N.

2 29 E.

1895

15 9 -4 W.

65 2 -9 N.

•19664

•42263

48 15 N.

16 21 E.

1894

8 43 -6 W.

63 12-1 N.

•20740

•41061

O'Gyalla(Pesth)
Odessaf

47 53 N.
46 26 N.

18 12 E.
30 46 E.

1895
1896

7 52 -5 W.
4 49 -6 W.

62 33 -9 N.

•21080
•22038

•42452

Pola

44 52 N

13 51 E

1896

9 41 '7 W.

60 31 -8 N.

•22061

•39042

Nice

43 43 N

7 16 E.

1897

12 12 '8 W.

60 15 -4 N.

•22318

•39059

Toronto^

43 40 N

79 30 W

1896

4 50 '1 W

•16645

Perpignan

42 42 N

2 53 E

1895

14 0'4W

60 8'5 N.

•223H3

•38958

41 54 N

12 27 E

1891

10 45 -1 W

58 4-6 N.

•2324

•3730

Tiflis

41 43 N

44 48 E

1895

1 48'1 E.

55 47-0 N

•25681

•37764

Capodiinonte
(Naples) ....
Madrid

40 52 N.

40 25 N

14 15 E.
3 40W

1893

1895

9 47 -0 W.
16 6 -6 "VV

56 42 -1 N.

Coimbra • • . . .

40 12 N

8 25 W

1895

17 42 -0 W

59 43-6 N

•22581

•38685

Washington . .
Lisbon . . ...

38 55 N.
38 43 N

77 4W.
9 9 W

1894
1895

3 39 -9 W.
17 39 -1 W

70 34-3 N.
58 15 '7 N.

•19979
•23344

•56646
•37731

Zi-ka-wei ....

31 12 N

121 26 E

1895

2 15 '6 W

45 55'1 N

•32679

•33743

Hong Kong. . . .
Colaba (Bombay)

22 18 N.
18 54 N.
14 35 N.

114 10 E.
72 49 E.
120 58 E

1896
1895

1896

0 26-0 E.
0 36 -9 E.
0 51 -OE.

31 41 -3 N.
20 48 -5 N.
16 39'7 N.

•36461
•37444

•37H68

•22509
•14230
•11333

Batavia . . .

6 11 S

106 49 K

1896

1 22 -0 E

29 29'5 S

•36768

•20795

Mauritius
Melbourne

20 6S.
37 50 S.

57 33 E.
144 58 E.

1895
1896

9 55-1 W.
8 15-0 E.

54 37-1 S.
67 18-3 S.

•23937
•23392

•33706
•55936

* Of the two values of the Inclination and Vertical Force, the first ie based on observations
with 3-inch dip needles only, the second on combined observations with needles of 3, 6, and
9 inches.

f New magnetic observatory ; only four last months' results available in 1896.

t Determinations of Inclination and Vertical Force suspended in course of 1896, owing to
disturbing action of electric tramway.

Report of the Keiv Olsewatory Committee.

185

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188

Report of the Kew Observatory Committee.

Table IV.
Summary of Sun-spot Observations made at the Kew Observatory,

Months.

Days of
observation.

Number of
new groups
enumerated.

Days appa-
rently with-
out spots.

1897.

12

7

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7

6

19

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16

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3

9

5

Totals for 1897 ....

165

64

22

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190

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192 Prof. J V. Jones. Calculation of the Coefficient of

" On the Calculation of the Coefficient of Mutual Induction of
a Circle and a Coaxial Helix, and of the Electromagnetic
Force between a Helical Current and a Uniform Coaxial
Circular Cylindrical Current Sheet." By Professor J.
VIRIAMU JONES, F.R.S. Received November 12,— Read
December 9, 1897.

§ 1. In measuring electrical resistance by the method of Lorenz we
have to determine the coefficient of mutual induction of a helix of
wire and the circumference of a rotating circular disc placed coaxi-
ally with ifc, the mean planes of the helix and the disc being
coincident. In a paper presented to the Physical Society in
November, 1888, I gave a method of calculating this coefficient ; but
subsequent consideration of the problem in connection with the
Lorenz apparatus recently made for the McGill University, Montreal,
has led me both to a simplification of the method previously des-
cribed, and also to a more general solution.

§ 2. If M is the coefficient of mutual induction of any two curves
we have

where r = the distance between two elements c7s, ds ; and e = the
an^le between these elements. Let the equations to the circle and
coaxial helix be

y = a cos 0~]

' z = a sin 6

x = 0 J

and i/' = Acos

z = A sin 9'
x' = pO'
dxdx' + dydy' + dvdz'

-

-r

Jo

Aacos(0-0'}cl0d0f

\/{A:*+O~— 2 AC* cos (0— 0') -\-p~0'*

If we change the variables, putting

Mutual Induction of a Circle and a Coaxial Helix, $-c.

0— 0' = 0

& — 0'

we find

M

J _©2 J _£

-rT Aa cos 0 Aa cos 0

where V = — - , = —

-v/(A2-f-a — 2a A cos 0 -\-p 0 ) ^

if a2 = A2 -fa2 — 2Aa cos 0.

/.2s7-02 p02 /.©i f2sr~ £

= W0C?0'-f

J_©2 J_(£ J2ra—02J-4>

Now v^' = log (^0' + y^T?^2) = F (0'), say,

and it may be readily seen by substituting 0 for 2tr— 0in the second
and fourth integrals that

JKW-tf, |MI |-»l

F(-0)t/0+ F(2^r-0)^0- F(-

-03 J2tsr-©2 J2or-©2

^2^-©!

+ F(2izr-0)d!0 = 0.

J-e

We have, therefore,
but

(ar-©2 .-or-,

F(®,)^0- ^(©0^0;

-0, J-0,

por— p2or .0 «2zir

F(@)r70=: F(0)d0, since F(®)<20=

J -0 Jfl J-0 J20T-

0

therefore

'*

M = - log (P©

- r — ^

Jo P

If ®, = 0 and ©2 = ©,

which is the coefficient of mutual induction of the circle, and a.
helix beginning in the plane of the circle of axial length, jp®.
VOL. LXIII. P

194 Prof. J. V. Jones. Calculation of the Coefficient of

It is clear that M = M©2 — M@l5

and we need therefore only consider the expression

JAacos0
. -T

where x = p® = the axial length of the helix, reckoned from the
plane of the circle.

We may now proceed in two ways — either by expanding the
logarithmic expression in powers of x/at which leads to a series of
limited application since it is convergent only so long as x < A— a ;
or by integration by parts which leads to an expression applicable
for all values of x.

§ 3. The first method I developed in the paper above mentioned.
We have

1.3.5. ... (2m— 1) 1

= A*~r 1.3.5....(2

'

p ' 2.4.6 ____ 2m 2m + l ' 0

-1) 1 / «

2 . 4 . 6. . . . 2m 2m + l \A-f-a,
i + 1 _L_l^ m~ —— gr2'?*P«t ... ( 3 )

2 \/Aa x

where c = -£_ , sr = -— - ,

A + a

0

or

Let

_ f2 cos 2

* - J (IZ^iia

= P

J (1-c-si

The following properties of these elliptic integrals are perhaps
worthy of notice : —

?'
c

Mutual Induction of a Circle and a Coaxial Helix, $-c. 195

)Q,,,— (2m— l)Q«_, ......... (iv),

)P,,,-(2m-8) (a"t + 1) p. (T),

2m— 1

'HJ* = (&,_! + cQ* ........................ (vi),

'2Q/K = (2m-c'2)Qwt-(2m-l)Q/«_1 . . . ..... (vii),

(viii),

where c'2 = 1 — c2, and the dotting of a function denotes differentia-
tion with regard to c.

It will be observed that Q0 and Q_i are respectively the complete
elliptic integrals (F and E) of the first and second kinds with regard
to modulus c.

§ 4. In equation (3) put

l)

~9 ""

so that M@ = © (A + a)c22 ( — l)"»Kw.

Then we can find by a double application of (v) a relation between
KMi+!, Km, and K,,^!, viz. : —

2m(2m + l) / (2m- 1) (2m-3)

m"" 2m. 2m K'"-1

where d2 = -- f2 and e2 = -

This formula renders the calculation of successive terms of the
series sufficiently easy.

§ 5. Hence to find M© , given A, a, and #, we have to calculate the
following quantities in order : —

196 Prof. J. V. Jones. Calculation of the Coefficient of

'2
d* = — ,— g\ and

;, K3, K4, &c., by successive applications of (-4),

and finally M@ = © (A + a)c22 (_i)»Kw.

§ 6. An example may be useful in showing the magnitudes of the
various quantities concerned.

If 2A = 21-02673 inches,

2a = 13'01997 inches,
2x — 5*02480 inches,
0 = 201 ar,

then c = 0-9719540,

c = 0-2351708,

F = 2-8598352,

E = T0655716,

K0 = 0-9387751,

J *' gz = 0-02178146,

K! = 0-0561543,

dz = 0-4156218,

e3 = 0-0206400,

K2 = 0-0076057,

K3 = 0-0014623,

K4 = 0-0003387,

K5 = 0-0000876,

Ke = 0*0000244, .•

K7 = 0-0000071,

2( — l)"*Km = 0-8890325,

3k[0 = 9028-182 inches = 22931*166 cm.

If the circle is in the mean plane of a helix of axial length 2x, the
coefficient of mutual induction will be 2M© , or in case of the above
dimensions,

M = 2M© = 18056-364 inches = 45862'332 cm.
The value of M@ given above was obtained in 1896 by

Mutual Induction of a Circle and a Coaxial Helix, 8fc. 197

Mr. Rhodes under the direction of Prof. Ayrton in the Physical
Laboratory of the Central Institution, in which the Lorenz apparatus
of the McGill University was tested by Prof. Ayrton and myself
(Appendix to the Report of the Electrical Standards Committee
of the British Association, 1897). The calculation was made by the
somewhat laborious method indicated in my paper " On the Deter-
mination of the Specific Resistance of Mercury in Absolute
Measure." * It was checked by Mr. Mather, and subsequently I
calculated M© afresh by the method given here.

§ 7. It is important in practice to determine the change in M© con-
sequent on small changes in A, a, and a?, both for the calculation of
the effect on M@ of small errors of measurement, and because from
time to time the disc of any Lorenz apparatus needs to be re-ground
in place, and possibly the coil, owing to a breakdown in insulation,
may sometimes need to be re-wound.

Let

then

A

M©

a dM.&

r =

M® da

x
M© dx

dM.®

"AT~
M©

dA.

-ir
A

da

—
a

dx

~
x

It may be shown by direct differentiation using relation (iii)
between the P functions and their differential coefficients that

s = 2T/W

1

where

2 deW )>

r - l~S T+2Y

2 " deW J

W=2(-i)»KfB,

(5),

2m — 1

and d, e have their former significations. W has already been found
in calculating M©; and T and V are easily calculable from the known
values of K0, Kl9 K2, K3, &c.

Since M© is a homogeneous function of the first degree in
A, a, x it follows that q + r + s = 1, as is obvious in the formulae
above given.

* 'Phil. Trans.,' A (1891), p. 21.

P 2

198 Prof. J. V. Jones. Calculation of the Coefficient of
§ 8: For the values of A, a, x given in § 6 we find

W = 0-8890325,

T = —0-0443163,

2V = —0-1036138,

log de = 2-9667036,

8 = —0-0997,

q = —1-2467,

r = +2-3464,

or cZM©/M@ = — l-

Let us suppose that after re-winding the coil mentioned in § 6,
and regrinding the disc, the diameters become

2A' = 21*02459, 2a' = 13'01499.
Then rda/a — — 0'000899,

qdA/A. = +0-000127,
and e?M@/M© = — 0'000772 or dM.® — 6'97 inches = I7'70cm.

Therefore M'© = 9021-21 inches = 22913*47 cm.

§ 9. I now pass on to the second and more general method of deal-
ing with the expression —

Integrating by parts we have
Me =

• 16A2a2®

, -. ,„ 4A.a

C

Hence by simple changes we have

•; ..... (6),

where F and E are complete elliptic integrals of the first and second
kinds to modulus fc,

Mutual Induction of a Circle and a Coaxial Helix, Sfc. 199

n j-j r 2 d^fr

" Jo (l-c2sin2 y>) v/(l-&2sin2 ty) '

This expression for M@ is applicable for all values of x from 0 to oo .
The elliptic integral of the third kind n is expressible by Legendre's
formula in terms of complete and incomplete integrals of the first
and second kind. Thus, if we put

or sin/3 =

we have (v. Cayley, " Elliptic Integrals," § 183)

These elliptic integrals, complete and.incomplete,may be conveniently
calculated by successive quadric transformations, as shown in
Cayley, Chap. XIII.

§ 10. Taking for the diameters of helix and circle, the values given
in § 8, viz.,

2A' = 21-02459, 2a' = 13'01499,

and as before 2x — 5*02480,

Professor Ayrton and I made the calculation of Me by equation (6)
with the following results : —

c = 0-9719222,

~k = 0-9615024,

V = 0-2747959,

L sin (3 = 9-9326156,

F (&) = 2-7109750,

E (A;) = 1-0840174,

F (&',£) = 1-0393881,

E (&', /3) = 1-0168643,

fc'2 sin 8 cos 8

L (F — 0) = -0-5051433,
c

c/2

-y (F — n) = —0-8616240,

?JrJ? = 1-7598494,
M© = 22913 '59.

200 Prof. J. V. Jones. Calculation of the Coefficient of

This result afforded a sufficiently satisfactory proof of the accuracy of
the calculations, seeing that the result in § 8 was obtained by the
application of equations (3) and (5), and that it approximated so
closely to the result just given. The approximation would be still
closer if we had taken account of the neglected terms of the series,
K8 and K9.

§ 11. To find corresponding general expressions for the rates of
variation of Me with A, a, and x it is simplest to revert to the
expression

A f*

_ -^a \

P Jo

We have dM& - _M? +:^ f * cos

dx ' ~ x x \ v/

(putting p — a?/®),

= _ + p

x x

,,, ,.- /-2or A ,

aM@ M© , A — a cos 0
~7T~ == "7 Aa® cos0 2 .,— ^

A cos 0— a

= -Aa®

where F and II have the same significations as in equation (6).
Similarly d~ = ®ck | F~^^ (1?-n) } »

1

It is readily deducible from equations (7) that

+ r + s = 1.

Mutual Induction of a Circle and a Coaxial Helix, $c. 201

When M© has been calculated by (6) it is a simple matter to
calculate q, r, -s by the above equations.

M©
Let g> / A i \ ~7. = Z. Then equations (7) may be expressed

thus : —

For the values of 2A , 2«', 2oj taken in § 10 we have

n = 17-411370,

Uc = 4-096932,

V — He = —1-385957,

F + He' = 6-807907,

Z = 0-8982254,
P0(&) = —0-8087238,
2 = —1-24629,
r = + 2-34593,
8 = —0-09964.

On the Potential Energy of a Circular Current and a Uniform Coaxial
Circular Cylindrical Current Sheet.

§ 12. The current lines in the sheet are circles in planes at right
angles to the axis.

Let the circle have its centre at the origin, and let its equations be

y = a COS 0"|

z = a sin 0 J

and let the equations to the coaxial cylindrical sheet be

if = A cos & "I
z = Asin0'J

the plane ends of the cylinder being determined by the equations
x = XH x = #2.

Let the current in the circle be »/e, and the current per unit length
of the cylindrical sheet 7 ; and let the potential energy of the circular
current and the current sheet be M'.

202 Prof. J. V. Jones. Calculation of the Coefficient of

(0-0')

j o o

M' = 2ar7<-7 Aa f cos 0 log /- + A / * + ^

LJ0 \a V a

For a circle and coaxial helix we find the potential energy by
multiplying their coefficient of mutual induction by the product of
7o 7*> the currents in the circle and helix respectively. Taking the
expression for the coefficient of mutual induction

M = M@2-M@1,

M©., and M0t being expressed by equation (2), and noting that
<yA = 2orp7 where 7 is the current per unit length of the helix measured
parallel to the axis, we see that the potential energy of the circle and
coaxial helix is identically the same as the potential energy of the
circle and a uniform coaxial circular cylindrical current sheet of the
same radial and axial dimensions as the helix, if the currents per
unit length in helix and sheet be the same.*

On the Potential Energy of a Helical Current and a Uniform Coaxial
Circular Cylindrical Current Sheet.

§ 13. If we attempt to integrate the general expression for the
coefficient of mutual induction in the case of two coaxial helices we are
brought face to face with functions which indeed deserve the attention
of mathematicians, but do not at present lend themselves to
calculation.

For many practical purposes, however, it will be equally useful to
calculate the potential energy of a helix and a coaxial uniform
circular cylindrical current sheet, or of two coaxial uniform circular
cylindrical current sheets ; and this potential energy is expressible
in terms of elliptic integrals.

Let the equations to a helical current be as before,

y' = A cos 0' ~}

I
z = A sin 0' }• ,

* I.e., if the current across a generating line of the sheet equal to the pitch of
the helix is equal to the helical current. — J. V. J., April 21, 1898.

Mutual Induction -of a Circle and a Coaxial Helix, tjr. 203

the limits of x being x\ and x'z, so that the axial length of the helix
is x'% — x'i.

Let the equations to a coaxial circular cylindrical current sheet bo

y = a cos 0, z = a gin 0,

its ends being at distances x}, x-> from the origin.

Let 7A be the current in the helix, and let 7 be the current per unit
length of the uniform current sheet. Then if M' is the potential
energy of the helical current and the current sheet we have

A f

= — 7A7 cos 0d0[/(#r2 — x\) — /(#^— ^)+/(#\— #2)— /(Xi— #0]
P Jo

whore f(z) EE z Ic

«2«

The integral cos<j)f(z)d(j> is easily reducible to elliptic integrals

J/o
of standard form.

It is to be noticed that f(z) =f(—z).

If the axial length of the helix = 2?, and the axial length of the
cylindrical sheet = 2?n, and if x equals the distance between their
mean planes, we have

M ' =

A

cos 0 cZ0 [ / (,« + 1 -f- m) — / (x + Z — m)

(9).

Similarly for two coaxial cylindrical current sheets v/e have

cos

Z — w)-/(a; — Z + m)]... (10),

w lie re 7, 7' are the currents per unit lent^th in the sheets.

§ 14. To find the force betvv-eeu a helical current and a coaxial
circular cylindrical uniform current sheet we have to differentiate
the potential energy as expressed in equation (9) with regard to x.

20-1- Coefficient of Mutual Induction of a Circle,

We have, if X is the force,
Aa 2ar

dM' Aa f

= — -- = 7*7 — cos0d0[F(# + Z + m) — F(# + Z — w)
'

+ F(aT— Z— m) — F(ir— Z + m)],

whoro F(«) = /'(*) = l

or by equation (2)

X==7/<7(M2-M1) ................ (11),

where M2 = coefficient of mutual induction of the helix and one of

the circular ends of the sheet,

and MI = coefficient of mutual induction of the helix and the
other circular end of the sheet.

M2 and Mt may be calculated as described in the previous articles
of this paper.

§ 15. Equation (11) is clearly a particular case of a more general
theorem.

Take any cylindrical sheet developed by the rectilinear translation
of a given closed curve, and let the sheet be the seat of a uniformly
distributed current, the current lines being successive positions of the
given curve as by its translation it developes the sheet. Let the
current per unit length of the sheet be 7. Further, let M! be the
coefficient of mutual induction of the given curve in its first position
and any second fixed curve, and M2 the coefficient of mutual induction
of the given curve in its last position and the second curve ; and let
72 be the current in the second curve.

Then the force between the current sheet and the second curve
resolved parallel to the direction of translation of the given curve as
it developes the sheet is given by the formula —

F = w(Ma-Mi).

For let the direction of translation be taken as the axis of sr- ; and
let MX be the coe'fficient of mutual induction of the given curve in
any intermediate position defined by the co-ordinate «, i.e., of an
element of the current sheet, and the second curve. Then the force
resolved parallel to a1 between the element of the current sheet and
the second curve

= 72 . <ydx • dklf/dx,

and the total force so resolved between the current sheet and the
second cur re

Meeting of March 31, 1898. 205

i

72 • «/dx • dM.x/dx = 727 (M2— M^.*

•*i

As special cases, we have equation (11) reducing the calculation of
the force between a circular cylindrical uniform current sheet and a
coaxial helical current to the calculation of the coefficients of mutual
induction of the helix and the circular ends of the sheet ; and the
simpler case of the force between a circular cylindrical uniform
current sheet and a circular current, which is obtained from the
calculations of the coefficients of mutual induction of the circle and
the circular ends of the sheet.

I hope that equation (11) may be of service in the accurate calcu-
lation of the constants of current weighing apparatus. My attention
was drawn to the matter from this point of view in consequence of
the Report of the Electrical Standards Committee of the British
Association made at Toronto, in which mention is made of the
importance of re-determining the ampere.

March 31, 1898.
The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.

Preliminary communications upon the results of the recent Solar
Eclipse were made by the following members of the expeditions : —

The Astronomer Royal, Sir J. Norman Lockyer, K.C.B., Professor
H. H. Turner, Dr. R. Copeland, and Captain E. H. Hills, R.E., and
Mr. H. P. Newall.

The Society adjourned over the Easter Recess to Thursday,
April 28.

* Professor A. Q-ray has pointed out to me that this result may be deduced from
the consideration that the removal of an element from one end of the sheet to the
other is equivalent to a small motion of the sheet parallel to its generating lines.
— J. V. J., April 21, 1893.

VOL. LX1II.

206 Piince Albert I of Monaco.

April 28, 1898.

The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.
The following Papers were read : —

I. " On the Meteorological Observatories of the Azores." By
H.S.H. PRINCE ALBERT I OF MONACO. Communicated by
J. Y. BUCHANAN, P.R.S.

II. "A Compensated Interference Dilatometer." By A, E. TUTTON.
Communicated by Professor CLIFTON, F.R.S.

III. " A Calorimeter for the Human Body." By WILLIAM MARCET,

M.TX, F.R.S.

IV. "An Experimental Enquiry into the Heat given oat by the

Human Body." By WILLIAM MARCET, M.D., F.R.S.

" On the Meteorological Observatories of the Azores." By
H.S.H. THE PRINCE ALBERT I OP MONACO. Communi-
cated by Mr. J. Y. BUCHANAN, F.R.S. Received April 19,
—Read April 28, 1898.

(Translation.)

In 1892 I brought before the British Association, met in Edin-
burgh, a project which my scientific cruises in the North Atlantic
had suggested and preliminary experiments have matured. The
importance of meteorological observations is now universally recog-
nised, and a continually increasing number of centres of observation
are being created in order to assist the progress of this science.

I proposed to establish on the Azores an advanced post, whose
mission should be : 1st, to observe the birth of certain atmospheric
disturbances, which appear to .be formed in this region of the
Atlantic; 2nd, to correct the path of certain others which appear to
threaten the coasts of Europe and which are announced from
America at too great a distance of time and space for there to be an
assurance that more or less considerable modifications may not take
place which will affect their strength, their direction, and the date of
their arrival on the European coasts.

We should then have, on a point situated almost in the middle of

On the Meteorological Observatories of the Azores. 207

the Atlantic, an observatory, the work of which would also include
the study of seismic phenomena, and this with great advantage,
because, in certain circumstances, the earthquakes felt in Europe
have, in the first instance, affected the volcanic massif of the Azores.
It is hardly necessary to say that those interested in the study of
terrestrial magnetism will view with pleasure the opening of an
observatory which is to render useful services in this department of
science. Many countries will profit directly by the observations
made on the Azores, because they interest all branches of the
nautical profession as well as the populations of all the western
•coasts of Europe. The navigator approaching the end of a long
voyage in a sailing vessel will here find the means of regulating his
chronometers at the time when it is most wanted, namely, before
making the continental land.

Since the first mention of my project in 1892, an event, which I
awaited with much impatience, has arrived to help it, namely, the
telegraphic connection of the Azores with Europe. Soon af terwards
the Portuguese Government gave effect to my views by creating on
the Island of St. Miguel, and under the direction of Captain Chaves,
a regular meteorological station, although fitted with the most
modest means.

Finally, last year Captain Chaves was commissioned to establish
-on the Island of Flores, the most westerly of the Azores, a second
meteorological station, the observations at which will be most useful
for supplementing those of San Miguel. Unfortunately, its means
are even more modest than those of the preceding one, and the
telegraph cable has not yet reached it.

In spite of the insufficient means of observation actually existing
in the Azores, the results which they already furnish towards estab-
lishing the paths of the depressions which cross the Atlantic, enable a
presentiment to be formed of the part which they will play when
their outfit is more complete.

In order that science may the sooner profit by tbe advantages
promised by the observatory of the Azores ; and in order to guarantee
it against all the dangers which might cause an interruption of its
functions, I propose to give it a constitution founded on the prin-
ciple of an international guarantee, which would be secured by the
pecuniary contributions of the countries interested. It is principally
to expose this idea that I have come to-day to speak of these
observatories to the Royal Society.

Portugal, accepting the principle of the international regime, has
commissioned Captain Chaves to invite the maritime nations in-
terested to give their adhesion to my project and to associate them-
selves in the organisation of the above-mentioned meteorological
service.

Q 2

208 Mr. A. E. Tutton.

IL may therefore be hoped that in the near future an understand-
ing will be arrived at on the importance of the development to be
given to the observatory of the Azores, and I ask the Royal Society,,
whose influence is so great in the domain of science, to support, by
its concurrence, the accession of England to the ideas which I uphold
for the common interest.

" A Compensated Interference Dilatometer." By A. E. TUTTON,
Assoc. R.C.S. Communicated by Captain ABNEY, C.B.,
F.R.S. Received March 8,— Read April 28, 1898.

(Abstract.)

The author describes a form of Fizeau interference dilatometer
which he considers combines the best features of the apparatus
described by Benoit, and belonging to the Bureau International des
Poids et Mesnres, in Paris,* and that described by Pulfrich'f con-
structed according to the modifications introduced into the method
by Abbe. Moreover, besides other improvements, a new principle,
that of compensation for the expansion of the screws of the Fizeau
tripod which supports the object, is introduced, which enhances the
sensitiveness of the method so highly as to render it applicable
to the determination of the expansion of crystals in general, includ-
ing those of chemical preparations. Hitherto the application of the
Fizeau method has been confined to such crystals as could be obtained
large enough to furnish a homogeneous block at least a centimetre
thick. A block only 5 mm. thick is ample for use with the author'*
compensated dilatometer. The principle of the compensation de-
pends upon the fact that aluminium expands 2'6 times as much as
platinum-iridium for the same increment of temperature. The author
therefore employs, like Fizeau and Benoit, a tripod of platinum-
iridium, and places upon its transverse table, through which pass
the three screws, a disc of aluminium whose thickness is l/2'6ths of
the length of the screws. The space between the lower surface of
the glass plate which is laid upon the upper ends of the screws to
assist in producing the interference, and the upper surface of the
aluminium, then remains constant for all temperatures under obser-
vation, and if a crystal is laid upon the aluminium compensator the
whole amount of its expansion by rise of temperature is available
for measurement by the interference method. Hence the method is
no longer a merely relative one, affording the difference of expansion
between the tripod and the substance investigated, but affords*
directly absolute measurements of the expansion.

* ' Trav. et Memoires,' 1881, p. 1.

f ' Zeita. fur Instrumen.,' 1893, p. 365.

A Compensated Interference Dilatometer. 209

The instrument consists of two independently mounted portions,
which the author terms respectively the expansion apparatus and the
illuminating and observing apparatus. For the purposes of pre-
liminary adjustment the two portions are arranged at close quarters,
while during the observations they stand at opposite ends of the slate
table, 6 feet in length, upon which they are mounted, the expansion
apparatus resting on a separate and movable cloth-lined slab for the
purpose of effecting the transfer from one position to the other.
Hence the optical measuring apparatus is far removed during obser-
vations from the heated atmosphere of the chamber containing the
tripod.

The illuminating and observing apparatus consists of a telescope
arranged with a side tube for auto-collimation. It is mounted on a
stout pedestal provided with three legs and levelling screws, and its
height can be varied by the vertical rack and pinion movement of a
stout inner column. At the common focus of the lens of the side tube
and of the telescope objective a small totally-reflecting prism is
placed, half closing the aperture of a diaphragm placed on the
objective side of the prism in the main optical tube ; the prism is so
arranged that the light from the illuminating lens is reflected
through the diaphragm to the objective. It passes thence, as parallel
rays, across the intervening space to the expansion apparatus, at the
summit of which it meets with one of two interchangeable deflecting
arrangements which direct the rays vertically down the tube of the
expansion apparatus into the interference chamber containing the
tripod. One of the two is a large totally-reflecting prism ; this is
used when white light or a sodium flame is the source of light
placed before the illuminating lens, the former for adjusting pur-
poses and the latter for generating the bands. The other is a train
of two refracting prisms whose total minimum deviation averages
90° ; this is used when a hydrogen and mercury Geissler tube is the
source of light; the dispersion being then adequate to effectively
separate the red C from the greenish-blue F radiations, or both from
the mercury green, radiation, when it is desired to generate bands in
C or F hydrogen light, or that corresponding to the green mercury
line as recommended by Pulfrich.

The expansion apparatus is suspended from an arm carried by a
pedestal provided with rack and pinion vertical adjustment as in the
case of the observing apparatus. Below the deflecting prism or
prisms the short metal tube passes into a longer one of porcelain,
which at its lower end is fitted into a further short metal tube carry -
. ing below the interference chamber within which the tripod is
placed. On passing down the tube from the deflecting apparatus the
rays pass first through a slightly tilted, thick glass disc held in a
diaphragm and forming the roof of the interference chamber. They

210 Mr. A. E. Tutton.

then pass through the large cover-disc laid on the tripod screws,
the under surface of which is one of the two surfaces the reflections
from which are to be made to interfere ; the other of the two relevant
surfaces is the upper surface of the crystal supported on the com-
pensator, or in the case of a badly reflecting crystal, of a small disc
of black glass, polished above and ground below, which the author
lays upon it. The large cover-disc and the glass roof-disc are slightly
wedge-shaped to the extent of 35', and are arranged complementarity
so as to counteract the dispersion produced by each other ; by using a
wedge-shaped cover-disc the undesired reflection from the upper
surface can be deflected out of the field of the telescope, and the
tilt of the roof-wedge is given for a similar reason. After reflec-
tion from the two surfaces relevant to the interference, the rays
re-traverse their path, but instead of doing so absolutely are made
to pass through the clear half of the telescope diaphragm to the
observing lens arrangement. An iris diaphragm is placed against
the main diaphragm to assist in further excluding undesirable
radiations, and the illuminated surface of the small reflecting prism
can be more or less curtailed by suitable rectangular signal-stops.

There are two observing lens arrangements : one a simple eye-
piece and the other a micrometer combination of three lenses. The
first enables the observer to properly adjust the images of the signal
stop in white light reflected from the two relevant surfaces of the
interference apparatus, so as to cover each other to the extent
required to produce interference bands of requisite width. The
micrometer combination converts the observing apparatus into a
microscope wherewith to view the bands. The spider-lines of the
micrometer are simultaneously visible. The reference point of the
interference apparatus is the centre of a minute silver ring on the
under surface of the cover-wedge, and the two vertical spider-lines
can be adjusted by a special drum to such a separation as enables the
inner circle of the ring to be brought symmetrical to themr showing
equal suitable arcs outside each ; this separation is also convenient
for the width of band generally employed, which corresponds to
100 drum divisions of the other drum which moves both spider-lines
simultaneously.

The interference chamber is provided with an adjusting table of
non-conducting material, and is quite open to the heated air of the
bath, being provided with large windows, which are also very useful
for the adjustment of the tripod. The heating bath is a double
air bath of copper suitably screened in every direction by asbestos
millboard. It is provided with a thermostat in the outer bath and
two thermometers in the inner bath. The expansion apparatus is
immersed in the latter up to a third of the porcelain tube. The
actual temperature of the tripod is ascertained by a third thermo-

A Compensated Interference Dilatometer. 211

meter, bent so that the bulb lies within the chamber in contact
with the tripod itself ; this has been found to be a point of the
first importance. With the aid of the thermostat and a graduated
gas tap a constant temperature can readily be attained.

The author determines the position of the bands at about 10° C.,
again near 70°, and once more about 120°, in order that not only
the mean coefficient, but the absolute coefficient at any temperature
and the increment per degree may be ascertained. The transit of
each band is followed and recorded permanently by means of a
specially constructed tape-puncturing recorder. This method is
found more satisfactory than relying exclusively on the Abbe
method of mere observation of the initial and final positions of the
bands for light of two wave-lengths.

The results of numerous determinations of the expansion of the
platinum-iridium of the tripod are given, carried out with the sur-
face of the tripod table and the cover-wedge separated at the long
interval of 12 mm., by the aid of green mercury light. The mean
value is very similar to that of Benoit, and is

a = 10

The result of several determinations in red hydrogen light of the
expansion of the pure aluminium used for the series of compensa-
tors, carried out by the Fizeau relative method with a block 12 mm.
thick, is

Similar determinations for the black glass of the crystal-covering
plates afford the value :

In a subsequent memoir the author intends to present the resiilta
of determinations of the expansion of the sulphates and selenates of
potassium, rubidium, and caesium.

212

Proceedings and List of Papers read.

* . * May 5, 1898.

The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.

In pursuance of the Statutes, the names of the Candidates recom-
mended by the Council for election into the Society were read as
follows : —

Baker, Henry Frederick, M.A.
Brown, Professor Ernest William.
Buchan, Dr. Alexander, M.A.
Harmer, Sidney Frederic, M.A.
Lister, Arthur, F.L.S.
McMahon, Lieutenant - General

Charles Alexander.
Osier, Professor William, M.D.
Parsons, Hon. Charles A., M.A.

Preston, Professor Thomas, M.A.

Reid, Professor Edward Way-
mouth, M.B.

Scott, Alexander, M.A.

Seward, Albert Charles, M.A.

Shenstone, William Ash well,
F.I.C.

Taylor, Henry Martyn.

Wimshurst, James.

The following Papers were read : —

I. " Observations on the Action of Anaesthetics on Vegetable and
Animal Protoplasm." By Dr. A. D. WALLER, F.R.S., and
Professor J. B. FARMER.

II. " On certain Structures formed in the drying of a Fluid with
Particles in Suspension." By Miss C.' A. RAISIN. Commu-
nicated by Professor BONNEY, F.R.S.

III. " On Photographic Evidence of the Objective Reality of Com-

bination Tones." By R. W. FORSYTE and R. J. SOWTER.
Communicated by Professor RUCKER, Sec. R.S.

IV. " The Relations between the Hybrid and Parent Forms of

Echinoid Larvae." By H. M. VERNON. Communicated by
Professor LANKESTER, F.R.S.

On the Action of Ancestlietics on Protoplasm. 213

*' Observations on the Action of Anaesthetics on Vegetable and
Animal Protoplasm." By J. B. FARMER, M.A., and A. D.
WALLER, M.D., F.R.S. Received March 9,— Read May 5,
1898.

The object in view was to observe simultaneously and compara-
tively the effects of certain anaesthetics (carbon dioxide, ether, and
chloroform) upon vegetable and upon animal protoplasm.

Two gas chambers in series, through which anassthetic and other
vapours can be passed, contain : the first, a leaf of Elodea Canadensis
under the microscope ( X 300) ; the second, a sciatic nerve of Rana
temporaries connected with an inductorium and galvanometer (or
upon occasion a galvanograph).*

The actual movements of chlorophyll bodies in a cell of the leaf
were observed and measured by one of us, while the other observer
took readings of the galvanometric deflections in response to excita-
tion of the nerve. To establish comparison between the two classes
of effects, we took as measures : — the number of chlorophyll bodies
that crossed a cobweb in the eye-piece during each successive minute,
and the magnitude of galvanometric deflections at intervals of one
minute, before, during, and after the action of the vapour. The
number of bodies passing per minute gives measure of the rate of
movement in the vegetable protoplasm, while the magnitude of succes-
sive galvanometric deflections gives measure of the mobility of the
animal protoplasm.

Our results will be most briefly presented by the records of some
representative observations.

Experiment I.

Chara. Nerve.

Chloroform vapour, 5 per Permanent abolition of Temporary abolition of
cent, for 2 minutes. movement. mobility.

Experiment II.

Weak ether vapour for No marked effect. No marked effect.

10 minutes.
Stronger ether vapour for Permanent abolition. Temporary diminution.

4 minutes.

* As described in ' Phil. Trans.,' B, vol. 188 (1897), p. 4.

214

Messrs. J. B. Farmer and A. D. Waller.

Nitrous oxide for 5 minutes.
Hydrogen for 5 minutes.

Carbon dioxide for 3 mi-
nutes.

Carbon dioxide for 4 mi-
nutes.

Carbon dioxide for 2 mi-
nutes.

Experiment III.
Elodea.

Diminution of movement.
Diminution.

Arrested, followed by
more rapid movement.

Ditto.
Ditto.

Nerve.

Diminution of responses.
Diminution.

Diminution from 15 to 5,
followed by augmenta-
tion to 35.

Diminution, followed by
augmentation.

Ditto.

Time.
1

5
6
7
8
9

10
II
12
18

16
17
18

Experiment IV.

Elodea.

Kate of movement,
indicated by number
of chlorophyll
granules passing
per minute.

18

Time.
19

15

20

41
OJ

21
22

0

23

0

24

6

r«S

6
6

co, »

16

Us

26

29

17

30

15

31

191
OJ

32
33

13

34

1

35

0

On the Action of Anaesthetics on Protoplasm,

215

Experiments V, VI, and VII.

Action of Carbon Dioxide, of Ether, and of Chloroform upon
Vegetable and Animal Protoplasm.

A. 6.

Movements of Elodea. C&nadensis. Mobility of nerve of Rana. Temporasia,.

\ \ l!!ll!!!!!llll!!!!||| I I I ! I I I I I I I I lli'lillllllllllllMI I I I I I I ! i

7 & 9 IO II IS 13 14 Ib 16 min.

The results obtained from a study of Chara and Elodea were quite
consistent, but owing to the greater ease in making a quantitative-
determination, the latter plant was used for the more exact compara-
tive experiments.

The action of carbon dioxide was to produce an initial sHght
acceleration, followed speedily by a complete cessation of movement.
After disconnecting the C02 apparatus and aspirating air through
the chamber the protoplasm, after the lapse of two or three minutes,
began to show signs of recovery. Fitful movements of the granules
first occurred, and then they soon resumed their processional motion
around the cell. At first very slow, the movement rapidly became
accelerated and considerably exceeded the normal rate. This accele-
ration was not of long dnration, and was followed by a slowing down
to the ordinary speed.

216

On the Action of Anwst/ietics on Protoplasm.

CO

The nerve showed itself, under the conditions of the experiment,
less sensitive to the action of C02 than was Elodea, and the latter
was less sensitive than an active Myxomycete plasmodium (of Bad-
hamia) similarly treated.

Ether vapour in air passed over the plant for two minutes caused a
speedy arrest of all movement, and the quiescent condition persisted
for some minutes longer. Recovery then ensued and the normal
rate of movement was slowly regained. With dilute ether vapour
(below 10 per cent, in air) insufficient to anaesthetise the nerve, the
protoplasmic circulation was unaffected.

Chloroform. — The action of chloroform proved to be far more
deadly than that of ether. Movement was arrested in less than a
minute, and two minutes' exposure to the full action of its vapour
caused the death of the cell.

When a more diluted vapour (about 2 per cent, in air) was passed
over the cell for two minutes recovery ultimately occurred.

The action of ether and chloroform, especially the latter, was very
marked in causing many of the chlorophyll granules, which had pre-
viously been almost restricted to the lateral walls, and hence had
presented their edges to the incident light, to become dispersed over
the surface of the cell, where they were fully exposed, over their
largest area to the light. The action of carbon dioxide as observed
in these experiments was not nearly so pronounced. This phenome-
non is such as might have been anticipated as a result of the paralysis,
temporary or permanent, of the protoplasm.

Structures formed in drying Fluid with Particles in Suspension. 217

" On certain Structures formed in the drying of a Fluid with
Particles in Suspension." By CATHERINE A. RAISIN, B.Sc.
Communicated by Professor T. G. BONNET, D.Sc., LL.D.,.
F.R.S. Received March 16,— Read May 5, 1898.
(PLATE 2.)

PAET I. — 1. Origin and Method of Experiments.

2. Classification of Forms produced.

3. Conditions and Causes of Formation.

4. Possible Applications in Nature.
PAET II.— 5. Results affected by Crystallisation.

PART I.
1. Origin and Method of Experiments.

I have frequently had to mount in water, for examination with the
microscope, the powder of various rocks. Certain of the slides,,
when accidentally dried, exhibited rather interesting forms. These
I showed to Professor Bonney, who encouraged me to try for farther
results, so the experiments were continued with various powdered
substances — many pigments (vermilion, indigo, sepia, &c.), chalk
and other more or less friable rocks. At first, ordinary microscope
slides were used, hut afterwards, larger pieces of glass, in each case,
generally with a cover-glass placed over the mud. The results
seem to be worth describing, as affording familiar, almost homely
illustrations which may throw some light on the origin of certain
minor structures in rocks.

2. Classification of Forms.

The chief effects produced may be shortly described. One form-
shown by the dried powder is that of a winding network (Plate 2, fig. l)r
which is formed of bent stems, fairly uniform in thickness, giving
rise to short branches in different directions, but generally at high
angles. The whole makes a kind of maze in which the broader
winding spaces often average from T\ inch to ^ inch in width.
This form arises from desiccation of a fairly dense* mass. Where
it is densest, a coarser maze is developed and the coarser part is
earlier formedf (fig. 1 towards a and b).

* I use this term for a mass where the water is distinctly "muddy," i.e., where
the proportion of the suspended particles to the water is relatively high.

t Sometimes the denser mud has been carried forward apparently b}' the
squeezing along of more suspended material (fig. 1). Sometimes a greater amount
of the solid substance has been left behind, while a less dense mass was pressed
forward. In slides left to dry in a tilted position, gravitation carried the g- eater
amount of particles towards the lower end.

Miss C. A. Kaisin. On certain Structures formed

The meshes in the network may be occupied by a finer deposit
arranged in successive curves. Within a coarser maze, the curves
are closer, and the finer material forms a more conspicuous pattern.

In other examples, the thick streaks become less bent (cf. fig. 4 ;
also fig. 2), and finally straight, sometimes with a terminal knob,
sometimes forked or branched, generally at a rather acute angle.
From these axes, finer pattern-marks seem to diverge on either
side. Certain materials usually formed straight axes* — these were
also developed in other substances under certain conditions, e.g.,
when the mud was thin, or when its boundary was within the edge
of the cover glass, or when a corner of the cover was upraised to
allow quicker escape of the moisture. Thus the straight axes seem
to be the result of a more ready retreat of the rim generally due to
a freer evaporation. While, if the cover was sealed down with
canada balsam, or if denser mud had spread beyond the edge and
•caked, so as to check evaporation,f a maze was produced.

A fine pattern may be formed either in connection with the thicker
aggregates, or where these are wanting. It generally arises from a
sorting of the material — the finer feathers and tufts are built of small
grains, the thick coarse axes of larger. The fine particles may be
spread almost continuously (e.g., ivory black, light red), the deposit
then becoming more concentrated towards a series of curving lines.
Similar wave patterns may become fan-like from development of
crossing radial curvesj (fig. 3).

Transverse bars, also curved, extend between straight axes, where
these are near together, and where the fine material is abundant in
somewhat granular substances§ (fig. 2). The predominance of
radial or of concentric or wave pattern is mainly due to the form of
the area and mode of retreat, since they are shown in the same
material. Feather forms are developed within confined areas, as in
ovoid bubbles which are contained in the margin of a deposit of van-
dyke brown (fig. 4).

This example (fig. 4) also illustrates other forms. The mud dried,
or partially dried, along part of the edge and water from the
included mass then tried to escape. Thus, bubbles were formed,
generally elliptical or ovoid, and elongated transversely to the

* Gamboge, Upper Headon marl, boulder clay, pipe-clay, some slides of chalk,
a tendency in vandyke brown, sepia, vermilion, &c.

f This was shown in one slide of vandyke brown. In another slide of that
material the cover was not sealed, and although the mud caked at part of the edge
(the part figured in fig. 4), the water escaped along most of the sides, and straight
axes were produced.

j Vandyke brown, Prussian blue, crimson lake, ultramarine, vermilion, sepia,
chalk.

§ Like chalk, pipe -clay, £c; not smooth uniform substances, as vandyke brown,
gamboge, &c.

in the drying of a Fluid wit/i Particles in Suspension. 219

like vesicles towards the surface of an igneous sheet or
dyke. Still more interesting are tapering pointed canals, some of
which radiate from the bubbles or from a central point. Others are
generally branched, often slightly curved, and have a central granu-
lar streak. Near the sealed edge, canals are numerous and vesicles
are large and few ; while beyond this part, the canals diminish in
number and finally almost entirely give place to numerous but small
vesicles. The intervening mud exhibits various contraction cracks
which originated in drying.

Thus, the structures may be classified as : —

1st. Those of coarser threads,

(1) where these form a maze ;

(2) where they produce straight axes usually with terminal (or
initial) knobs ;

2nd, the finer pattern,

(3) consisting of concentric or wave-lines ;

(4) forming feathery or fan-shaped tufts ;

3rd (5) vesicular structures, including rounded vesicles, or taper-
ing canals ;

4th (6) contraction structures, cracks.

This classification is somewhat artificial and intended to indicate
the chief types, between which gradations may be found ; and by
combination and aggregation of different forms numerous varieties
arise, as may be seen in the few figures reproduced.

3. Conditions and Causes of Formation,

It is not always easy to describe concisely the exact conditions that
govern the formations since they include at least three variables.
First, the nature of the material, its specific gravity, adhesive
character, and the size of the grains ; second, the relative amount of
the material, i.e. the muddiness of the fluid mass ; third, the form of
the area occupied and the direction of retreat during subsequent
drying. As an example of the influence of the last-named condition :
in one case, when indigo was carried in by a current, the coarser
particles were deposited over a triangular or semicircular area,
while the finer material spread over the whole space.* Further, any
pressure or force acting upon the mass during drying may influence
the form assumed ; thus bubbles sometimes exercise a resistance on
the part surrounding. f

Materials which consist of grains too large and heavy to be easily
moved may give rise to a rude attempt at a pattern. Thus, ordinary
fine sand exhibited a dendritic form, a deep channel or gutter extend-

* The corner of the cover-glass was propped up with a few bristles.

f Included bubbles sometimes are surrounded by concentric bands of the finer
material, as if the bubble favoured a uniform evaporation.

220 Miss C. A. Raisin. On certain Structures formed

ing as an axis, and shallower narrower furrows forming the-
branches.

In materials which consist of very finely divided particles, the
variation in the size of the grains is too slight to produce any effect
and the result is a uniform pattern. Thus indigo generally forms a
typical example of a maze. If, however, the material is smooth and
oily, like gamboge, it is very slow in drying, and the general form
which it assumes is that of knobbed straight axes.

In powders of medium grain the difference in the size of the
particles causes marked effects (e.</., chalk, prussian blue, sepia, &c.)
If the mud is dense, drying uniformly, a mazy network is usually
formed. A thinner mixture may produce knobbed straight axes.
An intermediate condition in the drying mass gives rise to feathery
or fan shapes, or to parallel generally curving bars.

The mode of formation can be understood by tracing successive
stages, and by comparing different examples. When the water begins
to evaporate, the retreating edge of the film drags back the coarser
particles, leaving behind some of the finer material in a moist con-
dition. This afterwards dries, not however quite uniformly, so that
it is ranged in wave-like lines, between which clear spaces or uniform
thinner material may intervene. If the boundary is wide the lines
will be almost straight, if the margin is narrow they will curve with
smaller radius. The film of finer material, after retreating, some-
times advances again in a slightly different direction as was seen in
watching it, and two sets of curving lines are thus formed, which
partly cross one another.

Meanwhile as the thick film retreats, its rim becomes concave
between certain points. Then the boundaries of adjacent concavities
approach, and in this way the intervening material is gradually
reduced to a streak. Inequalities, however, exist within the film,
and, where coarser grains occur, or a clot adheres closer to the glass,
these scrape away the finer material, thus clearing paths and leaving
intervening streaks, which are radial, often curved and transverse to-
wave-lines. The clearer furrows may terminate at a knot of coarser
grains, when the force no longer suffices to move these back, so that
they remain isolated or form the initial knob of a thick stem. This
may extend as a straight axis, or, if the film of air broadens as it
indents and pushes back the muddy fluid, the curving margin may
form the beginning of a maze or network, such as was described
above.

Between the thick axes fine stuff is distributed on similar prin-
ciples to those which caused the forms near the edge. The two
dominant structures are the nearly parallel or concentric wave-lines
and the radial streaks. But in this case the finer material is
deposited within limited areas by which the forms are modified. If

in the drying of a Fluid with Particles in Suspension. 221

the wave-lines only are strongly marked, they may extend as curving
transverse bars ; if the radial streaks are the dominant feature they
form radiating curves or feathery or fan structures. A thick mass
in its final desiccation may show cracking like the hexagonal flakes
of mud at the edge of a pond, or the thick axes of a slowly drying
material (like vermilion) may be jointed transversely. Sometimes
stellate cracks may form within a mass, as in the example already
described (fig. 4).

4. Possible Applications.

We have now to consider the possible applications of these simple
experiments to structures which occur in Nature. Water, carrying
fine suspended material, will often penetrate into rocks along a plane
of discontinuity, and drying may then give rise to a " pattern." *

Istly. Dendritic forms upon joint or other surfaces are generally
regarded as the results of crystallisation, and this undoubtedly is
often the case, as frost spreads on a window pane. But if the
formation takes place under the constraint of a narrow space, it may
be caused simply by desiccation in the way described above. It will
not be easy in all cases to infer which has been the exact mode of
origin ; sometimes the angle at which the branches diverge in the
dendritic structure will prove that the formation was governed by
crystallising forces ; but it is clear that both conditions often may
co-operate.f

2ndly. If no cavity exists along the plane of weakness, and the
coarser axes are adherent and imbedded within the mass, they might
appear to represent tubular structures — to be, as it were, flattened
cylinders. In course of time the molecular and the mineral charac-
ter might be changed, and crystallisation even might take place
either in the original or the replacing substance. Is it not possible
that this may be the explanation of certain puzzling structures
sometimes placed as doubtfully organic, such as some of the so-called
" fucoid " markings, or the peculiar forms in certain limestones ? J

3rdly. These last speculations lead us to consider the possibility of
similar contractions taking place in space of three dimensions, as we
may call it, instead of two — in the mass of a rock, instead of along its
surface. Thus the principle governing the formation of the land-
scape marble, as described by Mr. B. Thompson, § presents some

* In some experiments I used surfaces of rock, and obtained results on a slab of
London clay, of slate, &c., only, as might be anticipated, the forms were coarser
and less regular than on smooth glass.

f See note by Professor Bonney appended.

J This is not intended to refer to the (Krvanella forms described by Mr.
Wethered (' Quart. Journ. Geol. Soc.,' 1890 to 1895, vol. 46, p. 270; vol. 47, p. 550 ;
vol. 48, p. 377 ; vol. 49, p. 236; vol. 51, p. 196) nor of necessity to Eozoon.

§ ' Quart. Journ. Qeol. Soc.,' 1894, vol. 50, pp. 393—410,

VOJ, LX1U. B

222 Miss C. A. Raisin. On certain Structures formed

similarity, although, there it is the rise of gas hindered by material
instead of the lateral spread of air, causing the retreat of the water-
film which opposes it. Many peculiar forms assumed by concretions
may be similarly explained.

The deposit of an opaline layer with cusped points around a cavity
might be caused by the uniform drying of a smooth, homogeneous
material. Modified by crystallisation, it might help in tbe formation
of agates and chalcedonic deposits.*

Igneous rocks have formed from a molten mass which may gene-
rally be considered (as pointed out by Lagorio) like a solution of the
less fusible in the more fusible constituents, or in some cases may
consist actually of two magmas imperfectly mixed. As it becomes
solid the two parts may mutually react in a manner analogous to
the phenomena already discussed. The forms shown in the secondary
silicification of certain rocks (e.g., cherts, silicified rhyolites, &c.)
perhaps afford another illustration. Though this process is not
exactly comparable with the deposits of sediment described above,
yet colloid silica might penetrate in different directions, and
encountering constant obstacles, give rise to an irregular, almost
felsitic structure.

4thly. In the specimens which show cracking and expansion of
cracks to canalsf or bubbles, we may see a resemblance to other
forms in igneous rocks (fig. 4). Some of the stellate or cruciform
cracks remind us of the kind of contraction which, in a semi-solidified
pyromeride, develops fissures and inlets, afterwards filled by chal-
cedonic or other deposits. Further, the grouping of cracks and
bubbles in the drying film of mud, imitating roughly some of those
found within spherulites, would suggest that in certain of these a
crust may be formed before their complete development. This would
accord with the view which Professor Bonney has often advanced, in
conversation with me, for certain Boulay Bay pyromerides,J and
with the hypothesis which seemed to be suggested by certain Welsh
pyromerides and variolites : § that the spherulite sometimes follows,
as it were, an initial formation of a nodule which has arisen by flow-
brecciation, or other process.

Thus it seems possible that in several points the simple forms I

* A comparison similar to that with the landscape marble might be made with
the process for the artificial formation of agates described by Messrs. J. I'Anson and
E. A. Pankhurst, ' Min. Mag.,' 1882, vol. 5, p. 34.

f Compare with these the branched canals in gelatin described by Professor
Sollas, as due to the formation of ice spicules (' Trans. Roy. Irish Acad.,' 1890,
vol. 29, p. 427).

J I believe that this view has the support of Mr. J. Parkinson, F.G-.S., but I
leave the sentence as it was written about two years ago (see ' Quart. Jo urn. Geol.
Soc.,' 1898, vol. 54, p. 101).

§ * Quart. Joum. Geol, Soc./ 1889, vol. 45, p. 268 j and 1893, vol. 49, p. 152,

in the drying of a Fluid with Particles in Suspension. 223

have tried to record may help to throw light on certain structures
and processes in rocks. Applying the principles we have noticed
here, we might anticipate (even where crystallising materials are
present) —

Istly. That mutual interactions may give rise to wriggling or
mazy forms.

2ndly. That greater freedom of molecular motion might cause
more rectilinear forms.

Srdly. That the relative ease of transmission in different sub-
stances or conditions of a substance may govern the forms developed,
as the difference between the coarser and finer sediment.

4thly. That the form of the external boundary influences the
structures developed, so that streaks normal to a rectilinear figure,
or radial within a sphere, are caused.

5thly. That much depends on the relative permeability of the
surrounding magma ; and the solidification in a molten mass, first
of an external crust, would act similarly to a more impenetrable
environment.

PART II.

To have fully discussed experiments in which any effect of crystal-
lising forces is shown would have unduly lengthened this paper,
and on that subject some material has been published.* My main
object is to call attention to the results of mere mechanical rearrange-
ment, on which I think no distinct notice is available. But I may
briefly refer to a few results of crystallisation. I experimented
with solutions of various salts, mixed with gelatin, with " muds "
of vermilion, &c., and in other combinations.

When solutions of calcium sulphate and of gelatin were mixed
in varying proportions, if the solution was weak, crystallisation
generally seemed to start at many scattered points. At these there
formed small crystals or ovoid grains (like potato starch-grains, of ten
compound) or clusters, frequently spherulitic. In the intervals was
a gelatinous-looking deposit, which had no effect on polarised light.

* H. Vater, in ' Zeits. fiir Kryst. und Min.,' 1892-6, vol. 21, p. 433 ; vol. 22,
p. 209 ; vol. 24, p. 366 ; vol. 27, p. 477. O. Lehmann, in « Zeits. fur Kryst. und
Min.,' 1877, vol. 1, p. 453. ' Q.uart. Journ. Micr. Sc.,' 1855, vol. 3, p. 179,
PI. 13, 14 ; and 1856, vol. 4, p. 203, PI. 12, by J. GUaisher; vol. 4, p. 201, by J.
Spencer ; 1861, vol. 1, n.s., p. 23, by Q-. Kainey ; 1862, vol. 2, p. 128, by T. Davies ;

1866, vol. 6, p. 137, by K. Thomas ; 1872, vol. 12, p. 118, by Professor Harting.
1 Roy. Soo. Proc.,' 3866, vol. 15, p. 314, by E. Montgomery. ' Trans. Brit. Assoc.,

1867, p. 127, by Dr. Heaton. ' Phil. Mag., 1878, vol. 6, p. 113, by F. Guthrie.
' Intellectual Observer, 1865, vol. 6, by H. N. Draper. ' Trans. Eoy. Micr. Soc.,'
1871, p. 50, by H. S. Slack. ' On the Influence of Colloids upon Crystalline Form,
&c.,' by Dr. W. M. Ord, 1879. ' Nature,' 1892, vol. 47, p. 162, by Dr. J. H.
Gladstone.

224 Miss C. A. Raisin. On certain Structures formed

As we add a larger amount of the salt solution, the following effects
were produced: first, the crystallised bodies all became larger;
more crystal-shaped grains formed, instead of the rounded blebs,*
and then, beyond an irregular, clear space around each, the ground
was occupied by a more distinctly dendritic deposit, which faintly
depolarised. In a more watery medium, the ovoid grains are more
marked. From a mixture of vermilion in a solution of the salt, the
results are similar, but the vermilion is in clots or lumps, or scat-
tered granules, with intervening, irregularly shaped spaces. In one
slide the clear spaces are rather definitely shaped and angular,
almost as if dominated by crystallising force, yet the crystallising salt
has formed only small, ovoid grains, clustered rather more thickly
near the central part of the space.

The formation of spherulitic structures has been described by
several authors. Good examples were obtained in these experiments
with sodium phosphate mixed with gelatin. A weak solution, or a
solution of the salt without the gelatin, gave spherulitic structures,
though these were small and scattered. From a stronger mixed
solution the deposit consisted of rounded, gelatinous-looking globules,
more or lesa aggregated, which, with crossed nicols, showed radiate
structure and a black cross. Radial tufts of acicular crystals of
calcium sulphate are well known among microchemical tests ;f
these were obtained from pure solutions of the salt, or from mix-
tures with " mud," or with gelatin. One small isolated drop (J inch
across) of a mixture of calcium sulphate solution and vermilion,
which dried on another slide, J exhibited spherulitic spheres or hemi-
spheres (their centres being on, or just within, the circumference of
the drop), clustered like those which have been obtained in a sheet of
glass which had been raised to a high temperature and then cooled. §

In other drops, where definite crystals were formed, the crystals
projected inwards, often with branched, almost dendritic, or skeleton,
growth. || If in certain spherulites a radial ingrowth of crystallites
takes place, as seems probable, it would be somewhat analogous to
this result of shrinkage or skin tension in the drop.

In certain examples, where a rather concentrated solution was

* Cf. H. Vater, ' Zeits. fur Kryst./ vol. 27, p. 489.

f " Notes on the Micro-chemical Analysis of Rock-making Minerals," by
Lieut.-General C. A. McMahon, F.G-.S. (' Min. Mag.,' vol. 10, p. 110). 'Manual
of Micro-Chem. Anal.,' Professor II. Behrens, p. 71.

% I failed to reproduce this structure again, although many variations in the
conditions were tried.

§ " Address of President," by Professor T. GK Bonney, ' Quart. Journ. Geol.
Soc.,' 1885, vol. 41. p. 63. ' Roy. Soc. Proc.,' 1885, vol. 39, p. 103, by D. Her-
mann and F. Rutley.

|| For the mode of growth and general form of the crj'stals, compare Lehmann
in ' Zeits. fur Kryst.,' 1877, vol. 1, PL 21, figs. 49, 50a PL 22, fig. 84.

in the drying of a Fluid with Particles in Suspension. 225

mixed with material in suspension (e.g., calcium sulphate and ver-
milion), a mass of crystalline grains, separated by clear, narrow
interspaces, occupy a definitely crystal-shaped area. The neigh-
bouring grains are related in form, the spaces between are bent or
curved, the whole resembling micropegmatitic or pegmatitic struc-
ture (fig. 5.)

In the formation of chiastolite and other secondary minerals, the
matrix is often partly included, but in these experiments the more fluid
medium apparently separated from the vermilion, thrust it to the edge
of an initial, crystal -shaped area, and within that formed crystalline
grains separated by interspaces. The grains generally depolarise
uniformly, but occasionally are built up of clustered prisms, and some-
times even of slender, tufted needles. Lehmann, in his classic paper,
describes the causes of irregular, or interrupted growth as due
mainly to the viscosity of the medium or the presence of foreign
substance .* He points to spherulitic and dendritic forms as results.
The micropegmatite seems to be one more possible development. f
This would agree with the hypothesis advanced by Professor Bonney,
that it results in igneous rocks, when the magma is kept at a some-
what persistent, but not too high, temperature ; so that the material
probably would be in a very viscous or partly solidified condition. J

While this paper was in progress, I received from Professor
Bonney the following interesting note (drawn up by him some years
ago),§ the more valuable as made upon one of nature's experiments.
The observation adds one more suggestion as to the possible forma-
tion of "pseud-organic" structures, that they might originate from
a mixture of mechanical sediment and of a crystallising salt, and
the forms in the mud might remain even if the salt were afterwards
dissolved.

The note is as follows : — " In walking along the pavements during
the late frost, before the sun or the feet of the public had produced
an effect, I was often struck with the forms of the ice crystals. v The
pavements were dirty ; much fine mud, brought from the roads on
the boots of pedestrians, had been pretty evenly distributed in a
thin film. During the night this had been arranged in rod-like
crystals, often 3 or 4 inches long. These formed groups, spreading
like the sticks of a partly opened fan. They were sometimes

* ' Zeits. fur Kryst.,' 1877, vol. 1, p. 453.

f Micropegmatite is closely related to the other forms.

£ " On a Contact Structure in the Syenite of Bradgate Park," ' Quart. Journ.
Geol. Soc.,' 1891, vol. 47, p. 107.

§ Of this note, written in December, 1892, an abstract was sent to ' Nature '
(December 15, 1892) by the author in corroboration of a letter, which had
appeared the previous week, from Professor Meldola, calling attention to the
same phenomenon. Several letters (from Dr. J. H. Gladstone and others) on the
same subject were printed at the same time. ' Nature,' vol. 47, pp. 125, 162.

R 2

226 Miss C. A. Raisin. On certain Structures formed

slightly curved,* perhaps about J inch in diameter, and | inch at
thickest. They differed from the ' frost ferns,' in a much greater
simplicity of structure, being more like little bunches of grass
arranged along a stem than those exquisite and intricate fabrics of
the ice-world. They reminded me sometimes of the groups of
actinolite crystals in certain crystalline schists, as for instance at the
St. Gothard. These actinolites, on examination under the microscope,
prove to be not pure crystals, but much interspersed with granules
of pre-existing minerals. It occurred to me that the probable
reason for the formation of these ice structures was the impediment
offered by the small grains in the mud to the growth of tiny crystals.
Only here and there, where circumstances were exceptionally favour-
able, a crystal larger than usual would be developed, which, as it
advanced, gathered to itself other crystalline molecules. Thus
would be started a bunch of coarse crystals, springing from a common
centre, growing more easily in the direction of the axis of the
rhombohedron, just as in the case of frost ferns, but they would be
simpler, coarser, and arrested by the impediments, instead of delicately
flexured by the almost imperceptible inequalities of the glass.

" I obtained on a later morning, strong confirmation of this view.
Heavy rain fell all through the preceding day, followed by a clear
night, with a ground-frost. In many places the pavements had
been washed very clean. On the clean paving stones I saw, not
unfrequently, early the next morning, fairly delicate frost ferns
(though not equal to those on glass). Where the surface had been
a little dirty, the forms were less intricate and coarser; in some
rather dirty places the old types could be seen.

" Postscript. — What is written here was my impression at the time,
but I have since doubted whether the crystals were not ' muddier'
than the part around. It was not possible to examine the pavement
very closely ; also I noticed on a later occasion that the trampling of
the film of mud (prior to freezing), which produced a kind of con-
centration in an irregular network of wavy lines or bands, appeared
to have something to do with the formation of the flowers."

This note suggests that analogous processes may be traced in
schists, like those of the St. Gothard, and the mode of formation of
certain crystals in schists has been described in papers already pub-
lished.f On this point, however, it is needless to enlarge, as we may
hope to receive more results, since Professor Bonney has communi-
cated a paper dealing with this subject to the Geological Society.

* Similar forms were noticed on certain days in the winter, 1896-7.

f " On a Secondary Development of Biotite and of Hornblende in Crystalline
Schists from the Binnenthal," by Professor T. Gr. Bonney, ' Quart. Journ. Geol.
Soc.,' 1893, vol. 49, p. 104. Also " On some Schistose Greenstones, &c.," by the
same author, ibid., p. 94.

RAISIN.

EOT. Soc. PROG., VOL. 63, PLATE 2.

Fm. 4.

Fia. 5.

in the drying of a Fluid with Particles in Suspension. 227

EXPLANATION OF FIGURES (PLATE 2).

The results shown in figs 1 — 4 were obtained on glass plates, about 6 inches
by 3 inches, with cover- glasses about 3 inches by 2 inches. The whole pattern is
represented in figs. 1 — 3, but fig. 4 shows a small part only of one slide (magni-
fied). In each experiment a drop of the mud was placed on the slide, and then
covered, so that the mud spread out somewhat irregularly. In other examples
similar results were obtained, after running in material or keeping up a current
for a short time to carry the mud along.

FIG. 1.

Prussian blue in water. This was placed on the glass as a large drop, and a
very small one was accidentally deposited near by, in which the pattern at a has
been developed. The mud in a few minutes began to show indication of the
future pattern. Very shortly the film retreated from two edges (a and 5), where
the mud was " denser," and where it dried to a coarse maze. Afterwards the fine
maze formed, and was completely developed in two or three days.

FIG. 2.

Chalk mass, somewhat thin ; tilted so that the cloudy chalk gradually flowed
down. In this pattern the rods tend to become straighter, connected by curved
transverse bars.

(A pattern from denser chalk in several cases, not figured, was that of a coarse
maze.)

FIQ. 3.

Prussian blue. The fine pattern near one edge (a) with concentric or wave-
lines, and some clearer radial furrows was first developed. Then coarser bent
stems were deposited, and towards the further margin these became smaller,
interrupted, and finally reduced to isolated spots, while the fine material formed
rather feathery tufts (less distinct in the photograph). Dried in about two days.

FiG. 4 (x 8 diameters).

From a large slide of Vandyke brown, which formed straight axes and a fine
c< wave " pattern (an indication of this is shown at one side of the figure). Part
of the edge " caked " in drying, and within it, bubbles developed, often elongated
transverse to the margin, and stellate cracks or series of cracks. Fine material,
somewhat faintly marked in the figure, has formed roughly oval-shaped patches in
the vesicles or a central streak in the cracks.

Note. — Certain sharp lines, partly overlapping the pattern in figs. 3 and 4, mark
the edge of a film of Canada balsam, by which the cover was sealed down.

FIG. 5 ( x 25 diameters).

Mixture of a solution of calcium sulphate and vermilion dried on an ordinary
microscope slide beneath a cover-glass.

The figure represents parts of two long skeleton crystals of calcium sulphate (a
and 5) in which a micropegmatitic structure has formed. A small part of a third
crystal (c) is shown, the substance of which extends more continuously. The
vermilion partly borders the edges of the large skeleton crystals, and is black and
opaque in the figure. Other black patches in it are composed of aggregated
crystallites of calcium sulphate with some vermilion. The fine scattered lines or
radial tufts are similar crystalline needles of the salt.

228 Mr. H. M. Vernon. The Relations between the

"The Relations between the Hybrid and Parent Forms of
Echinoid Larvae." By H. M. VERNON, M.A., M.B. Com-
municated by Professor RAY LANKESTER, F.R.S. Received
March 29,— Read May 5, 1898.

(From the Zoological Station, Naples.)
(Abstract.)

The object of this research was to determine systematically during
a period of several months' duration, the exact relationship of structure
and size existing between certain hybrid and parent Echinoid larval
forms. Eight different species of Echinoids were worked with, but
the larger number of observations were confined to three of them,
viz., Strongylocentrotus lividus, SpJicerechinus granularis, and Echinus
microtuberculatus. The method of procedure was similar to that
described in a former paper.* It consisted in shaking pieces of the
ovaries and testes of the various Echinoids in small jars of water,
and then mixing portions of the contents. In the cross-fertilisations,
precautions were of course taken to prevent any accidental direct
fertilisation of the ova. After standing an hour, the now fertilised ova
were transferred to large jars of water, holding, as a rule, 2 to 3^
litres. Here they were allowed to develop for eight days, when the
plutei formed were killed, preserved, and examined under the micro-
scope. The structure of the hybrids, in relation to that of the parent
forms, was studied ; and all the larvae, both pure and hybrid, were
measured by means of a micrometer eye-piece in respect of their
body length and anal arm length. Fifty larvae were, as a rule,
measured in each case. In addition, the ova were examined under
the microscope twenty-four hours after fertilisation, and the numbers
of blastulae and unfertilised ova in a given volume of water counted.
Again, after eight days, the number of plutei surviving was similarly
estimated.

Upon the cross SpJicerechinus ? Stronyylocentrofus <?, twenty-two
experiments were made. As a rule only about 10 per cent, of the ova
were fertilised, and only 1 per cent, of them reached the eight days
pluteus stage. The hybrids were most easily obtained in the summer
months, few or none of the ova being cross-fertilised in the winter,
unless the aids to fertilisation made use of by O. and R. Hertwig,t
and by Born,J were adopted. Thus the former observers showed
that if the ova were shaken in water and kept some hours, so that
their vitality became diminished, they underwent cross-fertilisation

* ' Phil. Trans.,' B (1895), p. 577.

f ' Jenaische Zeitschrift f. Medicin,' vol. 19, p. 121 (1886).

J ' Pfliiger's Archiv,' vol. 32, p. 453.

Hybrid and Parent Forms of Echinoid Larvce. 229

much more readily than when freshly shed. Born, on .the other hand,
found the cross fertilisation could be increased by increasing the
amount of sperm added. Both methods, but especially the former,
were found of value in the present research.

As regards the structure of the hybrids under discussion, it was
found that the majority of those obtained in May, June, and July
were of an almost pure Sphcerechinus type, only a third or less of
them being of an intermediate or Strongylocentrotus type. In
November, on the other hand, only about a sixth were of the maternal,
and five-sixths of the paternal type. Finally, in December and
January, all the hybrid larvae were of the paternal type. These
latter larvae in almost all cases showed obvious traces of their hybrid
origin, but they were evidently much more inclined to the Strongy-
locentrotus than to the Sphcerechinus type. Thus the body skeleton
was like that of Strongylocentrotus, only it generally had a few
abnormal projections springing from it. It was also, as a rale, about
25 per cent, shorter. The anal arm skeleton generally consisted of
two rods, but there were very seldom any cross bars joining them,
such as occur in Sphcerechinus larvae.

On the reciprocal cross of Strongylocentrotus ? and Sphcerechinus $
eighteen experiments were made. During April, May, and June a
fair number of the ova were cross-fertilised, but no plutei were
obtained. In July and August some 47 per cent, of the ova were
fertilised, and 29 per cent, of them survived to the eight clays pluteus
stage. In November and December, on the other hand, with one
exception, not only were no plutei obtained, but as a rule not a
single ovum was cross-fertilised. The hybrid larvas themselves were
of the pure Strongylocentrotus type, but in one instance the arms of
the larvae were very much longer than had ever been noticed in any
other case. These hybrids appeared therefore to be of the nature of
sport.

These extraordinary variations in the capacity for cross-fertilisa-
tion seem to be due to the variations in maturity which the sexual
products undergo with change of season. Thus in the summer
months most of the Strongylocentrotus individuals contain but very
small quantities of ripe sexual products, or none at all. Also from
the fifty different series of observations made on normal Strongy-
locentrotus larvae, it appeared that the size of the larvae kept at the
maximum from the beginning of April till the beginning of May,
but then began to dwindle down, so that at the beginning of July it
reached its lowest level. The larvae were now sometimes 30 per cent,
smaller than the spring larvae. After the middle of August they
gradually increased again, and by the end of November had attained
their maximum size. Sphcerechinus larvae, on the other hand, kept at
about the same size throughout the year, though considerably

230 Relations of Hybrid and Parent Forms of EcMnoid Larvce.

smaller numbers of the ova reached the pluteus stage in the summer
than in the winter months. We see therefore that the Strongylocen-
trotus ?-Spha3rechinusc? hybrid is only formed at the time when the
Strongylocentrotus ova have reached their minimum of maturity ;
ivhilst in the case of the reciprocal hybrid, it follows that as the
maturity of the Strongylocentrotus sperm increases, it is able to trans-
mute first a portion and then the whole of the hybrid larvae from the
Sphaerechinus to its own type. In other words, the characteristics of
the hybrid offspring depend directly on the relative degrees of 'maturity
of the sexual products.

As a result of the ten experiments made on the cross Echinus ? -
Strongylocentrotus <? , it was found that the hybrid larvae were on an
average about 8 per cent, larger than the pure parental larval forms,
and, moreover, that even more of the cross-fertilised ova developed to
plutei than of the directly fertilised ones. The hybrid larvaB were of
a variable, but more or less intermediate, type. In the reciprocal
cross, on the other hand, only a small proportion of the ova under-
went fertilisation, and only about 1 per cent, of them reached the
pluteus stage. These plutei were on an average 13'2per cent, smaller
than the pure maternal larvae. In structure they were of a Strongy-
locentrotus-inteYmedi&te type.

Hybrids between Sphcerechinus ? and Echinus c? were obtained
on only two occasions. The larvae were of a very variable Echinus-
intermediate type, and were much dwarfed. In the reciprocal cross,
hybrids were also obtained only twice, but then about 60 per cent, of
the ova reached the pluteus stage. These hybrids were of the pure
Echinus type. On most other occasions a small number of the ova
were cross-fertilised, but failed to develop to plutei.

Hybrid larvae, of the maternal type, were obtained on crossing
Arbacia ova with Strongylocentrotus and with Echinus sperm, but
with Sphcerechinus sperm only gastrulae resulted. Hybrids were also
obtained between Arbacia $ and Strongylocentrotus, Sphcerechinus,
and Echinus ? . These hybrids were of the maternal types, but in
some of the Sphcerechinus hybrid larvae the anal arm skeletons were
similar to those in pure Arbacia larvae.

Hybrid larvae were obtained between Echinocardium cordatum $
and Strongylocentrotus, Sphcerechinus, Echinus, and Arbacia <$, the
larvaa being of the maternal type, but somewhat modified by the
nature of the sperm. The hybrids between Echinocardium
mediterraneum ? and Strongylocentrotus and Echinus <$ were of an
intermediate type ; hence, one is afforded a physiological argument
in favour of the specific difference of these two forms, the existence
of which has hitherto been considered rather doubtful.

Hybrid larvae of the maternal type were obtained on crossing
Strongylocentrotus ? with Dorooidaris $ , but the reciprocal cross

Meeting of May 12, 1898. 231

yielded only gastmlae. Finally, hybrids, of a presumably inter-
mediate character, were obtained from the cross .Echinus microtuber-
culatus ? and Echinus acutusg . With the ova of Sphcerechinus and
Echinocardium, and the sperm of Echinus acutus, only gastrulae were
obtained.

On performing cross-fertilisations with the colour varieties of
Sphcerechinus, there was found to be a distinct diminution of fertility.
In the most marked instance, obtained in the experiments made on
June 2, it was found that when white-spined varieties were fertilised
with white-spined, and violet-spined with violet, 98' 5 per cent, of
the ova reached the blastula stage, and 73 per cent, the eight days
pluteus stage. But on cross-fertilising white-spined with violet-
spined individuals, only 68 per cent, of the ova developed to
blastulee, and 15'6 per cent, to plutei. Also these crossed larvae were
4'5 per cent, smaller than the uncrossed. Other series of experi-
ments were made in July, November, and December, the differential
fertility seeming to gradually diminish with the progress of the season.
Nevertheless, it was always most distinctly present. On crossing the
less definitely marked colour varieties of Strongylocentrotus, a small
amount of infertility seemed to be present in one series of experi-
ments, but none at all in another.

May 12, 1898.
The LORD LISTER, F.R.C.S., D.G.L., President, in the Chair.

Professor Dewar made a preliminary communication " On the
Liquefaction of Hydrogen and Helium."

He prefaced his statement by referring to a letter which he had
addressed to the President on the lOfch May, announcing to him the
fact that he had succeeded in liquefying hydrogen in quantity, and
that by means of the liquid hydrogen he had also liquefied helium.

The following Papers were also read : —

I. " On the Magnetic Susceptibility of Liquid Oxygen." By Pro-
fessor FLEMING, F.R.S., and Professor JAMES DEWAR, F.R.S.

II. "A Study of the Phyto-Plankton of the Atlantic." By GL
MURRAY, F.R.S. , and Y. H. BLACKMAN.

III. " The Electric Response of Nerve to a single Stimulus investi-
gated with the Capillary Electrometer. Preliminary Com-
munication." By Professor GOTCH, F.R.S., and G-. J. BURCH.
VOL. LXIII. s

232 Dr. W. Marcet,

IV. " Effects of prolonged Heating on the Magnetic Properties of
Iron." By S. R. ROGET. Communicated by Professor EWING,
F.R.S.

V. " On the Connection of Algebraic Functions with Automorphic
Functions." By E. T. WHITTAKEB. Communicated by Pro-
fessor FORSYTH, F.R.S.

The Society adjourned over Ascension Day to Thursday, May 26.

"A Calorimeter for the Human Body." By WlLLIAM MARCET,
M.D., F.R.S. Received March 10,— Read April 28, 1898.

(From the Physiological Laboratory, University College, London.)

At the meeting of the Physiological Society held at University
•College in March, 1897, I exhibited and described a calorimeter con-
structed for the purpose of determining the heat given out by man.
'Several members of the Society, in succession, allowed themselves to
foe shut up in the chamber where they experienced no discomfort
whatever. The instrument was also described the same year to the
;Societe de Physique et d'Histoire Naturelle of Geneva, but no full
account of it has been published so far.

The first calorimeter for the investigation of animal heat was made
"by Lavoisier and Laplace,* who enclosed an animal in a chamber
rsurrounded with ice and determined the heat evolved by measuring
-the amount of ice melted. Crawford, in 1788, placed the air chamber
inside a water-jacket, and determined the heat emitted by means of
-the increased temperature of the water. An objection to this
iype of calorimeter is the very small rise in the water temperature,
and the difficulty of obtaining an uniform temperature in such a large
volume of water. J. Rosenthal,f in 1878, introduced a calorimeter
in which the heat given out from a small animal was absorbed by a
fluid with a low boiling point, such as ordinary ether, the amount of
heat was calculated from the volume of the fluid evaporated and its
known latent heat of vaporization.

RosenthaljJ at a later date, constructed a calorimeter, which con-
sisted of three concentric chambers of sheet copper, and was made
in duplicate; the two instruments were connected by means of a
U-shaped manometer. The heat given out by an animal, such as a
-dog, enclosed in the innermost chamber of one of the instruments,

* * Memoires de 1'Acad. des Sciences,' 1780.
f ' Archiv f. Anat. u. Physiol.' (Physiol. Abthg.), 1878, p. 349.
j C. Kosenthal, 'Arch. f. Anat. u. Physiol.' (Physiol. Abthg.), 1888. p. 1; J.
JRosenthal, ibid., 1889, pp. 1, 23, 39.

A Calorimeter for the Human Body. 233

was communicated to the middle chamber, and from the position of the
meniscus in the manometer, the initial temperature of the experiment
and the barometric pressure, the heat emitted in a given time was
indirectly calculated.

Experiments were made on man with a modified form of this
instrument by enclosing an arm in one of the two inner chambers.
Hirn* investigated the heat emitted by man by making use of a
wooden chamber in which he had previously ascertained the rate of
loss of heat through its walls. This was done by burning a known
volume of hydrogen gas within the chamber until the temperature
became constant, and then determining the heat lost per unit of
time, from the known volume of gas burnt. This method at first
sight commended itself by its simplicity, but was open to two objec-
tions— the first that it was an indirect method of inquiry, the second
that the person under experiment was unavoidably subjected to a
high temperature.

In 1889 Bichetf published an elaborate investigation on animal
heat, in which he made use of a calorimeter constructed in such a
way that the heat emitted by an animal in a closed vessel displaced
by pressure a volume of water equal to the expansion of the air in
the calorimeter.

An ingenious animal-calorimeter was constructed lately by Messrs.
J. S. Haldane, W. Hale White, and J. W. Washbourne.J These
gentlemen determined the heat given out from an animal, by com-
paring the pressure resulting from the expansion of the air in a
closed jacketed space surrounding the chamber containing the
liinal, with the corresponding expansion produced by the burning
)f a known volume of hydrogen gas in another similar vessel. The
amount of gas burnt is regulated with a stopcock, so that its heat
should correspond exactly with that produced in the other chamber

indicated by a differential manometer. The heat emitted is equal
to that of the combustion of the gas burnt.

Messrs. W. O. Atwater and E. B. Rosa, of Connecticut, U.S.,§
have quite recently measured the heat emitted from a person by
placing him in a large calorimeter, where he lived for periods of from
one to twelve days. The walls of the chamber were double, and
made of sheet copper and sheet zinc, while the heat generated was

* " La Thermodynamique et 1'etude du travail chez les e'tres vivants," ' Revue
Scientifique,' 1897. ' Kecherches sur 1'lSquivalent mecanique de la Chaleur.'
Colmar, 1858, pp. 51, 95. ' Exposition analytique et experhnentale de la Theorie
mecanique de la Chaleur.' Paris, 1875, p. 35.

t " La Chaleur animale," par Ch. Eichet, ' Bibl. Sc. Internat.,' 1889.

J ' The Journal of Physiology,' 1894, p. 123.

§ " An Apparatus for verifying the Law of Conservation of Energy in the
Human Body/' Brit. Assoc., 1897, Toronto, Trans, of Sec. A (General Physics).

s 2

234 Dr. W. Marcet.

carried away by a stream of water ; according to the authors, tests
showed this calorimeter to be very accurate.

The construction of the present instrument was suggested from
Berth elot's calorimeter, for the determination of specific heat by
mixtures, in which the heat given out is reflected by bright surfaces
of silvered copper surrounding at a short distance the vessel con-
taining the mixture. It was found, however, in experimenting with
the new calorimeter (which was not silvered inside), that all the
heat was not reflected, a certain proportion being absorbed by the
copper, which necessitated an arrangement for determining the
temperature of the metal.

The instrument (see figure) consists of a wooden chamber lined
internally with a thick padding of cotton wool, and externally with
several thicknesses of felt. Inside this chamber there is another
made entirely of sheet copper, the inner surface of which is main-
tained carefully polished ; its height is 145 cm., and its breadth is
69 cm. The two chambers have between them an annular space
from 4 to 5 cm. in breadth. The capacity of the copper chamber,
empty, is 81O4 litres, and its weight 62'370 kilograms, therefore an
alteration of 1° C. in the temperature of that mass of copper would
be equal to 5832 (small) calories, or would raise 5832 grams of
water 1° C.

The copper chamber is closed by means of a movable panel also
constructed of copper, which is fixed to a wooden backing ; the edge
of the copper panel is made to press tightly against an india-rubber
cushion carried round the rim of the opening in the copper chamber,
while the edge of the wooden backing is applied against the rim of
the wooden chamber, and the panel is kept in its place firmly with
brass screws. This movable door is too heavy to be handled easily
by one man, and on that account is fixed to a tackle fastened to a
beam in the roof of the laboratory, by which means no difficulty is-
experienced in opening or closing the chamber.

There is a small window 21 x 15 cm., made of two superposed
panes of very thick glass, and opening into the two chambers ; when
closed, the rim of the inner pane presses against a cushion around
the corresponding opening in the copper chamber; it shuts by a
spring bolt, and should the person under experiment feel uncom-
fortable, or wish to communicate with the outside, he can push open
this window at any time.

Inside the copper chamber there are two ventilators, or perhaps
more correctly " agitators," in the form of revolving fans, the object
of which is to thoroughly mix the air inside the chamber. One of
these agitators is fixed high up in the chamber, the other low down
on the opposite side. The upper agitator was found experimentally to
produce a blast of 190 litres per minute — say about 380 litres per

;

A Calorimeter for the Human Body.

235

minute for the two; nearly the whole of the air in the chamber
would be carried through the two agitators every two minutes.* The
number of revolutions of the fans recorded by counters amounts
together to two or three hundred thousand per hour.

The motor power for working the fans is obtained from the wires
used for the electric light of the laboratory, and exerted through two
small dynamos — one for each agitator, while the action of either one
or the other can be regulated by a carbon-resistance.

* The resistance caused by the ice, and a rose jet on the track from the lower
agitator, would probably reduce the draught to some little extent j no doubt, how-
ever, that the air is very thoroughly mixed inside the chamber.

236 Dr. W. Marcet.

The upper agitator is disposed in such a way as to drive the air of
the chamber through a mass of ice roughly broken up, and held in a
cylindrical tin vessel open at the top, suspended from the roof of the
chamber. The cold air having from its increased density a tendency
to fall, is taken up by the lower ventilator and driven upwards ; by
such means a circulation of the air in the chamber is maintained
through the ice-holder. Should the temperature of the chamber rise
during the experiment, by increasing the draught through the ice
more ice is melted and the rise is checked ; the reverse holds equally
good.

The ice used for absorbing the heat emitted by the person under
experiment delivers its water into a flask holding a thermometer
divided into fiftieths of a degree centigrade ; the flask and ther-
mometer are both weighed. The flask hangs from a hook on the
side of a tube projecting from the bottom of the ice-holder.

Besides the thermometer in the flask, there are three other ther-
mometers all centigrade, also divided into fiftieths of a degree,
connected with the calorimeter ; the bulb of one of them projects
into the copper chamber while its stem is carried outside above the
wooden chamber ; a second has its bulb fastened down to the side of
the copper chamber by means of a strip of copper which covers it
entirely, its stem also projecting outside ; the third thermometer
is passed through the wooden chamber into the annular space, whose
temperature it shows during the experiment.

The successive stages of an experiment are as follows : — the heat
emitted from the body is first rapidly distributed throughout the
chamber, then it is absorbed by the mass of ice, reappearing in
measurable form as water. Knowing that 79 calories are required
for melting 1 gram of ice, the total calories corresponding to the
ice melted are easy to calculate.

Some of the heat emitted falls upon the brightly polished surface
of copper of the chamber, most of it is reflected into the chamber, but
a certain proportion becomes absorbed in the metal, and is determined
by the thermometer attached to the walls of the chamber. Perhaps
a very small amount passes through the copper walls into the
annular space, it might have been neglected, but has been taken into
account in every experiment. A number of experiments showed
that the copper was equally heated in every part, or very nearly so,
while the test experiments made with hydrogen gas placed that
question quite at rest.

The thermometers were generally read and the readings recorded
every ten minutes, the temperature of the copper being used as a
guide towards the maintenance of a constant temperature through-
out the instrument.

It will be readily understood that a difference of as much as 1

I

A Calorimeter for the Human Body. 237

at the end of the experiment in the temperature of the air of the
copper chamber was not of great moment from the low specific heat
of air ; indeed, such a difference would only yield 214 calories, which
is but trifling on say, 90,000 calories given out in one hour. On the
other hand, a slight difference in the temperature of the copper
proved of importance on account of the mass of metal.

There was no difficulty, however, in maintaining the temperature
of the copper within 0'3° or 0'4° of its original reading before the
experiment. Should it accidentally run up beyond that figure, a
very rare occurrence, this only lasted a minute or two, and by
increasing the blast through the ice, the temperature of the copper
was soon brought down to its initial reading. A similar remark
applies to falling temperatures of the copper ; by stopping the
draught through the ice they soon rose to the initial reading. Of
course, constant attention to the temperatures was required during
the whole experiment, which, with but few exceptions, lasted one
hour.

There remained, however, a serious difficulty to contend with,
owing to the heat produced by .the action of the ventilators or
agitators.

At first the friction of the bearings on which the fans rotate was
thought to be the main cause of this heat ; and, in consequence, their
position was altered so as to be placed entirely outside the wooden
chamber. This, however, failed to mend matters, and it became
evident that the friction of the revolving blades against the air was
the source of the heat produced. The only method of overcoming
the difficulty was to determine the heat produced exclusively by the
agitators and subtract it from the total heat obtained in each experi-
ment.

It was now found necessary to introduce counters registering the
number of revolutions for each of the ventilators up to 1,000,000
turns. The inquiry necessitated by the ventilators (say agitators)
took up a considerable portion of the winter 1896-97.

These experiments were carried out exactly in the same way as
those made on the living body, with this difference, that while from
10 to 15 Ibs. (4'5 — 6'8 kilograms) of ice were wanted when a human
subject was under experiment, from 500 to 800 grams of ice only
had to be used with the agitator experiments. The following is the
result of one experiment taken at random amongst a great many
others : —

Initial . . .

Chamber.
. . . 15-59°

Annular space.
. 15-50°

Copper.
15-35°

Final . . .

. . . 15-55

15-52

15-50

-0-04 +0-02 +0-15

238 Dr. W. Marcet.

Weight of ice melted 97'46 grams.

T. water from ice 10'92°

Calories recovered.

From melted ice + 7699

„ heat absorbed in water .... + 1064
„ „ of air in chamber .... —9

,, ,, air in annular space . . + L

„ „ copper (of chamber) . . + 875

9630
(9 subtracted)

Number of revolutions of agitators 342,305

342,305' = 11717....

Unfortunately the heat produced by the revolving fans was not
found to be exactly proportional to the number of revolutions, or
rather squared revolutions, although the figures approximated to each
other much nearer on the same day than on different days. It was
therefore decided to make two* preliminary experiments with the
agitators on the same day as each calorimeter experiment, and to
subtract the agitator calories from the total calories obtained. As
the number of revolutions was not exactly the same in the test
experiments and in calorimeter experiments, the calories for correc-
tion were calculated in proportion to the revolutions in the test
experiment, of course previously squaring the revolutions.

The following table shows in calories the heat produced by the
ventilators during forty minutes from a few experiments, the number
of revolutions is about 230,000, and the calories are calculated for
200,000 :-

On 200,000 Eevolutions.
Date. Calories. Means.

4th January, 1897 6866

5974

8th ' 2S}

•

10th 5323™,

5551

49011

4658 /

14th „ 61201

5956 >6434
6463 J

* When time was pressing only one was made.

A Calorimeter for the Human Body.

239

From these experiments the mean error is 218 calories, or on, say,
70,000 (emitted in forty minutes) = 0'3 per cent.

I now felt able to rely on the work undertaken with the calori-
meter ; still the instrument had to be tested, and with this object it
was applied to the determination of the heat lost by a jar holding
6 or 7 litres of hot water and comparing the heat recovered with the
heat lost by the water ; the calorimeter was also used towards the
estimation of the heat produced by the combustion of a known
volume of pure hydrogen gas, comparing the heat recovered with
that known to be produced by the combination of that volume of gas
with oxygen, and this work I undertook in conjunction with
R. B. Floris, F.C.S.

The first set of experiments with hot water proved very trouble-
some. It was found necessary to mix the layers of water in the jar
before and after the experiment, and to read correctly and quickly a
thermometer registering up to 0*02 of a degree centigrade ; more-
over the loss of heat could not be determined while the jar was being
carried to and shut up in the calorimeter ; and a similar difficulty
was experienced on removing the jar from the calorimeter at the end
of an experiment. Notwithstanding these many causes of error, as
will be seen in the following table, the mean of the results approxi-
mated very closely to the calories calculated from the loss of heat of
the water.

If, for instance, the jar contained 6 litres of water or 6000 grams,
and lost 10° of temperature in the calorimeter, say, from 75° to 65° C.,
then 60,000 calories, with slight corrections for the specific heat of
water at that temperature, and the thermal capacity of the jar, would
have to be found in the calorimeter.

These experiments are tabulated as follows : —

Difference.
— 1'74 per cent.
-8-04 „
+ 1-15 „
+ 0-49 „
-M5 „
-1-66 „
+ 4-66 „
-1-04 „
+ 3-87 „
-4-88 „

Calories lost

Calories found.

by radiation.

57,451

58,468

49,345

53,659

61,760

62,480

59,432

59,141

60,383

61 ,085

63,323

64,392

63,226

60,410

65,882

66,575

61,873

59,566

63,016

66,250

51,940

55,033

-5-62

Mean.. 59,785

60,642

-1-41

240 Dr. W. Marcet.

Although there was in one case as much as 8*04 per cent, differ-
ence between the calories found and the calories lost from the jar,
still the mean of the eleven experiments differs only by 1*41 per
cent., which is a near result considering the difficulty of the experi-
ment.

The determination of the heat produced by the combustion of
hydrogen was certainly a more satisfactory method than the former
for testing the calorimeter ; hydrogen was prepared for the purpose
in the usual way by the action of sulphuric acid on zinc, the gas
being purified through solutions of potassium hydrate and cupric
sulphate, and collected over water in a bell-jar carefully graduated.
The receiver was supplied with a gauge, showing the pressure to
which the gas was subjected, and a thermometer ; from 20 to 29 litres
of gas were used in each experiment.

After making the required preliminary essays with the agitators,
the experiment was proceeded with as follows : —

First of all it was necessary to find out and to adjust carefully the
speed of the gas delivery, and with that object a weight was placed
on the bell-jar, while the rate of issue of the gas was regulated at
will by means of a screw clamp on the track of the gas tube.* In
that way the speed of the gas delivered was adjusted so as to produce
on burning about the same heat as a person would emit in the calori-
meter in a given time.

The delivery tube led from the bell- jar into the calorimeter
through a fixed metal tube carried across the walls of the two
chambers of the calorimeter, its end being connected with a suitable
burner ; when lighted, the gas burnt with but a very small flame.

Before commencing the experiment the tube was rinsed out with
hydrogen and the thermometers were read, together with the pointer
on the scale of the bell-jar. Then the gas was turned on and
lighted, the vessel containing the ice hung in position, the stop-
watch started, the calorimeter closed, and the agitators put in
motion. Of course every care was taken to keep the temperature of
the calorimeter constant, which was done without any difficulty, the
temperature of the copper varying seldom by more than 0'1° or 0*2° C.

When forty minutes or an hour had elapsed (mostly forty minutes),
the temperatures were read, the gas turned off, and the agitators
stopped. Next the calorimeter was rapidly opened, and the flow of
water from the ice to the flask arrested ; the temperature of the ice
water was then read off, these various operations being carried out
as rapidly as possible. It was necessary to determine the heat
absorbed by the burner, which was done by plunging the burner,
immediately after turning off the gas, into 200 c.c. of water at a

* The gas was carried as much as possible through glass tubing, in order to
avoid the loss by diffusion through india-rubber.

A Calorimeter for the Human Body. 241

known temperature and determining the rise of temperature of the
water; the burner was found to absorb 300 calories during the
experiment. The pointer showed on the scale of the bell-jar the
volume of hydrogen burnt, and the gauge the pressure the gas was
under in millimetres of water, while a thermometer gave the tem-
perature of the gas in the bell-jar, and a barometer the atmospheric
pressure ; the hydrogen gas was of course saturated with water
vapour. Hence we were in possession of every data for the reduc-
tion of the gas to the dry state, to 0° C., and 760 mm. pressure.

In the early experiments it did not occur to us to analyse the
hydrogen gas in order to ascertain its degree of purity, but we did
so subsequently, using for that purpose the eudiometer constructed
by one of us (W. M.), which for several years has been exclusively
adopted in this laboratory for the determination of oxygen in expired
air ; the analysis of the gas introduced but a very slight correction.
The following table gives the results of the experiments we made on
the heat emitted by the combustion of a given weight of hydrogen
gas. It might be added that the machine known as " Brunsviga "
was used for the calculations, which saved much time and trouble ;
by this means the whole of the calculations could be completed in
about fifteen minutes.

Favre and Silbermann find 1 gram of H to give in burning 34,462
calories.

Found. Difference.

1 33,334 3'26 low per cent.

2* 33,159 3-78 „

3* 35,291 2-41 high „

4 35,186 2-10 „

5* 34,212 0-73 low

6* 35,610 3-33 high „

7 33,923 1-56 low

8 34,079 1-11 „

9 34,440 0-06 „

10 35,048 1-70 high

Mean.... 34,428 O'lO low

Favre and Silbermann 34,462

Marcet and Floris 34,428

34 = O'l per cent.

The present result is certainly convincing, and these figures are
plain statements of all the experiments we made. The greatest

* In these experiments the hydrogen gas was not analysed ; it was analysed in
all the others and the correction therefrom introduced.

242 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

difference is only one of 378 per cent., and the mean difference did
not exceed 34 calories on 34,462, amounting- to O'l per cent. only. It
may therefore be concluded that the present calorimeter has proved
itself very accurate for the determination of the heat produced by
the combustion of a given volume of hydrogen gas ; and, conse-
quently it can be accepted as equally reliable for the correct estima-
tion of the heat radiated from the human body or from that of a
fairly Jarge animal.

" An Experimental Enquiry into the Heat given oufc by the
Human Body." By W. MARCET, M.D., F.R.S., and R. B.
FLORIS, F.C.S. Received March 10,— Read April 28,
1898.

(From the Physiological Laboratory of University College, London.)

Dr. Marcet's calorimeter having been fully described in the previous
paper, the present conjoint authors now submitted themselves to
experiment, one of them remaining shut up in the chamber, usually
for the space of an hour, while the other was engaged outside to
regulate the temperature of the chamber and note the readings of
the thermometers.

When breathing was carried on inside the calorimeter, it might
be thought that the air of the chamber became too full of C02 or too
deficient in oxygen for the purposes of respiration. Such, however,
was not the case, and no discomfort whatever was experienced in the
course of an hour's incarceration. It is easy to calculate from a con-
sumption of, say, 26'488 grams of O per hour that supposing the
calorimeter to be absolutely air-tight, a condition which was not
actually realised, there would be a fall of oxygen, after one hour
spent in the calorimeter, equal to a reduction of pressure from
760 mm. to 668 mm., and this would correspond to an elevation of
about 7000 feet (2135 metres) above the sea level. Such an altitude
would certainly not be trying to the respiration.

The experiment was carried out as follows in every instance: —

Previous to entering the chamber the subject of the experiment
sat down in the laboratory to rest, in many instances taking his
temperature, sublingual, with a clinical thermometer.

In the meantime a weight of ice varying between 10 Ibs. and
15 Ibs. (4'5 to 6'8 kilograms), according to circumstances, was cut
into blocks about 2 or 3 inches diameter, and placed in the ice holder,
where the blocks were disposed as much as possible in a position to
allow the air from the agitator to circulate freely between them. A
temporary receiver for the water from the melting ice was hung to a

Enquiry into the Heat given out by the Human Body. 243

hook soldered to the tube delivering the ice water, for which receiver
a flask of a capacity of over a litre was substituted on starting the
experiment in the chamber.

When all was ready, the person under experiment stepped into
the calorimeter and sat down on a wooden chair. Immediately
afterwards the ice holder was hung up in the chamber to a strong
hook fastened to the roof ; then the tube from the upper agitator
was connected with the ice holder, and the flask with a thermometer
in it, previously weighed, was substituted for the temporary small
receiver of the melted ice. At that very instant the stop-watch was
started to register the time spent in the chamber, the door was
closed and screwed down, and the two agitators were set in motion.
It might here be observed that the person in the calorimeter felt no
draught, as the air from the lower agitator was driven up behind him
through a rose-jet, and that from the upper agitator fell in front of
him on its exit from the ice holder. Indeed no sensation of cold was
experienced, or any discomfort whatever, the temperature in the
chamber remaining exactly the same within a few tenths of a degree
centigrade throughout the experiment. In those cases where the
air expired had to be collected for analysis, this was done by means
of a face-piece strapped to a cap fitting the back of the head. The
face-piece was supplied with a glass tube, which was taken between
the lips and used for the expiration, while another tube served for
the nasal inspiration from the outside of the chamber, without the
intervention of any valves. Fresh air was thus inspired through
the nose and expired through the mouth — a method of breathing
with which we were familiar. The inspiratory tube communicated
with the external air through the walls of the chambers, while the
expiratory tube was connected at will either with the bell-jars or the
open air. The bell-jars were suspended in such a way that the
person in the chamber never knew when he was breathing into the
open air or into the air holders. Three bell-jars were in use, and in
many cases an india-rubber bag, faced with oil-silk, was pressed into
service, so as to allow of the collection of an increased volume of ex-
pired air. The volume of air collected, though only including the air
expired during from twenty minutes to half an hour, taken at intervals
through the whole time, certainly gives an accurate estimation of
the composition of all the air breathed while in the calorimeter,
considering that the person remains in a perfect state of repose
during that time, except, perhaps, for a minute on entering the
chamber.

On one occasion the whole of the air expired in one hour was
collected, and in that experiment it was found that the volume
of air expired in half an hour, taken at different intervals of time,
was proportional to the volume expired in the whole hour.

244 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

The observer, whose duty it was to read the thermometers, stood
up on a stool ready to work the regulators of the dynamos, and by
constant attention the temperature of the metal of the copper
chamber was not allowed to fall or rise beyond about O3° from the
initial reading.

After an hour, measured to a second with the stop-watch, a last
reading of the thermometers was taken while at the same time a signal
was made to the person in the chamber by showing him a light, and
lie immediately closed the stopcock of the tube letting the melted
water into the flask. By this means the water collected was given
out exactly in one hour, the agitators were stopped, and the person
under experiment finally let out. As soon as the door was open, the
temperature of the ice water in the flask was recorded.

The sublingual temperature when required was again taken at
that time, if it had not been determined in the last few minutes of
the stay in the chamber.

The next process was to weigh the flask with the ice water and
thermometer, and by subtracting the weight of the empty flask and
thermometer, that of the melted ice was obtained. In one hour's
•experiment the water from the melted ice amounted to rather over
1000 grams, but its weight varied on each occasion. The counters
in connection with the agitators were now read.

This completed the data for the calculation of the calories re-
covered in the chamber. The calculation, a very simple one, is illus-
trated in the following table, which gives the particulars of one
•experiment taken at random : —

Illustration of the Observations and Calculations required in one

Experiment.

Two preliminary Test Experiments with Agitators to determine Heat

given out.

Upper agitator. Lower agitator.
924,442 677,155

735,640 494,300

1st counters. readings

{. initial .,

Number of revolutions . . 188,804

f Final readings . . 1,104,775
2nd counters <

I Initial „ .. 924,444

Number of revolutions . . 180,331

182,85*

852,831
677,155

175,676

Sum of revolutions squared. Calories found.

1st 13,813 12,527

2nd 12,674 12,138

Means .... 13,244

12,333

Enquiry into the Heat given out by the Human Body. 245

Experiment with Subject in Calorimeter.

Upper agitator. Lower agitator.

r . /Final readings.... 238,566 1,052,431

Counters < _n. ^7C, QKQ QQI

( Initial „ .... 104, / 75 852,831

133,791 199,600

133,791
199,600

(333,391)2 = 11,115....

13,244 : 11,115 = 12,333 : x
x = 10,355

3.51 P.M.

Chamber.
15-30° C.

Copper.
15-16° C.

Annular space.
15-20° C.

4.1

15-33

15-26

15-26

4.11

15-34

15-13

15-32

4.21

15-62

15-22

15-32

4.31

15-28

15-12

15-32

4.41

15-74

15-22

15-34

4.51

15-12

15-10

15-35

Difference of extremes — 0' 18 -0-06 +0'15

Time spent in calorimeter, one hour.
Weight of ice water, 1309'30 grams.
Temperature of water, 9° C.

Calories found.

Calories.

Ice water 1309-30 x 79* = 103,435

Ice water 1309-30 x 9° = 11,784

From air in annular space 69 X 0' 15 = 10

From copperf 5832 x 0'06 = 350

From air in chamber . . 214 x 0'18 = 38 115,229

-388

388

Calories 114,841

Correction for agitators 10,355

Heat emitted in one hour, say, calories found 104,486

* 79 = number of calories absorbed by the melting of 1 gram of ice.

f The figures 5832 for copper, 214 for air of chamber, and 69 for air of annular
space are constants obtained by multiplying the individual weights by their corre-
sponding specific heat.

246 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

Determination of Oxygen consumed or absorbed.
130"427 litres of air expired (reduced) in 26 minutes.

Per minute.

C02 found 239-0 c.c.

Surplus O absorbed 65'1

304-1 x 1-4338 (weight of 1 litre of 0)
X 60 minutes = 26"! 62 grams 0 absorbed per hour.

104,486/26,162 = 3994 calories, corresponding to 1 gram O con-
sumed.

The first set of experiments was undertaken in order to ascertain
whether in the course of an hour there is any variation in the heat
given out by the same person, and, with this object in view, the heat
emitted by each of us in turn was determined throughout the first
and second half-hours spent in the calorimeter. It was found neces-
sary to introduce a three-way cock into the tube delivering the water
from the melted ice into the flask ; this three-way cock diverted the
stream at will into one or other of two flasks hanging to the tubes
leading from the ice-holder.

The results obtained were as follow : —

Calories in two half-hours in succession.
W. M. E. B. F.

First Second First Second

half-hour. half-hour. half-hour. half-hour.

58,781 58,551 55,444 51,395

53,230 50,939 49,216 52,445

55,327 52,161 49,128 53,812

59,947 62,177 48,037 48,914

46,644 48,954 49,540 51,905

_ _ 46,744 44,878

Means 54,786 54,556 49,685 50,558

Difference = 0'42 per cent. Difference — 1'76 per cent,
decrease in second half- increase in second half-

hour on first half-hour. hour on first half-hour.

Total for the eleven experiments, 0*75 per cent, increase in second
half-hour. (Calculation from total figures.)

Therefore, in the case of W. M., the mean of five experiments gave
a difference of only 0'42 per cent, in the calories emitted during two suc-
cessive half-hours, while, in the case of R. B. F., the mean difference of

Enquiry into the Heat given out by the Human Body. 247

six experiments was only by 1'76 per cent. The mean difference (from
total figures) from the two persons in eleven experiments amounted
to O75 per cent., showing that practically the mean heat emitted was
the same in each of two consecutive half-hours. There were, how-
ever, differences, though usually slight, in each pair of experiments
— sometimes an increase, sometimes a decrease — the reason of which
is difficult to assign.

The calories given out by the various persons experimented upon
were taken generally between lunch and dinner, say at a mean time
of about two hoars after a full luncheon, and therefore under the
immediate influence of food. But towards the end of the inquiry a
certain number of experiments were made just before lunch, corre-
sponding with others made after lunch, in order to determine in a
general way the effect of a full mid-day meal on the heat-producing
power of the body. The mean of seventy-two experiments on four
persons, aged respectively 15, 27, 28, and 69, gave 102,907 calories
per hour,* and varied from 80,639 to 137,078. In other words, the
mean heat given out in one hoar was such as would raise 102,907
grams of water by 1° centigrade (from 0° to 1°).

The next point we submitted to enquiry was the relation, if any,
between the oxygen absorbed from the air breathed, and the calories
emitted at the same time.

The oxygen absorbed was determined by collecting the air expired
by the person in the calorimeter, and estimating the C02 and 0 con-
tained in the expired air. This was done by methods fully described
in previous papers (by W. M.), and need not be further insisted
upon. We found the method of breathing for collecting the air
expired (inspiration through nose and expiration through mouth)
quite satisfactory in every way, the subjects for these experiments
being all used to this mode of breathing.

It is important to observe at the outset that, while there were
great differences between the calories found for each person, the
oxygen absorbed from the air in every individual case did not
exhibit such marked variations ; moreover, except in a very general
way, the oxygen absorbed failed to vary in proportion with the
number of calories emitted.

* These experiments include the whole number made, most of them under the
influence of a full meal, but a few fasting, or before the mid -day meal. Of course
they can only be expected to give a general idea of the mean calories emitted by
man, as the amount of heat emitted varies with every different person, and under
different conditions as to food and many other circumstances.

YOL. LXIII. T

248 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

Calories emitted in one hour and corresponding Oxygen absorbed.
W. M. under experiment. Age 69 ; weight 57'9 kilograms.

Calories in
one hour.

Change of
sublingual
temperature.

Time for
collecting
air expired.

O absorbed.

Calories for 1 gram
O absorbed.

c C. niins. sees.

122,124

—

8 2

24 -276

5031]

110,654

—

7 48

25 -592

4324 1 4518

94,837

—

7 30

22 -581

4200 J

93,905

o-o

21 0

24-362

3855 "j

93,408

—

15 24

2L-697

4305 1 4143

92,731

-0-25

32 28

21 -721

4269 J

*91,270

-0-2

54 35

24-233

37661

*90,882

—

21 36

22-615

4019 1 4064

90,844

+ 0-1

21 50

20-611

4408 J

*90,155

-o-i

24 3

21 -764

4142]

*89,085

-0-2

20 3

25-015

3561 }• 3938

89,011

+ 0-05

15 45

21 -643

4113 J

88,832

—

24 0

21 -961

4045]

88,406

o-o

27 43

21 -867

4043 J- 3969

*87,240

-0-3

28 0

22 -830

3821 J

81,315
80,639

-0-15

-o-i

One hour
29 29

23 -062
24-495

3526 13409
3292/d40y

Mean 4042

Supplementary List.

107,397 ! —

104,169

—

101,151

+ 0-15

98,123

-o-i

97,974

—

96,399

-0-25

95,598

—

88,641

—

87,314

-0-2

* The figures for calories with an asterisk correspond to experiments made in
the calorimeter with an overcoat on. The effect of the increased clothing is
insufficient to influence the general means.

Enquiry into the Heat given out by the Human Body. 249

Calories emitted in one hour and corresponding Oxygen absorbed.
R. B. F. under experiment. Age 27 ; weight 53'0 kilograms.

Calories in
one hour.

Change of
sublingual
temperature.

Time for
collecting
air expii-ed.

r\ u u i Calories for 1 gram
0 absorbed

°C.

mins. sees.

105,203

o-o

26 0

26-458 3976]

103,569

—

8 50

23-249 4455 U283

103,186

-0-05

23 0

23-352 4419 J

101,445

9 10

23-266 4360]

100,077

o-o

21 0

26-785 3736 J> 41 61

97,071

—

9 20

22 -131

4386 J

96,947

—

18 0

22-286

4350]

95,924

-0-3

22 0

23 -215

4132 L 4044

92,880

-0-05

23 17

25 -443

3651 J

91,622
91,558
81,882

0-05
-0-3

7 40
20 0
28 0

26 -312
25 -951
23 -533

3482]
3528 1 3796
4379 J

80,985

-0-45

15 41

23 "593

3433 3433

Mean 4022

Supplementary List.

106,839

102,940

101,661

100,159

-0-25

99,309

-0-05

96,735

-0-2

90,523

-0-25

85,338

-0-4

T 2

250 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

Calories emitted in one hour and corresponding Oxygen absorbed.
E. R. under experiment. Age 28 ; weight 80'4 kilograms.

Calories in
one hour.

Change of
sublingual
temperature.

Time for
collecting
air expired.

O absorbed.

Calories for
1 gram
O absorbed.

°C.

mins. sees.

126,928

+ 0-1

26 0

30 '762

4126

124,335

—

13 45

30 -665

4055

117,131

+ 0-05

28 32

29-290

3990

116,874

-0-3

12 2

30 -237

3865

115,221

-0-15

24 41

28 '379

4060

111,754

o-o

22 2

32 -887

3398

Mean 3916

Supplementary List.

137,078

-0-3

129,028

o-o

127,594

+ 0-15

126,872

+ 0-1

125,129

~

These lists include thirty-six experiments on three different persons,
in all of which the oxygen taken from the air, while in the chamber,
was determined. At the outset a striking similarity is observed
between the means of the calories produced for 1 gram of oxygen
absorbed.

(Mean of 17 exp.)
( » 13 „ )
( „ 6 „ )

With W. M. that figure is 4042

„ R. B. F. „ ... 4022
E. R. . 3916

It is, therefore, obvious that there is a definite relation of cause
to effect in the absorption of oxygen towards the production of
animal heat. These figures must not be considered as absolutely
final ; they show that under similar circumstances relating to time
of food, &c., the mean calories produced for 1 gram of oxygen absorbed
are the same for different persons, at all events as far as can be
gathered from the three subjects experimented upon ; and, moreover,
it may be concluded that the true figure closely approximates 4000
(small calories). Him, from his experiments, gives 5'22 large
calories for 1 gram of oxygen absorbed, which exceeds our figure
(4'00) to a marked extent.

If the volume of oxygen absorbed from the air was proportional to
the calories given out during the same time, then, by placing iu a
tabular form the numbers for the calories found, beginning with the

Enquiry into the Heat given out by the Human Body. 251

highest number and ending with the lowest, and also inscribing
opposite these figures those showing the oxygen absorbed in each
corresponding experiment, it would be expected that the figures for
oxygen absorbed would follow in succession those for the calories
found, beginning with the highest and ending with the lowest.
Such, however, is far from being the case. Therefore, except in a
very general way, as shown by our means and under similar circum-
stances with reference to food, the oxygen taken from the air
does not produce heat in the body in proportion to the amount absorbed.
And this may be taken as a clear indication that the oxygen absorbed
in a given time is not a measure of the heat produced during that
same time.

Should tables now be made of the calories in numerical order,
beginning with the highest, placing the figure for " calories for
1 gram oxygen absorbed " opposite its respective calories, a peculiar
occurrence is observed. It will be seen readily by a consideration of
the foregoing tables that if the calories found in one hour and
those calculated for 1 gram oxygen absorbed be grouped three
by three (or even two by two), the calories for 1 gram oxygen
absorbed decrease fairly regularly together with the falling for the
hour-calories (less so when taken two by two), and this takes place
in the case of three different persons, and therefore cannot possibly
be accidental. It follows that 1 gram of oxygen absorbed from the
air is attended with the emission of either 5031 calories or 3292
calories, as extremes for one person, and for another person either
4455 or 3433 calories, and again for a third either 4126 or 3398
calories. The readiest explanation of this phenomenon is the assump-
tion of a storage of oxygen in the tissues, which is made use of,
although unaccounted for (as oxygen absorbed) at the time. Still,
the mean relation of the oxygen absorbed to the heat emitted remains
the same, being as nearly as possible 4000 calories for 1 gram
oxygen absorbed under similar conditions.

This shows that whatever be the mode of action of the absorbed
oxygen it repeats itself in a general way, if taken at similar periods
with reference to food, &c.

There is a circumstance in these experiments which should be
taken into account concerning the frequent change of temperature
of our bodies while in the calorimeter, as ascertained by sublingual
observations with a clinical thermometer. The cooling reached an
extreme of 0'45° C., though usually only 0'15° or 0'2° C., but it
varied much in different experiments, while on some occasions there
was no change, and even once or twice a rise was observed. The fall
of temperature was thought at first to be due to the proximity of
the ice in the chamber ; but the same effect was observed by taking
W. M.'s sublingual temperature while sitting quite quiet for an hour

252 Dr. W. Marcet and Mr. E. B. Fioris. An Experimental

out of the calorimeter, when a distinct and gradual fall in the sub-
lingual temperature occurred to the extent of O2° C.

We looked carefully through the results obtained, in order to
ascertain whether this cooling of the body while under experiment
had any appreciable influence either on the heat emitted, or on the
oxygen absorbed, but failed to observe any phenomena which might
be ascribed to such a cause ; it must, however, be attended with some
effect.

A few experiments were made on the influence of food in a general
way by comparing the heat given out in the calorimeter by the same
individual, shortly before, and one or two hours after the midday
meal, the meal consisting of a full allowance of meat, potato, bread,
and a glass of beer. The experiments before luncheon are, there-
fore, in a comparatively fasting condition, and those after luncheon
may be looked upon as being under the influence of a full meal.

Before lunch.

92,731

88,406

(90,844

81,315

95,924
81,882
80,985
96,050

111,754
115,221
116,874
117,131
126,928

(118,087
121,868

(114,675

98,643

104,922

109,078

667,273

W. M.

After lunch.

96,3i>9

98,123

87,314

101,151

R. B. F.

99,309
84,653
91,208
99,474

E. R.

125,129

126,872
129,028
127,594
135,870

E. F.

114,377
125,001
110,495
109,730
108,952
112,780

Per cent,
increase after lunch.

3-95
10-99

fall)
24-39

3-53

3-38

12-62

3-56

11-97

10-11

10-40

8-93

7-04

fall)
2-57
fall)
11-24
3-84
3-39

681,335

Enquiry into the Heat given out by the Human Body. 253

Therefore out of nineteen experiments only three show a fall in
the amount of heat emitted after lunch. Of these three, one (W. M.)
is easily accounted for from the digestion of the person under
experiment being on that day somewhat out of order, and very
little food being taken. In the other instances, in which the labo-
ratory boy was in the calorimeter, he acknowledged finding it diffi-
cult to sit quiet, and movement may easily account for the irregular
result.

It follows from these experiments that the rule is an increase in
the emission of heat from the body after a full meal.

Finally it was of interest to ascertain how far the heat emitted by
the body is in proportion to the weight of the body. The following
table shows clearly that this relation is subject to great variations ;
the lightest person under experiment, also the youngest (being
sixteen years of age), gave out a mean amount of heat per kilo,
weight greatly exceeding all the others.

Calories
per hour.

Weight of
the body.

Mean
calories per
kilogram.

W. M. (mean of 26 experiments). . .

95,605

57-9

1651

R. B. F. ,,21

96,469

53-0

1820

E. E. ,,11

123,449

80-4

1535

E.F. „ 12

112,217

41-0

2737

When the work connected with this paper was nearly completed,
it occurred to us that there were two important omissions in the
enquiry. The first was the neglect to take into account the heat lost
from the calorimeter by the air expired when it was collected for
analysis ; * on the other occasions the air was expired into the calo-
rimeter, and therefore there was no loss of heat from that cause.
We now made a few experiments, taking the temperature of the air
expired at its exit from the chamber. The excess of this tempera-
ture over that of the air inspired was used for calculating the heat
lost, and the correction introduced where necessary. This figure
varied somewhat for each person under experiment. The second
omission was leaving the carbonic acid which might have collected

* Supposing the air expired was found on its exit from the calorimeter to be
8° C. higher than the external air, and that this volume of air reduced amounted
to 112'5 litres in 25 minutes, this would give a weight of 145'5 grams of air,
which multiplied by the specific heat of air (0'2375) and by 8, the excess tem-
perature = 276-4 calories, or for an hour 663 calories. On a total heat of 95,000
calories, the heat thus lost would only amount to 0'7 per cent.

254 Dr. W. Marcet and Mr. R. B. Floris. An Experimental

in the calorimeter unaccounted for. Some C02 must be derived from
the skin, and perhaps some small quantity of air might possibly have
escaped from the face-piece into the chamber.

The calorimeter was conveniently available for the determination
of the C02, which might have collected in it, as the chamber was
perfectly closed, whatever minute openings there were being much
too small to allow of any diffusion out of the chamber. This was
tested experimentally in the course of the present enquiry by
expiring air into the bell-jars, while out of the .calorimeter ; shortly
afterwards the same person entered the chamber and breathed in
it for forty minutes or an hour. The mean of eight experiments
gave figures for the C02 in and out of the chamber exactly the
same.*

The determination of the C02 in the air of the chamber while
breathing the external air was made by putting on the face-piece
on entering the calorimeter, and after the door was closed, rinsing a
dry flask (holding about 6 litres) with air from the upper agitator ;
this flask was then stopped with an india-rubber cork, having a tube
with a stopcock inserted through it. After sixty minutes another
large, dry flask, full of fine, dry sand, was suddenly emptied of its con-
tents, and closed with a cork similar to that used with the other
flask. The determination of C02 was made in each flask with a
standard solution of barium hydrate, by Pettenkofer's method. The
C02 in the chamber was obtained by subtracting the weight (or
volume) of C02 found in the chamber at the very beginning of the
experiment from the weight of the C02 found in the chamber after
the subject had remained an hour in it. This C02 varied somewhat
with the three persons who submitted to experiment ; the mean
value for each of us was used for the correction of the oxygen ab-
sorbed ; this correction was, however, but small, varying from about
1 to 3 per cent, of the CO2 determined in the air collected in the
bell -jar.

The results obtained from the present enquiry may be summarised
as follows : —

1. The amount of heat given out from the human body when

CO2 in bell -jars

Time for collecting

CO2 in chamber

per minute.

in bell-jar.

per minute.

c.c.

Mins. Sees.

c.c.

204-4

9 20

199-2

181-5

8 3

176-1

176-0

9 16

183-5

208-6

7 41

214-6

200-1

8 25

194-7

187*9

8 31

200-2

205-0

8 50

194-9

194-8

194-7

Enquiry into the Heat given out by the Human Body. 255

tested on two successive half-hours is found to be the same when the
means of the calories are taken, although in each separate experi-
ment the heat emitted may vary to some slight extent.

2. The heat emitted by the same person varies, and the extent of
this variation is wider in some subjects than in others ; thus in
W. M.'s case the calories emitted in one hour from twenty-six experi-
ments varied from 122,124 to 80,639, or by 33'9 per cent, of the
larger figure. In the twenty-one experiments of R. B. F. they varied
from 106,839 to 80,985, or by 24'2 per cent. With E. R., in eleven
experiments, from 137,078 to 111,754, or by 18'5 per cent.

3. As a fact irrespective of theory the mean number of calories
found from three different persons, under similar circumstances of
food, &c., corresponding to 1 gram of oxygen absorbed from the
air, was the same, and can be stated in round numbers at 4000.
Had more experiments been done fasting, this figure would have
shown a slight tendency to fall.

4. Although the mean calories per individual for 1 gram oxygen
absorbed under similar circumstances of food, &c., are the same, still
in the experiments taken singly, the number of calories correspond-
ing to 1 gram oxygen absorbed, vary, and this in a regular way.
The greater the heat given out, the greater the calories produced for
1 gram oxygen absorbed, and vice versa. Therefore, either a given
amount of oxygen absorbed can produce different quantities of heat,
or the oxygen found as absorbed does not represent that to which
the heat is due; this second alternative appears the more probable.

5. The influence of a meal, as ascertained on three different
persons, is well marked. Taking the midday meal, when mixed
food is eaten, generally with a good appetite, the calories emitted
about two hours after lunch show an increase over those given out
about three or four hours after breakfast. The excess varies in
different persons, and according to the kind and amount of food taken.

6. The calories emitted per kilo, weight of the body are subject
to marked variations in different persons.

A few experiments were made on the influence of clothing on the
heat emitted, but we thought it best to reserve that subject for a
future communication.

256 Prof. J. Dewar.

" Preliminary Note on the Liquefaction of Hydrogen and
Helium." By JAMES DEWAR, M.A., LL.D., F.R.S., Ful-
lerian Professor of Chemistry in the Royal Institution.
Received and read May 12, 1898.

In a paper entitled " The Liquefaction of Air and Research at
Low Temperatures," read before the Chemical Society, and pub-
lished in their 'Proceedings,' No. 158, an account is given of the
history of the hydrogen problem and the result of my own experi-
ments up to the end of the year 1895. The subject is again dis-
cussed in a Friday Evening Lecture on " New Researches on
Liquid Air,"* which contains a drawing of the apparatus employed
for the production of a jet of hydrogen containing liquid. It was
shown that such a jet could be used to cool bodies below the tem-
perature that could be reached by the use of liquid air, but all
attempts to collect the liquid in vacuum vessels failed. No other
investigator has so far improved on the results described in 1895.
The type of apparatus used in these experiments worked well, so it
was resolved to construct a much larger liquid air plant, and to
combine with it circuits and arrangements for the liquefaction of
hydrogen, which will be described in a subsequent paper. This
apparatus, admirably constructed by the engineers, Messrs. Lennox,
Reynolds, and Fyfe, took a year to build up, and many months have
been occupied in testing and making preliminary trials. The many
failures and defeats need not be detailed.

On May 10, starting with hydrogen cooled to —205° C., and
under a pressure of 180 atmospheres, escaping continuously from the
nozzle of a coil of pipe at the rate of about 10 cubic feet to 15 cubic
feet per minute, in a vacuum vessel double silvered and of special
construction, all surrounded with a space kept below —200° C.,
liquid hydrogen commenced to drop from this vacuum vessel into
another doubly isolated by being surrounded with a third vacuum
vessel. In about five minutes, 20 c.c. of liquid hydrogen were col-
lected, when the hydrogen jet froze up from the solidification of air
in the pipes. The yield of liquid was about 1 per cent, of the gas.
The hydrogen in the liquid condition is clear and colourless, show-
ing no absorption spectrum and the meniscus is as well defined as in
the case of liquid air. The liquid has a relatively high refractive
index and dispersion, and the density appears to be in excess
of the theoretical density, viz., 0'18 to 0'12, which we deduce
respectively from the atomic volume of organic compounds and the
limiting density found by Amagat for hydrogen gas under infinite

* ' Roy. Inst. Proc.,' 1896.

On the Liquefaction of Hydrogen and Helium. 257

compression. My old experiments on the density of hydrogen in
palladium gave a value for the combined body of 0'62, and it will be
interesting to find the real density of the liquid substance at its
boiling point. Not having arrangements at hand to determine the
boiling point, two experiments were made to prove the excessively
low temperature of the boiling fluid. In the first place, if a long
piece of glass tubing, sealed at one end and open to the air at the
other, is cooled by immersing the closed end in the liquid hydrogen,
the tube immediately fills, where it is cooled, with solid air. The
second experiment was made with a tube containing helium.

The * Cracow Academy Bulletin ' for 1896 contains a paper by
Professor Olszewski, entitled " A Research on the Liquefaction of
Helium," in which he states " as far as my experiments go, helium
remains a permanent gas and apparently is much more difficult to
liquefy than hydrogen." In a paper of my own in the * Proceedings
of the Chemical Society,' No. 183 (1896-7), in which the separation
of helium from Bath gas was effected by a liquefaction method, the
suggestion was made that the volatility of hydrogen and helium
would probably be found close together just like those of fluorine
and oxygen. Having a specimen of helium which had been
extracted from Bath gas, sealed up in a bulb with a narrow tube
attached, the latter was placed in liquid hydrogen, when a distinct
liquid was seen to condense. A similar experiment made with the
use of liquid air under exhaustion in the same helium tube (instead
of liquid hydrogen) gave no visible condensation. From this
result it would appear that there cannot be any great difference in
the boiling points of helium and hydrogen.

All known gases have now been condensed into liquids which can
be manipulated at their boiling points under atmospheric pressure
in suitably arranged vacuum vessels. With hydrogen as a cooling
agent, we shall get within 20° or 30° of the zero of absolute tem-
perature, and its use will open up an entirely new field of scientific
inquiry. Even as great a man as James Clerk Maxwell had doubts
as to the possibility of ever liquefying hydrogen.* No one can pre-
dict the properties of matter near the zero of temperature. Faraday
liquefied chlorine in the year 1823. Sixty years afterwards Wrob-
lewski and Olszewski produced liquid air, and now, after a fifteen
years' interval, the remaining gases, hydrogen and helium, appear as
static liquids. Considering that the step from the liquefaction of air
to that of hydrogen is relatively as great in the thermo-dynamic sense
as that from liquid chlorine to liquid air, the fact that the former
result has been achieved in one-fourth the time needed to accom-
plish the latter, proves the greatly accelerated rate of scientific
progress in our time.

* See ( Scientific Papers,' vol. 2, p. 412.

258 Mr. S. R. Roget. Effects of prolonged

The efficient cultivation of this field of research depends upon
combination and assistance of an exceptional kind ; but in the first
instance money must be available, and the members of the Royal
Institution deserve my especial gratitude for their handsome dona-
tions to the conduct of this research. Unfortunately its prosecution
will demand a further large expenditure. The handsome contribution
made by the Goldsmiths Company ought also to be mentioned as
very materially helping the progress of the work.

During the whole course of the low temperature work carried out
at the Royal Institution, the invaluable aid of Mr. Robert Lennox
has been at my disposal ; and it is not too much to say that but for
his engineering skill, manipulative ability, and loyal perseverance,
the present successful issue might have been indefinitely delayed.
My thanks are also due to Mr. J. W. Heath for valuable assistance
in the conduct of these experiments.

" Effects of Prolonged Heating on the Magnetic Properties of
Iron." By S. R. RoQET, B.A. Communicated by Professor
EwiNG, F.R.S. Received April 4,— Read May 12, 1898.

It has been known for some years that when transformers are
kept in use, their open-circuit loss is liable to increase considerably
with the lapse of time. This implies a deterioration of the iron core
in regard to magnetic hysteresis. The subject began to receive
attention in 1894-5, when some curves showing this increase in
hysteresis were published by Mr. G. W. Partridge.* The effect
was first thought to be due to a species of magnetic fatigue, resulting
from repeated reversals of magnetism in the iron, but it was proved by
Professor Ewing early in 1895 not to be due to this cause ; f and
was further shown by the experiments of Mr. Blathy and Mr.
Mordey to be a direct effect of heat and to occur in transformers as a
consequence of the iron being maintained for long periods at a com-
paratively high temperature. Continued baking of iron was found
to produce a similar augmentation of hysteresis. The published
results of Mr. Mordey,^ and, later, those of Mr. Parshall,§ deal
with prolonged heating at temperatures which do not exceed 140° C.
At the suggestion of Professor Ewing, the author has been carrying
out, in the laboratory of the Engineering Department of Cambridge
University, some investigations which deal with a more extended
range of temperature. The experiments are still in progress, but

* * The Electrician/ vol. 34, p. 160, December, 1894.
t Ibid., p. 297, January, 1895.
J ' Proc. Roy. Soc.,' vol. 57, p. 224, June, 1895.
§ ' Min. Proc. Inst. C.E.,' vol. 126, p. 244.

Heating on the Magnetic Properties of Iron. 259

already results have been obtained which appear to be of sufficient
novelty to warrant publication.

The hysteresis of the iron was directly measured by means of
Professor Ewing's Hysteresis Tester, in which the work spent on a
specimen rotating in a magnetic field is observed and is compared
with the work spent in rotating standard specimens.* In these
experiments the same pair of standards was used throughout for
the calibration of the hysteresis tester. The test specimens were
all cut from the same sheet ©f metal and were of soft Swedish
transformer plate, having very low initial hysteresis. They were
first tested in the annealed state and were then heated in small
ovens which were kept hot by means of incandescent lamps. The
temperatures of the ovens were observed in most cases by mercury
thermometers, but those above 200° C. were measured by a
Callendar-Griffiths platinum pyrometer. The specimens were taken
out of the ovens from time to time to be tested, and all the tests
of hysteresis were made at atmospheric temperature. It was not
found possible to keep the temperature of each oven very constant,
but when the ovens were once hot, the variation of temperature
was rarely more than 10 degrees C. in either direction. To these
variations may be ascribed certain irregularities which will be
apparent in the observations, but the general character of the
changes due to prolonged heating is sufficiently clear. Each specimen
consisted of a bundle of seven strips 3 inches long, and about J- inch
wide, and each strip was annealed separately by heating it to redness
in a Bunsen flame, and allowing it to cool in the air. As the effects
of prolonged heating described below were in all cases found to be
completely removed by reannealing, the same samples could be used
over and over again, and this was in fact done in most cases. In all
the experiments the measurement of hysteresis relates to cyclic pro-
cesses in which the induction B changes from + 4000 to — 4000
C.G.S. units.

The effects produced by baking differ widely at different tempera-
tures. Below 40° C. the author has found no evidence of any
change. Between 40° C. and about 135° C. the hysteresis simply
increases with time, at least during the longest time of heating tried
in these experiments. The increase of hysteresis is relatively rapid
at first, and becomes slower as times goes on. Curves 1 — 4, fig. 1
show results of this nature by exhibiting the percentage increase
in hysteresis after various times of baking. The absolute values of
the hysteresis at the different stages are stated in Table I in ergs
per cycle per cubic centimetre (for B = 4000) together with the rise
expressed as a percentage of the initial hysteresis to the nearest

* ' Journal Inst. Elect. Eng.,' vol. 24, p. 403 j also ' Min. Proc. Inst. C.E.,' vol.
126, p. 206.

260

Mr. S. R. Roget. Effects of prolonged

1 per cent. The curves have been sketched by joining the observed
points instead of drawing smooth curves through them, as this avoids
confusion of points belonging to different curves.

It was found however that at higher temperatures, from about
135° C. upwards, a maximum value of the hysteresis was attained
in a comparatively short time, after which continued heating caused
a marked decrease of hysteresis instead of a further increase. The
initial rise at the higher temperatures is very rapid ; for example,
the hysteresis doubles in a few hours at a temperature of 160° C.,
and reaches nearly three times its initial value in a few days.
Curve 5 of fig. 1 exhibits this case, the data for which are given in
Table I. After seven days of heating, the hysteresis of this sample
began to decrease, and in fifteen days it had fallen to 2^ times
its original value. A still more notable decrease occurs at higher

JIG. 1.

20O

Fl

Heating on the Magnetic Properties of Iron. 261

T

7

JO.

Hours

temperatures. This feature in the effect of prolonged heating seems
to have escaped the notice of previous workers in the subject.

262

Mr. S. R. Roget. Effects of prolonged

It appears that there is a temperature in the neighbourhood of
180° C., for which the maximum increase of hysteresis is greatest.
With higher temperatures the hysteresis, although rising more rapidly
at first, docs not reach so high a maximum value and begins to fall
sooner and faster, tending apparently to a lower steady state the
higher the temperature. An example of this is shown in curve 7,
fig. 1 (temperature 260° C.), where a fairly low and nearly steady
state is reached in the last days of the heating. In this instance it
took the iron only about a quarter of an hour to reach its maximum
of hysteresis, which was only 91 per cent, higher than the initial
value.

Fig. 2 shows the earlier stages of the action for temperatures
of 125° C. and over. It will be noticed that the peak at which the
hysteresis reaches its maximum in each case comes sooner the higher
the temperature, and that its height becomes reduced when the
temperature is high. The absolute values of the hysteresis in the
experiments to which these curves relate are given in Table II.

It is probable that the attainment of a maximum value followed
by a decrease is not confined to temperatures above 135° C., and it

Heating on the Magnetic Properties of Iron.

263

is intended to carry out experiments to find if this is so, using more
prolonged heating.

In order to exhibit the character of the change in magnetic
property, supplementary experiments were made by the ballistic
method, using a ring of soft iron formed by coiling* up a long strip
of sheet metal. This was first annealed, and tested in the annealed
state. It was then baked by heating at 200° C., and cyclic curves
were determined in the usual way after the ring had become cold.
The results are stated in Table III, and are shown in the curves of
fig. 3. Carve 1 shows the initial state (after annealing), where
the value of the hysteresis is 830 ergs per cycle per cubic centimetre
(B = 4000). Curve 2 shows the state after nineteen hours of baking
at 200° C., when the hysteresis had greatly increased and had
reached a value of 1580 ergs. Curve 3 was taken after further
heating at the same temperature for four days, by which time the
decrease of hysteresis is very apparent, its value having diminished
to 1420 ergs. Permeability curves, taken by the method of reversals
after heating during the same periods, are given in fig. 4 and

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YQL, LXIII, V

264

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266 Effects of Heating on the Magnetic Properties of Iron,
Table III. — Cyclic Curves for Ring.

1.

2.

3.

Before heating.

After 20 hours at
200° C.

After 4 days at
200° C.

H.

B.

H.

B.

H.

B.

1-36

4000

2-20

4000

2-06

4000

1-26

3650

1-97

3170

1-91

3500

1-06

2300

1-05

-1900

1-47

1950

0-72

-850

0-70

-2620

1-02

-1310

0-44

-2320

0-28

-3100

0-68

-2480

0-26

-2740

o-oo

-3400

0-28

-3050

o-oo

-3130

-0-28

-3460

O'OO

-3310

-0-26

-3400

-0-87

-3700

-0-28

-3520

-0-72

-3700

-1-23

-3790

-0-87

-3740

-1-05

-3850

-1-51

-3880

-1-45

-3930

Table IV. — Permeability Curves for Ring.

1.

2.

3.

Before heating.

After 20 hours at
200° C.

After 4 days at
200° C.

H.

B.

H.

B.

H.

B.

0-19

90

0-39

70

0-39

100

0-39

220

0-78

160

078

190

0-58

420

1-16

390

1-16

520

0-78

760

1-55

1200

1-55

1660

0-97

1570

1-94

2730

1-75

2320

1-16

2550

2-12

3600

1-94

3400

1-36

3760

2-33

4320

2-12

4420

1-55

5220

2-52

5480

2-33

5340

1-75

6150

2-72

6220

2-52

6100

In order to ascertain whether the effects could be due to the
iron taking up anything from the atmosphere, a couple of specimens
were, at the suggestion of Professor Ewing, sealed up in exhausted
bulbs and heated in the same oven with others exposed to air.
No evidence, however, was found of any difference between the
iron heated in vacuo, and that heated in air.

There is nothing to show that when baked iron is left for
long time it recovers from the condition produced by baking. But
in all cases the iron is restored to its original state of low
hysteresis by reannealing.

Algebraic Functions and Automorphic Functions. 267

In conclusion the author wishes to express his thanks to Professor
Ewing for many suggestions as well as for the facilities which
have enabled the experiments to be carried out.

[Subsequent to the writing of the above paper, permeability curves
have been taken, for a ring of the same material, by the ballistic
method, up to a magnetic force of 25 C.G.S. units. A comparison of
those taken before and after baking shows that the saturation value
of the induction is unchanged by prolonged heating, for although the
earlier part of the curve, as in the case given above, was much
altered, the parts of the curves above a force of 15 C.G.S. units are
practically indistinguishable. — May 15, 1898.]

44 On the Connexion of Algebraic Functions with Automorphic
Functions." By E. T. WHITTAKER, B.A., Fellow of
Trinity College, Cambridge. Communicated by Professor
A. R. FORSYTE, Sc.D., F.R.S. Received April 23,— Read
May 12, 1898.

(Abstract.)

If u and z are variables connected by an algebraic equation, they
are, in general, multiform functions of each other ; the multiformity
can be represented by a Riemann surface, to each point of which
corresponds a pair of values of u and z.

Poincare and Klein have proved that a variable t exists, of which
u and z are uniform automorphic functions ; the existence-theorem,
however, does not connect t analytically with u and z. When the
genus (genre, Geschlecht) of the algebraic relation is zero or unity, t
can be found by known methods ; the automorphic functions required
are rational functions, and doubly periodic functions, in the two cases
respectively. But no class of automorphic functions with simply
connected fundamental polygons has been known hitherto, which is
applicable to the uniformisation of algebraic functions whose genus
is greater than unity.

The present memoir discusses a new class of groups of protective
substitutions, such that the functions rational on a Riemann surface
of any genus can be expressed as uniform automorphic functions of
a group of this class. These groups are sub-groups of groups gene-
rated from substitutions of period two. Groups are first considered
which can be generated by a number of real substitutions of period
two, whose double points are not on the real axis, and whose product
in a definite order is the identical substitution. These groups are
found to be discontinuous, and of genus zero. A method is given for

268 Algebraic Functions and Automorphic Functions.

dividing the plane into curvilinear polygons corresponding to such
a group ; these polygons are simply-connected, and cover completely
the half of the plane which is above the real axis. Sub-groups of
these groups are found, whose genus is greater than unity, and
which are appropriate for the uniformipation of any algebraic
curves.

The sides of the polygons, into which the half -plane is divided, are
formed of arcs of circles orthogonal to the real axis. These may, in
the sense of Lobatchewski's geometry, be regarded as straight lines.
One case, where the construction fails, is shown to correspond to the
limiting case in which Lobatchewski's geometry becomes Euclidian
geometry; the figure then becomes the division of a plane into
parallelograms, used in the theory of doubly periodic functions, and
is appropriate for the uniformisation of algebraic curves of genus
unity. Thus doubly-periodic functions are a limiting case of the
class of functions considered.

The automorphic functions of the groups described solve the
problem of conformally representing a plane, regarded as bounded
by a number of finite lines radiating from a point, on a curvilinear
polygon, whose sides are derived from each other in pairs by pro-
jective substitutions of period two. This leads to the conformal
representation of any Riemann surface, at each of whose branch-
points only two sheets are connected, on a curvilinear polygon whose
sides are derived from each other in pairs by projective substitutions;
and, as it is known that any algebraic curve can, by birational trans-
formation, be represented on a Biemann surface whose branch- points
are all simple, it is seen that the uniformisation of algebraic func-
tions of any genus can be effected by groups of the kind described.

The analytical connexion between the variables of the algebraic
form and the uniformising variables is given by a differential
equation of the third order. A certain number of the constants in
this equation have to be determined by the condition that the group
of substitutions associated with the equation leaves unchanged a
certain circle. When any arbitrary values are given to these con-
stants the solution of the differential equation is termed a qnasi-uni-
formising variable. The properties of quasi-uniform ising variables,
and their relation to the uniformising variable, are discussed in the
last section of the paper.

A Study of the Phy to- Plankton of the Atlantic. 269

" A Study of the Phyto-Plankton of the Atlantic." By GEORGE
MURRAY, F.B.S., Keeper of Botany, British Museum, and
V. H. BLACKMAN, B.A., F.L.S., Hutchinson Student, St.
John's College, Cambridge, and Assistant, Department of
Botany, British Museum. Keceived March 28, — Read May
12, 1898.

(Abstract.)

The authors record their observations on a year's work in collect-
ing phyto-plankton along a track from the Channel to Panama
carried ont by Captains Milner and Budge, and also during one
voyage to Brazil by Captain Tindall. They also give the results of
their own observations on living material at sea. The material was
obtained by the pumping method.

One of the objects of their work was to determine, if possible, the
nature of the Coccospheres and Bhabdospheres. They describe the
minute structure of the calcareous plates or coccoliths and rhabdo-
liths, and record the existence in the Coccospheres of a single central
green chromatophore, separating into two on the division of the cell.
They regard Coccosphaeraceaa as a group of Unicellular Algee, and
they define the group, the limits of the genera and species. The
Coccospheres and Bhabdospheres from the surface are compared with
those of the deep-sea deposits and their identity established. They are
also compared with geological coccoliths and rhabdoliths from various
beds, and many objects regarded by geologists as true coccoliths and
rhabdoliths are rejected. A large number of new Peridiniaceaa were
discovered and are formally described and figured. No specific
diagnoses of marine Peridiniaceas have previously been published,
authors of species having depended on figures, and, at most, a few
words of description. It is hoped that the present systematic treat-
ment of the subject will conduce to greater order in the group.
The authors record the occurrence of all the forms in seven tabular
statements, one for each collecting voyage.

Observations of the diatoms and Cyanophycese were also made, and
are briefly treated.

A study was also made of the species of Pyrocystis, of which they
describe a new one. The facts they record tend, in their opinion, to
confirm the view originally expressed of it by Dr. John Murray, its
describer, that it is a unicellular alga, doubts having been entertained
of the accuracy ol this opinion by several biologists.

YOL. LXIII. x

270 Prof. W. J. Sollas.

May 26, 1898.
The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.

The following Papers were read : —

I. " On the Cytological Features of Fertilisation and related Phe-
nomena in Pinus silvestris, L." By V. H. BLACKMAN, B.A.,
F.L.S. Communicated by FRANCIS DARWIN, F.R.S.

II. " The Skeleton and Classification of Calcareous Sponges." By
G. P. BIDDER. Communicated by ADAM SEDGWICK, F.R.S.

III. " On Surfusion in Metals and Alloys." By W. C. ROBERTS-
AUSTEN, C.B., F.R.S.

IY. " Note on the Complete Scheme of Electrodynamic Equations of
a Moving Material Medium, and on Electrostriction." By
J. LARMOB, D.Sc., F.R.S.

V. " Aluminium as an Electrode in Cells for Direct and Alternate
Currents." By E. WILSON. Communicated by Professor
HOPKINSON, F.R.S.

VI. " Contributions to the Study of < Flicker.' " By T. C. PORTER.
Communicated by Lord RAYLEIGH, F.R.S.

VII. "On the Kathode Fall of Potential in Gases." By J. W.
CAPSTICK. Communicated by Professor J. J. THOMSON, F.R.S.

The Society adjourned over the Whitsuntide Recess to Thursday,
June 9.

" On the Intimate Structure of Crystals. Part I. Crystals of
the Cubic System with Cubic Cleavage." By W. J.
SOLLAS, LL.D., D.Sc., F.R.S., Professor of Geology in the
University of Oxford. Received January 20, — Read
February 3, 1898.

The remarkable advance in our knowledge of the constitution of
gases that has marked the latter half of this century has immensely
strengthened a belief in the doctrine of atoms. It is to this doctrine,
therefore, that we naturally turn to assist us in the study of the
intimate structure of solids. The solid, however, stands at the oppo-
site pole to the gas ; in the one the particles are unrestrained, free
to move about any axis, and along paths of comparatively wide

On the Intimate Structure of Crystals. 271

range, before exerting mutual action on each other ; in the solid, on
the other hand, they are so closely packed that in many cases the
abstraction of heat is accompanied by only a very inconsiderable
approach of the atoms to nearer proximity. Thus among metals,
that having one of the highest coefficients of expansion is indium ;
but this only contracts 0'00004< of its bulk for every degree centi-
grade that it is lowered below the ordinary atmospheric temperature ;
nor does it continue to contract at this rate, but at a continually
diminishing one, as its temperature is progressively reduced. A
metal with a very low coefficient of expansion is iridium, which
loses only O000006 of its volume for every degree that it falls in
temperature. Among non-metallic elements we may point to the
remarkable case of the diamond, which, with the small coefficient of
O'OOOOOllS, actually ceases to contract at all when cooled below
42° C. It may be possible by other means to effect greater reduc-
tions in the volume of solids, but so far as the withdrawal of thermal
energy is concerned, it evidently accomplishes but very little, at
least in the case of solids treated at a temperature considerably
below their fusion points.

The assumptions made in the study of gases are of the fewest and
simplest kind, but they include one that is of fundamental import-
ance in the investigation of solids, viz., that in some sense an atom
is a body occupying space ; it is only by making this admission that
deviations from important laws like Boyle's find an explanation.

The dominion of an atom over a certain region of space endows
that space with form ; what that form is we do not know, though we
may eventually discover. In the absence of knowledge it is permis-
sible to make some kind of assumption, and then to endeavour to
discover how far the consequences of that assumption accord with
ascertained facts. I propose to make the simplest assumption
possible, and to regard the volume of space appropriated by an atom
as having the form of a solid of revolution, and very generally of a
sphere. Within this space there exists something, the energy of the
atom, or a force of repulsion, or both, which preserves it from inva-
sion by other atoms' ; outside it there is something, a pressure or force
of attraction, which drives the atoms as close together as possible
without causing interpenetration. It will probably be found also
that these influences, pressures, and thrusts, are directed, or that the
atoms are polar.

Dalton's law of multiple proportions seems to meet with its counter-
part in crystallography in Haiiy's law of " the rationality of the
indices," and the conception by which Haiiy sought to explain this
and other facts relating to the form and structure of crystals
presents singular points of resemblance to Dalton's ideas of atoms.
Haiiy's views on crystalline structure appear to me to contain the

x 2

272 Prof. W. J. Sollas.

germ of a great truth, which subsequent refinements in the geo-
metrical treatment of the subject have to some extent obscured.

Recent work by Lord Kelvin, Mr. Tutton, and others, has given
great encouragement to those who cherish a hope of ultimately
arriving at some sure representation of crystalline structure ; but
the remarkable observations of Penfield* on the several species of the
mineral chondrodite are of an especially suggestive character. The
chondrodites present us with a homologous series of chemical com-
pounds, having the following constitution : —

No. of atoms of Mg.

(a) Mg3[Mg(F.OH)]2(Si04)2 5

(6) Mg6[Mg(F.OH)]8(Si04)s 7

(c) Mg7[Mg(F.OH)]2(Si04)4 9

As Professor Miers tells us, "the three minerals have almost the
same form, but differ only in the length of one crystallographic axis
(parameter). The lengths of this . . in the three minerals are in
the ratio of 5 : 7 : 9. Thus the addition of the olifine radicle,
Mg2Si04, exerts a so-called ' morphotropic ' action along one definite
axis, and causes a certain constant increase in the length of this axis
(parameter)." " It is further a curious fact that the length of this
(parameter) varies directly as the number of magnesium atoms in
the compound." The inference that the magnesium atoms are dis-
posed along this axis would seem to follow naturally.

Mr. Barlow has lately completed an investigation into the differ-
ent ways in which spherical bodies of different volumes may be
packed together so as to produce different crystal forms. His
method of treatment is general, and many of the arrangements of
atoms, which I am myself led to imagine as existing in certain
crystals, will, no doubt, be found to fall as special cases under his
general laws. But I do not propose in this communication to merely
suggest some way in which atoms regarded as spheres may be built
up into geometrical forms ; my purpose is different, it is to consider
csrtain particular substances, and to endeavour to discover the par-
ticular structure which must most rationally be assigned to them.
Further, to avoid misconception, it should be added that the "law of:
closest packing," which is so admirably developed by Mr. Barlow,
does not seem to be obeyed by the greater part of the crystals I have
investigated ; so far as the cubic system is concerned, there is but
one simple snbstance in which the atoms are as closely packed as
possible, that is the diamond.

It is a singular fact that crystals of the cubic system, when com-
posed of salts which are diatomic, such as NaCl,KCl, are character-
ised by a cubic cleavage, while those composed of triatomic salts
* ' Amer. Journ. Science,' vol. 47, p. 188.

I

On the Intimate Structure of Crystals.

273

such as cuprous oxide (Cu20), or fluorspar (CaF2), possess an octa-
hedral cleavage. Let us for the moment follow the hint given by
Haiiy, and regard the cubic crystals with cubic cleavage as reduced
by repeated cleavage to a primitive cubelet. How in the case of a
diatomic compound composed of atoms of different relative sizes, as,
say in common table salt, can the molecules be arranged together so
as to produce this cubelet ?

FIG. 1.

7- S

/VA.

v v

^ ^\

a..

? \

CL.

\. y

^ A

MA.

\^ 2

The only satisfactory way that I can discover is to place one mole-
cule (NaCl) by the side of another (ClJSTa), as in the diagram (fig. 1),
so that tangent planes to the pairs of atoms may form a square
prism, and then to rest on the top of this two more molecules, simi-
larly put together, the chlorine of the upper group resting on the
sodium of the lower, and the sodium of the upper on the chlorine
of the lower ; common tangent planes to the exterior of the spheres
taken in fours will be found to form a cube.

This is a simple and possible arrangement of the molecules of
common salt, but whether it alone and not some other is the actually
existent arrangement is a question for argument.

Ever since Kopp formulated his famous laws, the subject of
atomic volumes has possessed great interest for the chemist, though
the discrepancies which too frequently impair the correspondences
discovered by Kopp have evoked a general feeling of mistrust.

Nevertheless I am persuaded that in atomic volumes we possess the
touchstone by which our conjectural arrangements may be brought
to the test. The study of atomic volumes and crystalline structure
cast mutual light upon each other.

Kopp obtained his volumes by dividing the molecular weight (m)
of a substance by its density (d), thus m/d = v. Evidently if
atoms have the form of solids of revolution, this volume is a lump
quantity, including not only the volume of the atoms, but of the
interstices between them. We shall therefore speak of it as the
gross volume (V), in contradistinction to the true relative volume (v)
of the atom.

The shortest way of explaining our method of investigation will
be to describe at once the process as applied to the haloid compounds
of the alkali metals. Let us commence with common table salt. Its

274

Prof. W. J. Sollas.

molecular weight is 58-513 (Na 23'06 + 0135-453).* Its density,
corresponding to the specific gravity, found as the result of very
careful determinations by Retgers, is 2'167 at 17° C. The gross
volume is then 58'513/2'167 = 27'0002. If this number be multi-
plied by 4, it will give the volume of a primitive cubelet, supposed
to be built up of 4 molecules, as already described. The cube root of
this number (108*01) is 4' 7623, and represents the length of an
edge of the cubelet, or the sum of the diameters of the atoms of
sodium and chlorine, by which this edge is determined. The next
step is to endeavour to obtain some probable value for the ratio of
these diameters, that of the sodium to that of the chlorine atom.

It is quite certain if the sodium and chlorine atoms do not both
occupy the same space, that the volume of sodium, and the other alkali
metals, is very different in the free state and in combination. This
is a conclusion to which Kopp was led, who found that by assuming
a reduction of the volume in the free state to one-half when the
element entered into combination, he obtained fairly constant dif-
ferences on subtracting the half volumes of the metals from the
volumes of the chlorine salts. Our investigations support this
opinion of Kopp. In the following table data for investigation are
given for such haloid compounds as are open to study.

Metals.
Lithium .

Sodium 23-06

Potassium.. 39 '14

m.

d.

Y.

T,

F.

7-03

0-578

12-162

—

186-0°

—

0-589

11-936

—

—

13-06

0-984

23-46

0°/4°

95-6

19-14

0-865

45-25

15°

62-0

—

0-875

44-732

13°

— '.

m, atomic weight ; c?, density ; Y, gross volume ; T, temperature at
which sp. gr. was determined ; F, fusion point.

Salt. m. d. Y. T.

Lithium chloride. .
Sodium chloride .„
Potassium chloride
Lithium bromide. .
Sodium bromide . .

» • •

Potassium bromide
Lithium iodide
Sodium iodide
Potassium iodide. .
» • •

* In this and all subsequent cases the atomic weights are those given by Ostwald
to oxygen, 16, as a base.

ie. . . . 42-483

2-074

20-484

3-9

lo 58-513

2-167

27-0002

17-0

>ride . . 74-593

1-989

37-7503

16-0

de. . . . 86-993

3102

28-004

17-0

ie . . . . 103-023

3-079

33-404

17-0

...» —

3-198

32-217

17-3

aide . . 119-103

2-7

44-12

—

133-89

3-485

33-218

23-0

149-92

3-654

41-029

18-2

de. . . . 166-0

3-059

54-266

.... —

3-079

53-914

—

On the Intimate Structure of Crystals.

215

With the exception of the densities of sodium and potassium
chlorides, which have been very exactly determined by Retgers, the
densities given above cannot be regarded as more than approxima-
tions, not to be trusted in the second place of decimals, not always
in the first. If one-half of the volumes of the metals given in the
first table be subtracted from the volumes of the salts given in the
second, we obtain the following results : —

Y. Haloid

Salt.

V.

iV. Metal.

elements.

Lithium chloride ....

20-484

5-968

14-516

,, ....

—

6-08

14-404

Sodium chloride

27-002

11-73

15-272

Potassium chloride. . .

37-7503

22-625

15-1253

Lithium bromide ....

28-004

5-968

22-032

„ ....

—

6-08

21-92

Sodium bromide

32-217

11-735

20?487

Potassium bromide . .

44-112

22-625

21-487

Lithium iodide

138-318

6-07

32-23

Sodium iodide

41-029

11-73

29-299

Potassium iodide ....

53-914

22-625

31-289

„ ....

54-266

—

31-641

It will be observed that the difference between the gross volume of
the salts containing the same haloid element and the gross volume of
the metal they contain is approximately equal in all cases; thus,
the common difference in the case of the chlorides varies from 14'4
to 15-27 ; in the case of the bromides, from 20'487 to 20-032 ; in that
of the iodides, from 32'23 to 29"299. It was assumed by Kopp that
these differences corresponded to the volume of the haloid element.
We make the same assumption, and by treating the subject from
another point of view obtain a more consistent agreement between
the differences which represent the volumes of the haloids.

The system in which lithium bromide crystallises is not known ;
the same is true of lithium iodide, and these salts are in consequence
necessarily excluded from our inquiry. Neglecting them, it will be
seen by inspection that the greater the difference between the gross
volume of metal and the haloid with which it is combined, the
smaller is the value found for the volame of the haloid ; thus, in the
case of the chlorides, the smallest value found for chlorine is
14'4, and the disparity between the volumes of lithium and chlo-
rine is the greatest in the series. In the same way the bromine in
sodium bromide has a less volume than that in the corresponding
potassium salt, and the volumes of sodium and bromine are farther
removed from equality than those of potassium and bromine. This
is a necessary consequence of such an arrangement of spheres as

276

Prof. W. J. Sollas.

we have imagined to exist in the case of common salt, already
described, for it can readily be shown, and will presently appear,
that the ratio of the volumes of the eight spheres forming a primi-
tive cubelet to the volume of the interstices continuously diminishes
as the spheres approach equality, or, more precisely, the total volume
of the cubelet, including interstices, is to the volume of the con-
tained spheres as 1*9099 : 1 when the spheres are all equal, and
diminishes from this down to a limit, of which we shall have more
to say presently, of 1*7125 when the two kinds of spheres have
attained the greatest possible degree of inequality consistent with
the arrangement assigned to them.

Of the different possible modes of packing in the cubic system,
the one we have adopted is the only one that gives this result,
within the limits of difference in size which we are considering ; every
other kind of simple packing leads to an increase in the gross volume
when the two sets of constituent spheres depart from equality in dimen-
sions. There is but one exception to this statement, and this does
not affect our argument, as it is true of one particular ratio only,
and is not applicable to the haloid salts of the alkalies.

Returning now to the imagined cubelet of common salt, we are
able to give a value to the diameter of the sodium atom it contains ;
thus, the gross volume of the sodium is 11-73, one-half of the gross
volume of sodium in the free state ; suppose eight atoms of sodium
built up into a cube in the same way that the four molecules of
sodium chloride were imagined to be built up, one sphere to each
corner of the cube, then the edge of the cube will be equal in length
to the sum of the diameters of two sodium atoms. Thus, the gross
volume of sodium 11' 73 X 8 = 93*84, the gross volume of eight atoms,
and V93*84 = 4' 5443, the length of the edge of the cube ; this
divided by 2 gives the diameter of a sodium atom as 2*2721.* But
the length of the edge of a cubelet of sodium chloride was found to
be 4*7623 ; deducting the diameter of a sodium atom from this, we
have 4*7623—2*2721 = 2*4902, the diameter of an atom of chlorine.

Using the value found for the diameter of an atom of sodium as
a basis, we may proceed to treat all the haloid salts available for
examination in the same way as follows : —

Diameters of
atoms.

LiCl 4*3433

_C1 2*4902

Li = 1*8531

Diameters of
atoms.

KC1 5*3216

-01 2*4902

K = 2*8314

* This could of course be directly obtained from the gross volume, which might
be regarded as the cube circumscribing the sodium sphere ; but I am anxious to
preserve a parallelism in treating the salts and the elements.

On the Intimate Structure of Crystals.

277

NaBr . .

Diameters of
atoms.

5-051

KBr..

Diameters of
atoms.

5-6089

Na

2-2721

— K

2-8314

Nal ...

Br = 27789
5-4750

KI ...

Br = 2-7775
6-0099

Na

2-2721

_K

2-8314

I = 3-2029

1 = 3-1785

These results, however, are merely approximate,* for, as Professor
Miers has pointed out to me, the diameter of the second sphere in a
cube cannot be obtained by simply subtracting the diameter of the
other from the edge. Professor Miers shows that the relation
between the length of the edge of the cube (A) and of the radius
of the larger spheres (B) and of the smaller (r) may be expressed
by the equation —

(R+r)2 = [A-
from which he obtains —

or

E =
r =

1-8848

Cl

2-4954

2-2721

Cl

2-4954

2-8372

Cl

2-4954

2-2721

Br

2-807

2-8372

Br

2-772

2-8372

I

3-1957

2-335

I

3-1957

Employing this formula, the diameters of the atoms are found to
be as follows : —

Lithium chloride ........ Li

Sodium chloride .. ...... £Ta

Potassium chloride ...... K

Sodium bromide ........ Na

Potassium bromide ...... K

Potassium iodide ........ K

Sodium iodide .......... Na

There does not appear to be any sound reason why the volume of
an element should remain absolutely constant and independent of the
element with which it is associated, even in a homologous series, and I
am inclined to think that the differences which appear in our investi-
gation are not wholly due to defects in our knowledge of the specific

* It has since occurred to me that a slight modification in our conception of the
manner in which the atoms are arranged will render our determinations exact ;
this will be the case if we consider the atoms to be situated with their centres on
the nodes of a cubic lattice ; we shall recur to this in a subsequent part of this
communi catio n .

278

Prof. W. J. Sollas.

gravity of the different salts, but that they are real and of signifi-
cance. The difference in the coefficients of expansion for the different
haloids suggest a certain "want of constancy in volume. Thus,
Fizeau obtained for the linear coefficient of expansion of

NaCl 0-00004039

KC1 0-00003803

KBr 0-00004201

KI 0-00004265

4-49

5-15

9-78

16-76

and since it is improbable that the component atoms of these salts all
possess the same coefficient of expansion, it would seem that an
absolute constancy of relative volume is in a high degree impro-
bable. It is sufficient, however, for our purposes if it can be shown
that the deviation from constancy is confined to narrow limits, as
indeed, from the results so far obtained, appears to be the case.

The importance of these results for our inquiry is, however, this,
that they cannot be obtained by any other method of packing; other
methods, instead of minimising the differenced between the gross
volumes, would, on the contrary, exaggerate them.

The relative dimensions of the atoms already considered may be
tabulated as follows : —

Element. Diameter. Volume.

Li 1-8848 3-5059

Na 2-2721 6-1408

„ (inNal) 2-325 6'6659

K 2-8372 11-960

Element. Diameter. Volume.

Cl 2-4954 8-1274

Br (in KBr) 2772 H'1526

„ (in NaBr) 2'807 H'5804

I.. 3-1957 17-1276

In the next table the sum of the volumes of the atoms in a molecule
is compared with the gross volume of the salt, and exhibited in
the form of a ratio.

Salt. I.

LiCl 11-6333

NaCl 14-2682

KC1 20-0874

NaBr 17*7212

KBr 23-1126

Nal 23-7935

KI 29-0876

I. Sum of the volumes of the atoms.
II. Gross volumes of the salts.
III. Ratio of I to II.

II.

III.

20-484

1

1-7608

27-0002

1

1-8923

37-7503

1

1-8793

32-217

1

1-818

44-112

1

1-9085

41-029

1

1-7244

54-266

1

1-8656

On the Intimate Structure of Crystals. 279

It will be observed that in every case the ratio is smaller the greater
the difference between the size of the component atoms.

It may next be pointed out that there exists a very important
limitation to our power of arranging pairs of atoms or diatomic
molecules in the manner we have suggested ; the two atoms of the
molecule may be equal in size, or they may be unequal, so long as the
inequality does not exceed the value of 1 : 0*7286.*

I owe to the kindness of Professor Miers the following method of
finding the value of this limit. Let the centres of the spheres
be referred to three edges of the cube, meeting at one corner, as
the axes x, y, and z. The coordinates for the centre (Ci) of the
larger sphere are A— B, B, B, and for the centre C2 of the smaller
sphere r, r, r. Then

(CA)3 = (A-B-r)2+2(B-r)2.
In the limiting case, when the two larger spheres are in contact,

A = B(2+v/2),

.*. (CA)2 = B2(5 + 2v/2)-2Br(3+v/2)3r2.
Also (CA)2 = (B + r)2,

.*. B3(4 + 2v/2)-2Br(4+-v/2)+2r8 = 0.

BV B 5'4142 1

— =2-. 1 = 0.

rj r 6'8284 3'4142

.'. B/r = 0-7929 d=\/0-3358 = 1*3724 = l-*-0'72865.

When the smaller spheres fall below the limiting value 0'729 the
tangent planes to the spheres no longer define a cube, but a figure
which is a hemimorphic form of the rhombohedral or hexagonal
system ; and in all cases that I have yet examined of diatomic salts,
belonging to a homologous series crystallising in the cubic system
with cubic cleavage, I find that directly one of the atomic volumes
falls below this limit the salt passes out of the cubic system and
presents itself under hemimorphic hexagonal forms. This is the case
with silver iodide, which is fully discussed in the second part of this
communication. That the substances to which we have at present
restricted our attention consist of pairs of atoms which lie within
the prescribed limit is shown by the following table, in which the
ratios of the diameters are

* If the centres of the spheres be situated on the nodes of a cubic lattice, the
value of this limit will be changed.

280

Li _ 1-8848 _
Cl ~ 2-4954 ~

Na 2-2721

B7 = 2W = 0'8094'

K 2-8372

Prof. W. J. Sollas.

Xa, _ 2-2721
CT ~ 2^954

Br 2-772

0-977.

Cl 2-4954 _

K =^83-72 -°8792'

= - » 0-7307.

I 3-1957

K 2-8372

Maximum limiting ratio, 1 : 0'72865

If the arrangement of the atoms in the crystals under consideration
be, as I conceive, the actually existing arrangement, it is certainly
not the one to which views on close packing would have led us.
Nature does not appear to have been at all parsimonious of space,
and that atoms should be disposed in such comparatively open order
and yet produce structures of great rigidity, almost inevitably
suggests the existence of poles or directed forces. The importance
of the question renders it necessary to probe the matter deeper, and
we may naturally seek for further confirmation of our hypothe-
sis. Since the arrangement at which we have arrived is the most
open probable, we may expect if any other arrangements exist
to find evidence of closer packing. We turn, therefore, to the
evidence aiforded by solutions. In a solution the molecules are not,
as a rule, constrained to oscillate about fixed positions, they are not
built up into a solid architecture, but are free to glide over one
another, and to migrate from place to place. In their case open
packing is not to be expected; in the absence of arrangement, the
closest packing will prevail. Closest packing among equal-sized
spheres exists when one is surrounded by twelve others in contact.
It is the arrangement met with in triangular piles of round shot. In
a stack of this kind the ratio of the volume of the balls to the volume
of the pyramid they form, including interstices, is as 1 : 1*35.

On introducing a crystal of common salt into water the crystalline
edifice is destroyed, and the separated molecules become surrounded
by those of the solvent in closest packing. As the solution is made
very dilute the molecules of the salt are resolved into their ions,
which wander about in the solution, still under the influence of
internal pressures, adapting themselves to the law of closest packing.

Under these circumstances what change of volume is naturally to
be expected when common salt passes into brine ? Clearly a con-
traction, and that to a considerable amount, such, indeed, as is
always actually observed whenever the haloid salts of the alkalies are
dissolved in water. This general observation affords strong con-
firmation of the truth of our hypothetical arrangement, which
will be still further strengthened if we pursue the subject into
quantitative comparison. The ideas involved in the expression
atomic volume are less simple in the case of a liquid than in that of
a solid. In any case the atomic volume must be regarded as an

On the Intimate Structure of Crystals.

281

average effect, but in a liquid there are more factors to be inte-
grated. The results of the following investigation are necessarily,
therefore, only first approximations.

From the numbers which we have already assigned to the relative
volumes of the atoms the relative density follows from the relation
777 1® = d, and by dividing d by the factor 1*35 we obtain the density
of the substance, which would be produced by the atoms, when most
closely packed together. Data are given in the following table: —

Element.

Atomic weight.

Yolume of
atom.

Density.

D-M-35.

Li

7-03

3 -5059

2 -0009

1 -4853

Na

23-06

6 -1408

3 -7552

2 -7816

„ inNal.. .
K

80*-14

6 -6659
11 -960

3 -4594
3 -2727

2 -5625
2 -4243

Cl

35 -453

8 -1274

4 -3622

3 -2312

Br

79 -963

11-1526

7-17

5 -311

„ in KBr . .
I

126 '86

11 -5804
17-1276

6-905
7 -4238

5 -1148
5 -4991

The researches of chemists have given us exact determinations
of the specific gravity of solutions of the haloid salts of the
alkalies, and from these we may calculate the density of the ions.
From the equation A/cZi, B/W2 = 100/D, where A and B represent the
percentage of salt and water respectively, di and dz the density of
each, and D the density of the solution. The specific gravity of the
solutions examined will be found given in Watts' 'Dictionary of
Chemistry,' or Whetham's ' Solution and Electrolysis,' and need not
be repeated here ; they are derived from Gerlach's tables, published
in 1869, in the ' Zeitschrift fiir Analytische Chemie,' vol. 8, p. 245.
Wherever possible, I have selected for examination a solution con-
taining a gram-molecule of the salt to a litre of water. Making d± in
the equation above = %, its value, as found for the different haloid
salts, is given in the table below : —

Salt.

Density of
molecule.

Density of
molecule

-r-1'35.

Density found
from solution.

Number of
gram-molecules
in 1 litre of
solution.

LiCl

3-6518

2 -7051

2 -5585

1 '0

NaCl

4 -0741

3 -0178

3 -4605

1-0

KC1 . . . .

3-7134

2 '7507

2 -6731

I'O

NaBr . .

5 -8404

4 -3262

3-938

0 -9687

KBr

5 -1532

3 -8172

3 -4916

0*4198

Nal .j

6 '3009

4-6673

4-1118

0'721

KI

5 -7069

4-2273

3 -597G

1 "0

282

Prof. W. J. Sollas.

As close a correspondence appears as could be expected from the
conditions of the case, and it would seem that the crystalline struc-
ture attributed to the haloid salts, while inconsistent with no known
group of facts, is in quantitative accordance with all that we have
investigated, and throws unexpected light on hitherto recondite
phenomena. The subject of solution must not, however, be left
without giving the densities found for more dilute solutions : they
are shown in the following table : —

Salt.

Gram -molecules
per litre.

Specific gravity of
solution.

Calculated density

of molecule.
\

LiCl

0*1

1-0021

3 '6093

NaCl

0*1

1-0038

5-557

KC1

O'l

1-0046

3 -9989

NaBr

0 -4854

1-04

4 '7223

KBr

0-072

1-0063

3-488

Nal

0-346

1 -0374

3-993

KI

O'l

1 -0112

4 -2709

Some of these numbers are less concordant with the density
deduced from the crystalline structure than those obtained with
stronger solutions, as presented in the preceding table, but it is to be
remarked that whatever errors exist in the observations are all
thrown on to the values we have obtained ; the numbers given in the
third column bear all the burden of error arising when dealing wifch
very minute quantities. To show how greatly our results are influ-
enced by slight variations in specific gravity, as given in the second
column of numbers above, I have calculated backwards from the
density of the atoms to find what specific gravity should give us
identical values for the density, as calculated from the crystalline
structure and from solution. It is not necessary to give the results
for more than two salts ; in the case of potassium chloride the
specific gravity of the solution, to accord with theory, should be
1-0038 instead of 1*0046 observed, to reduce the density 3 -9989 to
2*7668, its value on the assumptions we have made; in the case of
sodium chloride the specific gravity should be 1*0019 to give a
density of 3*0467, instead of the 1*0038 found. Although different
observers do not always give the same specific gravity for the same
solutions of salts, it is certain that the discrepancies between theory
and observation before us are not to be explained away by blaming
the observations ; we have before us an interesting residual pheno-
menon, susceptible of more explanations than one.

It will be observed that those salts the density of which is in
excess of that predicted, are those whose volumes are relatively

On the Intimate Structure of Crystals. 283

small. It is only when the ions possess a volume identical with that
of the molecules of water that exact agreement between theory and
observation can result. The molecular volume of water at 15° is
0'9987/18'006 = 18'083, and if its molecules are closely packed, the
true molecular volume will be obtained by dividing this number by
1-35; this gives 13'395 ; the diamete? of the molecular volume is
2*9465. Comparing the diameter of the ions with this, taken as
unity, we have : —

Water* TO

Li 0-6289

Na 07711

K 0-9609

01 0-8259

Br 0-9472

1 1-0828

It will be seen that the ions of potassium bromide and iodide
make the nearest approach to equality with the atomic volume of
water, and should consequently give the most accordant results with
theory ; this will be found to be the case on reference to the tables,
the differences which appear are well within the limits of experi-
mental error. The chlorides are all characterised by giving to
theory a density which is in excess.

Alternative explanations may be offered ; on the one hand, the
molecular volume of water has been taken as spherical, because its
molecules are most probably in rotation, but it is quite within the
bounds of possibility that the ions in their migrations may roll upon
the constituent atoms of the water molecules, and thus to some
extent invade the boundary of the molecular volume.

In the case of the smaller ions with relatively small volume this
would lead to a considerable increase in the calculated density, while
in the case of the larger ions it would be scarcely affected. It is
also possible when the commingled spheres of the ions and water
molecules are of a diameter bearing a certain rabio to each other
that closer packing may be brought about, so that the volume of
interstices we have allotted to the smaller ions would be reduced ;
this is a question for geometers.

The crystallographic study of these salts remains for consideration.
There are two ways in which the primitive cubelets may be arranged
in the construction of crystals : they are shown in plan in figs. 2 and
3; both give homogeneous assemblages in the cubic system, but
that shown in fig. 3 is holohedral, that in fig. 2 is hemihedral.

* March 4. — But, as Eamsay and Shields have shown, the molecule of liquid water
includes four molecules of the formula H2O ; the difference between its dimensions
and those of the ions is therefore greater than is given here.

284

Prof. W. J. Sollas.
FIG- 2- FIG. 3.

When, as until recently, sodium chloride was assigned a holo-
hedral symmetry, it would have been natural to suppose that the
arrangement of its molecules was that of fig. 3 ; but lately it has
been placed among hemihedral crystals with which potassium chlo-
ride has long been associated. The structure of these salts, and
judging by analogy of most of the alkaline haloids, is thus that
represented by fig. 2.

It is of interest to observe that in the holohedral arrangement
similar atoms are brought into contact ; this is not the case with
hemihedral symmetry. Perhaps in this is to be found an explana-
tion of the fact that diatomic compounds of monads do not possess
holohedral symmetry.

A plagiohedral asymmetry is revealed in the structure both of
common salt and potassium chloride by the action of solvents, which
produce etch-figures bounded by faces of a hexakis-octahedron.
The factors which determine the forms produced by solution are
unknown, but probably include the disposition of the chemical bonds
of the atoms in the molecule, and the relation of the water molecules
to the disposition of the atoms in the crystal. It is evident, how-
ever, both from models and figure that there is a skew in the distri-
bution of the chemical bonds of our molecules, and this may be
connected with the skew faces produced by solution.

Planes can be drawn through the assemblage of fig. 2 parallel to
the faces of the cubelets without crossing any of the molecules;
these may be regarded as planes of cleavage.

When a cube of rock salt is truncated at two opposite edges,
parallel to planes of a rhombic dodecahedron, and pressure is
exerted on the crystal in a direction normal to these faces, a per-
sistent compression results in the direction of the diagonal, and
accompanying this a doubly refracting stripe appears. With in-
creased pressure a clean fracture is produced, parallel to one of the
rhombic dodecahedral faces to which pressure is applied.

All this is in complete consistence with the structure hypothetic-
ally assigned to the crystal. The effect of pressure, as I imagine it,

On the Intimate Structure of Crystals.
FIG. 4.

285

is shown in the diagram (fig. 4), the molecules are forced to slide
over each other ; those lying on the diagonal along which pressure
is exerted make a nearer approach to each other ; those at right
angles are driven further apart. Up to the critical point, compres-
sion and accompanying anisotropy are produced; beyond it the
gliding plane becomes a plane of fracture.

The question of elasticity must be left to elasticians ; but I would
venture to point out the facts elicited by Voigt and Koch ; Yoigt
found for the elasticity modulus of rock salt a coefficient of
4170 kilograms per square millimetre parallel to the tetragonal axes
or edges of the cube, 3400 kilograms parallel to the digonal axes or
normal to the rhombic dodecahedral faces (110), and 3180 kilograms
parallel to the trigonal axes or normal to the octahedral faces (111).
Koch found for potassium chloride, 4009 kilograms parallel to the
tetragonal axes, and 2088 kilograms along the digonal axes. Voigt
obtained very similar quantities. Looking at the plane of assemblage
given in the figure (fig. 2), one would suggest that these results are of
a kind to be expected ; the force exerted along the tetragonal axis is
chiefly effective in producing compression of the atoms, along the
diagonal axis in distorting the structure. An exact correspondence
is obtained by Lord Kelvin between the theoretical elasticities of a
hypothetical cube and the results obtained by direct measurement of
potassium chloride, but the correspondence does not extend to the
results of observation for rock salt, and the structure we have assigned
to our crystals is not that considered by Lord Kelvin in his investiga-
tion.*

The hardness of rock salt in different directions has been investi-
gated by Exner, who finds that its value is at a maximum parallel to
the edge, and at a minimum parallel to the diagonals, of the face of
a cube. This result was obtained by determining the weight, with
which it was necessary to load a finely pointed needle, to cause it to

* " On the Elasticity of a Crystal according to Boscovicli," ' Roy. Soc. Proc.,*
Tol. 54, p. 69.

VOL. LXIII. Y

286 Prof. W. J. Sollas.

scratch the face of the crystal. It was found that if it required a
load of one to produce scratching parallel to the edge of a face of the
cube, a load of 1'3 was necessary parallel to a diagonal. Looked at
broadly, it will be seen by reference to the figure that the effect of a
force acting parallel to a diagonal should be to that acting parallel
to a side, as 1 : \/2, i.e., as 1 : 1'414. Considering how complicated
the problem actually is, this correspondence is quite as close as could
possibly be expected.

By several distinct lines of argument, resting on the study of
molecular volumes, of the density of solutions, of the symmetry and
physical characters of crystals, we have been led to the same result ;
given the atomic volumes in the ratios we have assigned to them, no
other was possible ; and we may now with greater confidence
proceed to the investigation of other diatomic compounds, which
will be found to throw a surprising light on the molecular tactics of
crystals.

" On the Intimate Structure of Crystals. Part II. Crystals of
the Cubic System with Cubic Cleavage. Haloid Com-
pounds of Silver." By W. J. SOLLAS, LL.D.,D.Sc., F.R.S.,
Professor of Geology in the University of Oxford. Re-
ceived January 27, — Read February 3, 1898.

The haloid compounds of silver offer more points of interest in the
study of crystal tactics than those of the alkalis, especially as they
include that remarkably anomalous substance — iodide of silver.

Silver itself crystallises in the cubic system, and possesses the
same kind of structure as all other metals which possess cubic
symmetry, i.e., its atoms are arranged on the plan of most open
packing: unlike the alkali metals it undergoes no change of volume
on entering into combination. Its atomic weight is 107'93 ; its
density has been differently determined by different observers, for
silver heated in vacuo Dumas found IO512, and Roberts- A usten
10*57; we take the mean of these numbers 10'541. The atomic
weight, 107-938, divided by 1O541, gives 10*233, the gross atomic
volume. From this the diameter of the atomic sphere is found to bo
2-17152, and its volume 5'3616.

Both the chloride and bromide crystallise in the cubic system,
and are regarded from analogy as possessing the same crystalline
structure and symmetry as the corresponding salts of potassium and
sodium.

The specific gravity of silver chloride is obtained from the solid
after fusion. The latest determinations give for silver chloride a

On the Intimate Structure of Crystals.

287

specific gravity of from 5*517 to 5*594, and for silver bromide from
6'215 to 6'425. Data for calculation are given in the table : —

AT

M.W.

Specific
gravity.

Gross
volume.

Diameter of atomic
sphere or edge of
crystal cubelet.

107-938
143 -391

187 -901
234-798

10 -541
5-517
5-594
6-215
6-425
5 675

10 -233
26 -249
26 '615
30-233
29 -246
41 '374

2 -1715
4 -7175 (a)
4-7395 (5)
4-9452 (a)

4-8907 (5)

AgCl . . .

AgBr. . ,

AgT2

Salt, gross volume.

Silver, gross volume.

Difference of gross volume.

AgCl .... 26 -249
26-615
AgBr. ... 29 -246
30 -233
Agl 41 -374

10 -213

»
55

55
55

16 '036 chlorine (a)
16-402 „ (5)
19 -033 bromine (a)
20-02 „ (J)
31-141 iodine.

We are now in a position to compare the diameter of atoms of
silver in the free state and in combination. The diameter of chlorine
being taken as 2'4954, the. value found in Part I, and that of
bromine 2'801, its value in sodium bromide, we obtain from Pro-
fessor Miers' formula —

Diameter of Ag in —
AgCl. AgBr.

(a) 2-2279 (a) 2-1784

(6) 2-2399 (6) 2'1307

The results for (a) and (&) correspond to the different specific
gravities (a) and (6) given above, and obtained by different
observers.

The differences between the diameters (a) of silver in combination
and that it possesses in the free state are not great.

On comparing the gross volumes of the haloids given above with
their gross volumes in the haloid compounds of the alkalis, it will
be observed that the gross volume of bromine in silver and sodium
bromides is closely correspondent ; this is because the atomic volumes
of sodium and silver have nearly the same relative value.

Silver iodide, to which we now turn, is one of the most interesting*
substances we have yet encountered, and most important results
follow from its study. At ordinary temperatures it does not present

T 2

288 Prof. W. J. Sollas.

itself in the cubic system, but in hemimorphic Hexagonal crystals.
For this reason we cannot, by the method we have previously em-
ployed, calculate the diameters of its component atoms, but a refer-
ence to the preceding table will show that the gross volume of the
iodine is not greatly in excess of that which it possesses in sodium
iodide, so that in all probability its atomic volume is the same, or
sufficiently similar to serve as basis for argument. The diameter of
the silver atom is then 2'1715, that of the iodine 3'1905. The ratio
of the diameter of the silver to that of the iodine falls consequently
below the limiting rates of 0'7286 : 1"0. The exact ratio both for
this and the constituents of the other silver compounds is given in

the following list : —

Ratio of
diameters of atoms.

Ag : Cl = 0-8928 : 1
Ag : Br = 0-7761 : 1
Ag : I = 0-6894 : 1

From this it is evident that while the chloride and bromide are well
within the 0"728 limit, the iodide lies outside it ; and it follows from
our hypothesis that while the two former salts may be, as they are,
cubic, the iodide should not, but might be hexagonal hemimorphic,
as it is.

When silver iodide is heated it contracts along the vertical axis (c)
and expands in directions normal to this, till at a temperature of
146° C. it passes per saltum into the cubic system, and then with
further rise of temperature expands uniformly. The transition
from the cubic to the hexagonal system on cooling is accomplished
almost with explosive violence, fragments of the solid iodide are
projected into the air, and deep clefts extend into its substance.
How on the basis of our reasoning is this curious transformation to
be explained ? Only on the supposition that the atomic volumes
expand as the temperature of the substance rises ; the mass, as a
whole, may contract, as it certainly does, but this is to be accounted
for by a change in the relative position of the atoms, the atomic
volumes themselves must be conceived as all the time expanding.
But it may be asked, is there any reason why the iodine and silver
should expand at the same rate, and if not, which is the more likely
to possess a higher coefficient of expansion, the iodine or the silver
atom ? The probabilities are all in favour of the iodine. The co-
efficient of expansion of silver in the free state is 0*000037 from 0°
to the melting point, and 0'00002 from 0° to 100° C. That iodine
has an immensely greater coefficient may be judged from the change
in its specific gravity with rise of temperature, thus at 40'3°
its sp. gr. is 4-917 ; at 60°, it is 4'886 ; at 79'6°, it is 4'857 ; at 107°,
just before it liquefies, it is 4'825 ; after liquefaction, it is 4'004 ;

On the Intimate Structure of Crystals. 289

and at 151°, a point just above the temperature at which the hex-
agonal form of silver iodide is exchanged for the cubic, it is 3'866.

We may fairly therefore attribute the greater expansion to the
iodine, the silver probably undergoing but slight increase in bulk.
In what way does this help us ? If the disparity between the
volumes of the atoms were originally the cause which determined
the silver iodide to assume hexagonal instead of cubic symmetry,
how, by increasing this disparity, shall we render it cubic? Nothing
can be simpler. By the time the substance has reached 146° C. the
atomic volume of the iodine has become so great relatively to the
silver that the latter is lost in the interstices, and it is the iodine
alone which is directly operative in supporting the crystalline
edifice. Here we have a basis for calculation. If the iodine thus
forms the framework of the crystal, it must be, as we shall show
later, because it is packed on that open system which we have
already described and illustrated in the first part of this communi-
cation. From this the diameter of the iodine spheres can be calcu-
lated.

The volume of silver iodide, as deduced from Rodwell's data, is
40%67, just above 142°, the point which Eodwell gives as the critical
temperature for the change of system. Supposing, as we have
already stipulated, that the iodine is built up in most open cubic
packing, we find from this volume the number 3*439 as the length
of the diameter of the iodine atom.

We shall make important use of this number directly, but we
must first endeavour to find a probable structure for the silver iodide
when crystallised in the hexagonal system.

It will conduce to clearness to avoid discussion at this stage, and
to describe at once the structure which I am led to think is the only
possible one consistent with the crystalline and physical properties
of the compound. Let us regard the silver and iodine spheres as
directly united together to form molecules of Agl ; conceive these
placed on a horizontal plane with their major axes vertical, and dis-
posed in triangular order as in the diagram (fig. 1). The balls must
not be in contact laterally, but separated by definite regular intervals ;
over this first sheet place a second similarly formed, and so related to
the first that the silver atoms rest in the alternate intervals left between
the lower set of iodine balls taken in threes (fig. 2). The assemblage
so produced will be homogeneous, hexagonal, and hemimorphic. It
represents silver iodide as it exists at ordinary temperatures. Now,
bearing in mind the fact that every silver atom rests in the interval
between three iodine atoms, let the latter enlarge to a slight extent,
and simultaneously retreat from each other along the horizontal
plane to a small but uniform amount. This corresponds to the
expansion along the lateral axes on heating. But as a result of this

290

Prof. W. J. Sollas.

FIG. 1.

Plan of first sheet of molecules of Agl.

One molecule of Agl shown in elevation.

FIG. 2.

Plan showing two sheets of molecules of Agl.

On the Intimate Structure of Crystals. 291

expansion the atoms of silver will descend deeper and deeper
between the atoms of iodine, and the distance between successive
sheets in a vertical direction will diminish. This corresponds to
contraction along the vertical axes with rise of temperature. On
this hypothesis the anomalous contraction of silver iodide ceases to
be an anomaly, but follows as a natural, though by no means neces-
sary, consequence of its crystalline structure.

At the critical point, when the hexagonal is exchanged for
cubic symmetry, the atoms of iodine possess, as already shown, a
diameter of 3*439. Let them be represented in plan in the relative
positions they must occupy for open cubical packing. They are
shown in fig. 4 by a section taken at right angles to a trigonal
axis.

Measured along the edge of the cube, the intervals between the
atoms from centre to centre must, on this system of packing, be to
the diameters precisely as vx2 : 1. Find the diameter of a small
sphere that will just fit in between the three spheres as represented
in the section. It is exactly 2*17687. But we have already found
that the diameter of an atom of silver, both in the free state and in
combination, measures at ordinary temperatures 2*1715, an extra-
ordinary coincidence. The difference between this number and
that just obtained, 2*1769— 2*1715 = 0*0054; again, the difference
between the diameter of the atoms of iodine in the alkaline iodides
at ordinary temperatures and the atoms of iodine in silver iodide at
142° is 3-439—3*2 = 0*239, and these two numbers (0*0054 and
0*239) probably approximately represent the change in dimension
of the constituent atoms of silver iodide as the temperature of this
substance is raised through a range of 130°. Calculating from the
coefficients given by Fizeau, the expansion of 0*0054, which we have
found for the silver, is just twice that which it would experience in
the free state.

Up to the critical point, when the interval between the iodine
atoms has become large enough to allow the atoms of silver to pass
between them, the atoms of silver have been supported by the atoms
of iodine and have supported iodine in their turn • all the atoms
have been subject to molecular pressure, but directly the critical
position is attained, the atoms of silver are driven by this internal
pressure into the middle of cubical clusters of atoms of iodine and
partly or wholly released from pressure, the atoms of iodine alone
then sustaining the crystalline fabric. It is not wonderful under
these circumstances that the spectrum of silver iodide should differ
markedly when observed below and above the critical point. Thus
Wernicke has observed that at a high temperature the spectrum (of
silver iodide), like that of solid and liquid iodine, contains no blue
nor violet light. In the normal state, below 138° C., silver iodide

202 Prof. W. J. Sollas.

gives a spectrum less bright, but twice as long and particularly
developed in the blue and violet spectrum.*

The passage of silver iodide from one form to the other is, as has
been stated, sudden and abrupt. This necessarily follows, from the
geometrical conditions of the case. On reference to fig. 5 it will be
seen by inspection that while a gradual descent of the atoms of
silver may take place so long as their centres are situated above the
centres of the atoms of iodine, against which they glide, yet directly
after they come to lie in the same plane, a sudden descent must take
place to a definite extent, which is given by the formula DOi — DO2
= n+»2— 2ri cos0, or by the equivalent -/(Sr^2— 4^), where n is
the radius of the large spheres, r2 of the small spheres, and Oi02 the
distance through which a sudden descent occurs.

The instantaneous descent of the silver which thus takes place is
accompanied by a sudden change of volume in the compound itself ;
as determined by Rod well, the volume diminishes from 1 '01575 to
TO, as the temperature passes above 142°, the maximum density of
the salt then being attained. In the collocation of spheres which
we have imagined, it is possible to compare the bulk before and
after the critical point is passed very simply. A tetrahedron is
constructed by joining the centres of three spheres of iodine below,
which are in contact with one of silver lying on the axis above, with
a fourth of iodine, also on the vertical axis and attached to the
single sphere of silver. The ratio of the volume of this tetrahedron
is directly proportionate to the whole volume of the structure,
whether in the cubic or hexagonal systems, and at the critical point
the volumes are directly proportionate to the heights of the respec-
tive tetrahedra. From this we find that the volume before contraction
is to that after as 114 : 100, amply sufficient, and, it might be
objected, superfluous ; for the contraction, as observed by Rodwell,
only amounted to from 1016 to 1000. This is a case, however, in
which theory proves more correct than observation, for Mallard and
Chatelier have shownf that Rodwell's results are erroneous, owing-,
as they remark, to his having deduced the cubical expansion from
the linear extension, as though silver iodide were an isotropic body.
These observers were able to bring about the transformation from the
hexagonal to the cubic structure by the application of pressure
(4,000 kilograms to the square centimetre), and they found that
the ratio of the volumes before and after change, was as 116 to 100,
which gives a coefficient ten times as great as that of Rodwell, and
very closely in agreement with that (114) which we have theoretically

* Wernicke, ' Pogg. Ann.,' vol. 143, vide Rodwell, ' Proc. Boy. Soc.,' vol. 25,
p. 206. Wernicke accounts for this by supposing some of the iodine to be liberated
from combination.

f 'Bull Soc. Min.,' vol. 7, 1884; ' Journ. Phys.,' vol. 4, p. 305, 1885.

On the Intimate Structure of Crystals. 293

deduced. Under the influence of rising temperature, the change
was smaller, from 111 to 100, but this value is said to be merely
approximate. That the change of volume should be smaller is not
unintelligible ; the direct effect of pressure is to bring about a
change of configuration, which is unstable, since the substance
reverts to its original state directly the pressure is relieved; the
direct effect of heat, on the other hand, is to produce an expansion
of the atomic volumes, and the change of configuration follows only
as a consequence of this. In the difference between the value 111
and 116 we should have a measure of this increase in atomic
volume, but for the probability that an expansion of atomic volume
may take place, as a consequence of the change of configuration
which results from the action of pressure. It is of interest to note
that the amount by which the pressure must be reduced to reverse
the operation and bring back the substance to the original state is
only one-half of that required to produce the change directly ; the
reversal also takes place much more rapidly than the direct trans-
formation.

It is to the beautiful observations of Fizeau that we owe our
knowledge of the change in dimensions of silver iodide measured in
relation to its crystalline axes. Along the axis c, Fizeau found a
negative coefficient of expansion of — 0*00000397; along two rect-
angular axes in a plane normal to c he found a positive coefficient of
0'00000065. These were for a mean of 40° over an interval of from
—10° to 70°; the coefficient of variation Aa/A0 was found to be for
c — 4*27, for the other axes T38. Thus for the mean temperature
the coefficient of contraction is six times that of the coefficient of
expansion. A very significant relation, but not more so than the
fact that the contraction increases as the temperature rises, and, as
Bodwell's observations seem to prove, the increase becomes very
considerable as the temperature rises above 70°. Every geometer
will perceive at once that these relations are in absolute har-
mony with the conception we have framed of the ordering of the
molecules in the crystal. They directly depend on the changing
ratio of the sine and cosine of the angle 9 as the small sphere (Ag)
of the figure (fig. 6) is squeezed out from the three larger spheres
(I) against which it is pressed (only one of these spheres (I) is
shown in the figure). As the iodine atoms approach each other,
with fall of temperature, the line aC will revolve round a as a
centre, and thus the vertical parameter will expand as the hori-
zontal contracts. From the coefficients given by Fizea.u, it follows
that at his mean temperature of 40° the angle 9 is 9° 18' ; from the
crystallographic measurements of Zepharovich, made presumably at
the ordinary temperature of the air, and therefore at or about 15°
this angle appears to have become 22° 17', as calculated for me by

294

Prof. W. J Sollas.
FIG. 3.

Vertical section through one edge and centre of a face of a rhombohedrcn of

three sheets.

FIG. 4.

FIG. 5

FIG. 6.

On the Intimate Structure of Crystals. 295

Professor Miers. The ratio of sine and cosine for this angle is
0'41 : 1*0, which gives the relation that should subsist by hypothesis
between the coefficient of expansion along the axes a and c at
15° C. Fizeau's observations fail us here, and I look forward
with interest to fresh determination^ of these constants, which
Mr. Tutton has kindly promised to make for me. It is now
possible to trace out the series of changes which silver iodide un-
dergoes as it falls in temperature from 150° downwards ; at 146°
(Mallard and Chatelier) or 142° (Rodwell) it possesses cubic symmetry,
because the atoms of iodine are out of all proportion so much
larger than those of silver, that the latter cease to be operative as
elements in the crystalline structure ; the iodine atoms are arranged
to form cubes which we may picture to ourselves as rhombohedra
with an angle of 90° j every iodine atom is chemically united
with an atom of silver which depends from it into the central space
within a rhombohedron ; as the iodine atoms become smaller, with
loss of energy, this space becomes too small to contain the silver
atom which is consequently forced outwards or upwards ; as it passes
out of the rhombohedron of 90° the vertical parameter of the latter
is necessarily lengthened, while its horizontal parameters are
shortened ; the change in dimension of the vertical parameter,
which occurs as soon as the centre of the atom of silver begins to
move above the plane containing the centres of three surrounding
iodine atoms, is excessive as compared with that of the horizontal
parameter, but the difference is diminished by the diminishing ratio
between the diameters of the two different kinds of atoms ; at 15° the
difference of the two coefficients is probably nearly as 3 : 1 ; it will dimi-
nish rapidly with further cooling, and, before the atoms of silver assume
a position in which the radius vector drawn from them to the iodine
atoms, about which they revolve, makes an angle of 45° with the
parameter Oa, the expansion along the vertical axis will cease and
be replaced by contraction, unless, indeed, as this crisis is approached
the diameters of the atoms should fall within the ratio of 1 : 0*729,
when the crystal would once again become cubic.

In the study of molecular volumes we hold the key which is
destined to unlock the secret of crystal structure so long concealed.
We shall eventually discover by its means, in connection with other
studies, the relative and absolute dimensions of all the elementary
atoms, and probably not only this but also their true forms — for it
is possible that they are not all spheres.

296 Prof. W. J. Sollas.

"On the Intimate Structure of Crystals. Part III. Crystals
of the Cubic System with Cubic Cleavage." By W. J.
SOLLAS, LL.D., D.Sc., F.R.S., Professor of Geology in the
University of Oxford. Received March 8, — Read March 17,
1898.

The remaining metals and diatomic compounds which crystallise
in the cubic system and possess cubic cleavage are few in number ;
some of them form the subject of the present communication. Tri-
atomic compounds fulfilling these conditions are left for later con-
sideration.

Ammonium chloride. — M. w., 53*506 ; sp. gr., 1'52 (Schroder) ; m. v.,
35-201. Volume of four molecules, 35'2 x 4 = 140'8.

Edge of cubelet, or sum of the diameters of one mole-
cule of NH4 and one atom of 01., V140'8 5'204

Diameter of one atom of Cl ........................ 2'4954

...................... 27134

Gross volume of KE4, 2'71343 = 19'98 ; volume of molecular sphere
of NH4, 19-98 Xi7r = 10-46.

Galena, PbS.—M. w., 238'97 ; sp. gr., 7'25 to 7'77 (7'513 taken);
m. v., 31-78; volume of four molecules, 31- 78x4 = l27'12.

Edge of cubelet or diameter of Pb+ S . . . . 5'028

Diameter of one atom of Pb ............ 2'625

S ............ 2-408

Lead enters into combination without change of volume. Gross
atomic volume of Pb, 2'6253 = 18' 1 ; volume of atomic
sphere, IS-lx-^ = 9'481. Gross volume of S, 2'4t)83 =
13-96.

Lead selenide, PbSe.— M. w., 286'01 ; sp. gr., 8'154 (Little) ; m. v.,
35-076. Volume of four molecules, 35'076 x4 = 140*305.

Edge of cubelet or diameter of Pb + Se . . 5'1962

Diameter of one atom of Pb ............ 2*625

„ Se ............ 2-571

Gross volume of Se, 17'0 ; volume of atomic sphere, 8'9.

Of the oxides which crystallise in the cubic system with cubic
cleavage only three are sufficiently well known to afford data for

On the Intimate Structure of Crystals. 297

treatment ; these are calcium, magnesium, and stannous oxides. The
metals calcium and magnesium undergo a considerable amount of
condensation on entering into combination ; it will therefore be more
convenient to select stannous oxide as the compound which is to serve
as the basis for obtaining the relative diameter of oxygen ; but this
course is not without its disadvantages, for very different values have
been found by different experimenters for the specific gravity of
stannous oxide, and the same is true of the metal tin itself, which
further has the additional defect of crystallising, not in the cubic,
but in the tetragonal system.

Tin.— At. w., llS'l ; sp. gr., 7'0 to 7*5 ; mean, 7*25 (taken).

Gross atomic volume, 16*29 ; volume of atomic sphere, 8*53.

Diameter of atom, 2*535.
Stannous Oxide, SnO.— M. w., 134*1 ; sp. gr., 6*1 (Nordenskjold),

6-6 at 0° C. (Berzelius, Ditte). The latter value is taken.

M. v., 20-313. Volume of four molecules, 81'273.

Edge of cubelet or diameter of SnO 4*3316

Diameter of one atom of Sn 2*535

O 1*8508

Gross volume of oxygen, 6'34 ; volume of atomic sphere, 3*32.

Calcium oxide, CaO. — M. w., 56 ; sp. gr., 3'251 ; m. v., 17'25.
Volume of four molecules, 17'25x4 = 68'9.

Edge of cubelet or diameter of CaO 4'100

Diameter of one atom of O 1*851

Ca 2*27

Gross volume of Ca, 11*695. The gross volume of Ca in the
metallic state is 25*48.

Periclase, MgO.— M. w., 40*38 ; sp. gr., 3'636 ; m. v., 11*105.
Volume of four molecules, 44*423.

Edge of cubelet or diameter of MgO .... 3*5416

Diameter of one atom of O 1*851

Mg 1-6936

Gross volume of Mg, 4*858. The gross volume of Mg in the
metallic state is 14*341. It crystallises in the hexagonal system.
These results are more or less uncertain ; it must be borne in mind
that the volume of oxygen differs greatly in different compounds.

The metals which remain for consideration in the present com-
munication are as follows : —

298 Prof. W. J. Sollas.

Copper. — At. w., 63'8 ; sp. gr., 8'945 ; at. v., 7'0766. Volume of

atomic sphere, 3'7053; diameter, 1'92.
Gold.— At. w., 197-2; sp. gr., 19'33 at 17'5°; at. v., 10-202.

Diameter of atomic sphere, 2'169.
Iron.— At. w., 56 ; sp. gr., 7'85 at 16° (Caron) ; at. v., 7134.

Diameter of atomic sphere, 1*925; or sp. gr. 8'139 (Roberts

Austen) ; at. v., 6'88 ; diameter of atomic sphere, T902.
Manganese.— At. w., 55; sp. gr., 7'3921 at 22°; at. v., 7'44.

Diameter of atomic sphere, 1*952.
Platinum.— At. w., 194-8; sp. gr., 21'5 at 17'6° ; at. v., 9'0605.

Diameter of atomic sphere, 2'085.
Palladium.— At. w., 106; sp. gr., 11'4 at 22'5°; at. v., 9'2983.

Diameter of atomic sphere, 2' 103.

The Absorption of Hydrogen by Palladium. — Strong confirmatory
evidence of the existence of the open packing which we have assigned
to the metals crystallising in the cubic system is afforded by the
phenomenon of solid solution (so called), and particularly by the
absorption of hydrogen by palladium. "When similar spheres are
arranged in open cubic order, they form straight rows in contact,
running parallel to the edges of the cube they constitute, and corre-
sponding to these files of spheres are open galleries, lying between
and running parallel with them. Through these galleries atoms, if
small enough, might pass from end to end without encountering any
obstacle, and thus the transpiration of hydrogen through metallic
plates might be explained. Further, between every set of eight
atoms, forming a primitive cube of the pile, the gallery widens out
into a chamber, in which an atom smaller than that of the metal
might conceivably lodge. The diameter of an atom which could
occupy the space between eight atoms, forming a primitive cube, of
palladium, can readily be calculated. The diameter of an atom of
palladium has already been determined to be 2' 103, the edge of a
cubelet formed of eight atoms is therefore 4'206, and the length of
the trigonal axis of such a cube is 4'206 x \/3 = 7'285 ; and (7'285 —
4'206)/2 = 1-538, the length of the diameter of an atom, which
would just occupy the central space. This estimate, however,
requires modification, by virtue of the fact that palladium progres-
sively increases in volume as the absorption of hydrogen takes place.
In Dewar's determinations the expansion was measured by the
change produced in the specific gravity of the palladium; the lowest
specific gravity which Dewar observed was 10'8033 ; this gives for
the edge of the primitive cube a value of 4'2818. Assuming that
the atoms of palladium have not increased in volume by absorbing
energy, but have simply become more remote from one another, we
may proceed as follows : 4'2818 X -/3 =. 7'416, the length of the tri-

On the Intimate Structure of Crystals. 299

gonal axis of the primitive cube, and thus (7'416— 4'206)/2 = 1-605,
the true diameter of an atom which could just occupy the central
interspace of the primitive cubelet. The cube of this number will
give us the gross volume of the atom of occluded hydrogen ; it is
4-134. If now we turn to Riicker's address on "The Range of
Molecular Forces," * we find the most probable estimates given for the
volume of hydrogen (H) are as follows : — From K (Boltzman) 4'4,
(Klemencic) 4'4 ; from n (Mascart) 4'65 ; from 6 (Van der Waals
and O. Meyer) 4*4. Between these numbers and that we have just
obtained there is a very remarkable concordance.

It may further be observed that the number of such interspaces as
we have considered is, to the number of atoms among which they lie,
in the ratio of 1 : 1, so that from purely geometrical considerations
it might be inferred that the limiting value for the absorption of
hydrogen by palladium would be reached with the formation of the
substance Pd2H2. Observation shows that this limit is never ex-
ceeded, never even attained, while that which is reached may fairly
be represented by the formula Pd3H2. It is obvious that purely
geometrical considerations are not all -that are involved, and to dis-
cuss other factors would be to trespass beyond our province. There
is one point in direct connection with our inquiry which must not,
however, be disregarded. The value we have found for the diameter of
hydrogen was obtained on the assumption that all the central spaces
were occupied by hydrogen, which would only be the case if Pd2H2
were formed ; the observed ratio, Pd3H2, would lead us to believe that
only two- thirds of the spaces are so occupied. This renders neces-
sary a correction in our estimate, which would slightly increase the
dimensions of the hydrogen atom. It is not possible, however, to
introduce this correction, on account of the absence of information
regarding the crystalline form assumed by Pd3H2. If crystals of
palladium be capable of taking a charge of hydrogen, there should
be no difficulty in ascertaining whether a change in crystalline
form accompanies occlusion. On the assumption that the maximum
expansion of palladium due to occlusion is confined to two-thirds of
the volume of the metal experimented upon, I find that the diameter
of the hydrogen atom should be 4*395. Possibly the assumption is
not defensible, but in any case it would appear that the amount of
coincidence we have already obtained between the dimensions of the
hydrogen atom, as calculated from the crystalline structure we have
assigned to palladium (along with other metals) and the dimensions
which follow from other modes of inquiry, affords strong confirma-
tion of our hypothesis.

The absorption of hydrogen by potassium might easily take place
without producing any marked expansion, i.e., so far as the relative
* ' Trans. Chem. Soc.,' vol. 63, p. 257, 1888.

300 Prof. F. Gotch and Mr. G. J. Burch. Electrical

dimensions of the atoms are concerned in the matter, for the inter-
space in the centre of a primitive cube of potassium is large enough
to house an atom of a gross volume exceeding 17.

In the case of iron the central space is notably smaller than in
that of palladium ; supposing no expansion to occur on absorption,
the largest atom it could contain would have a diameter of 1/392,
corresponding to a volume of 2*697.

It is probable, however, that a change in crystalline system is
associated with the absorption of gases by iron and nickel. This
is suggested by the curious effect produced on the nature of these
metals by repeated absorption of hydrogen, at least in the case of
nickel, which loses its cohesion and after repeated treatment becomes
converted into a friable powder.

The galleries formed by ranges of central spaces present con-
strictions at intervals corresponding to the places where the four
spheres forming the face of a cubelet are most closely approxi-
mate; the ratio of the diameter of a sphere that could just traverse
one of these constrictions is to that of a sphere which would jnsfc
occupy a central space as v/2 : -v/3. Hence the passage of an atom
into the central chamber involves either a displacement of the atoms
surrounding the entrance or a contraction in the volume of the
entering guest. Is it possible that the " singing " of palladium,
which accompanies the process of occlusion, is connected with vibra-
tory movements of its atoms as they open and close the entrances to
the central chambers ?

In conclusion it may be pointed out that all the metals which are
known to occlude hydrogen, viz., potassium, sodium, magnesium,
iron, nickel, platinum, and palladium, are paramagnetic, sodium and
magnesium being the only cases of an uncertain nature, while lead
and gold, which offer roomy central spaces for the occupation of
hydrogen, but do not absorb it, are diamagnetic.

u The Electrical Response of Nerve to a Single Stimulus
investigated with the Capillary Electrometer. Pre-
liminary Communication." By F. GOTCH, M.A., F.R.S.,
Professor of Physiology, University of Oxford, and G. J.
BURGH, M.A. (Oxon). Received April 1, — Read May 12,
1898.

The electrical changes which are evoked in nerve by a single
stimulus have up to the present been but little investigated. The
examination of the phenomena has been almost entirely limited to
observations upon the gal vanome trie deflections caused by the summed
effects of a rapid succession of excitations, and rheotome methods,

Response of Nerve investigated with Electrometer. 301

carried out along these lines by Bernstein, Hermann and others, have
yielded results of great value. It is, however, only on the assumption
that the aggregate value of the successive electromotive states gives
at any moment a faithful representation of each component member of
the series, that deductions can be drawn from such rheotome observa-
tions as to the characters of the single electrical response. Attempts
have been made to obtain indications of the response to a single
stimulus by other methods, but without very satisfactory results,
As far as we know, the only permanent record of such a response is
that obtained by Gotch and Horsley in 1888 with the assistance of
Burch ; the record was that of the photographed excursion of a
sensitive capillary electrometer.*

For some time the authors have been engaged in endeavouring
to obtain with the capillary electrometer records of the single
response of nerve which should be large enough not merely to-
indicate its occurrence but to afford data for determining its chief
characteristics.

This object has been so far attained that they are now able to
measure the electromotive changes of nerve in response to a single
stimulus, by the application to the photographic records of the
process of analysis introduced by one of them.f (Q. J. B.)

The electrometer employed, made especially for the purpose by
Burch, is more sensitive and, at the same time, more rapid in its
action than any they have hitherto used. The latter quality, while
essential to success, entails great liability to disturbance by mechanical
vibrations, and considerable difficulty was met with on this account.
The following form of support was ultimately adopted. A brick
pillar was built up to the level of the ground upon a concrete founda-
tion at the bottom of a pit 7 feet deep. On the pillar was
placed a stout box containing some 5 cwt. of clay and upon the box
three cast-iron plates, each weighing 1 cwt. Each plate was sepa-
rated from the one below by three bags of sawdust, the bags forming
supports, so arranged in opposite triangles as to come alternately
under the nodes and loops of the plates. The electrometer, with its
accompanying microscope, was fixed to the topmost plate, and was
thus efficiently isolated from the rest of the apparatus and from the
floor of the working room.

The excursions of the meniscus were recorded by a pendulum
motor,;]: the image being projected by a Leitz 3 mm. objective upon
the sensitized plate. This was carried by the motor across the optic
axis in a circular arc at a distance of 125 cm. from the lens, giving

* * Roy. Soc. Proc.,' vol. 45.

f < Phil. Trans.,' A, vol. 183 (1892), pp. 81—105.

J See " The Capillary Electrometer in Theory and Practice," Gr. J. Burch; also
Burdon Sanderson, ' Journ. Phys.,' vol. 18, pp. 126 — 134.

VOL. LXIII. Z

302 Prof. F. Gotch and Mr. G. J. Burcli. Electrical

a magnification of 416 diameters. The velocity of the transit of the
plates in the experiments now described varied between 14 and
70 cm. per second ; it was determined in every instance by record-
ing upon the plate the vibrations of a tuning fork having a period of
500 per second.

The sciatic nerves of large specimens of R. temporaries were used
in all the experiments, and the present results were obtained during
the winter months, i.e., from October to March.

The prepared nerve was placed in a moist chamber kept at from
4° to 6° C. ; the chamber contained non-polarisable electrodes for the
electrometer and polarising connections, and a pair of exciting-
electrodes. In every case the nerve was excited by a single stimulus
applied to the sciatic plexus 20 to 30 mm. from the nearest of the
electrometer contacts.

The form of stimulus usually employed was a relatively feeble
induced current caused by the opening of the primary circuit of a
standardised induction coil, which included one Dariiell cell; the
opening was effected by the pendulum motor and the primary coil
contained no core. Each single stimulus of this type produces a
movement of the meniscus when the electrometer contacts are
suitably arranged upon the nerve. The movement is in some cases
perceptible to the eye when the highly magnified image is projected
upon a screen, but in many instances is only visible after the develop-
ment of the photographic record. That the movement was not due
to an escape from the exciting circuit is shown as follows : — The
direction and character of the movement is unchanged whatever the
direction of the exciting current; the escape, if present at all, is
clearly indicated in the record as a rapid displacement of the meniscus,
preceding by a distinct interval the larger movement which is here
referred to ; such antecedent escape excursions remain unmodified in
character under conditions which materially affect both the larger
movement and the physiological condition of the nerve (polarisation,
C02, &c.) ; the escape, if present, is increased by augmenting the
intensity of the exciting induced current, whilst the larger change
reaches a maximum with a certain intensity of stimulus ; finally, the
larger movement is obtained by mechanical excitation such as the
single tap of a light hammer arranged after the method of v. Uexkiill.*
In order to facilitate the description of the excursions obtained,
selected photographs have been projected upon a screen and the out-
lines of the variation in the level of the meniscus carefully traced ;
a number of different curves are thus brought into juxta-position.
A. reduced copy of this is given in fig. 1. Some of the actual records
will, it is hoped, be produced in a more extended communication,
•but the curves given in the figure are not merely faithful reproduc-
* v. Uexkiill, ' Zeils. f. Biol.,' vols. 31, 32, 1895.

Response of Nerve investigated with Electrometer. 303

tions of the originals, but correspond as regards dimensions with the
records upon the photographic plates, The curves are to be read
from left to right ; the short line under each indicates 1/100 of a second.
In several instances, such as curves (i), (iv), (v), (vi), (vii), and (ix),
the escape of the exciting current, arranged to be in the same
direction as the change due to the response, is seen preceding this.
When present it indicates the moment of excitation. In the actual
records this moment was marked on each plate by photographing
the movement of the opening key which caused the exciting break
induction shock.

Fm. 1.

— -- ~ -- "
S —

(JT)
(HD
(IT)
(VJ
<VT)
(W)

(Wf)

(X)

304 Prof. F. Gotch and Mr. G. J. Burch. Electrical

Freshly Prepared Nerve ; both Electrometer Contacts upon the
Uninjured Surface.

The nerve in these preparations was dissected out from the spinal
column to the knee, and the muscles below the knee were left attached
to the preparation. With the electrometer contacts arranged at
distances of 5 and 15 mm. respectively from the knee end, no resting
difference of potential was perceptible. A single electrical or
mechanical excitation of the sciatic plexus 45 mm. from the knee
end of the nerve causes no visible displacement in the level of the
mercurial meniscus, but the photographic record shows a rapid
excursion indicating that the contact nearest the seat of excitation
(proximal) is first negative and then positive to that more remote
(distal). The character of the rapid up and down movement is
indicated in curve (i) fig. 1. If the contacts are placed further
apart (25 to 30 mm.) the spike present in the record is more pro-
nounced, the ascending and descending limbs being further apart.

Freshly Prepared Nerve ; the Proximal Electrometer Contact upon the
Uninjured Surface, the Distal upon a recently made Cross Section
at the Knee End.

The contacts were arranged 10 mm. apart, and the well-known
resting difference of potential existed between them. This demarca-
tion difference caused a downward movement of the level of
the meniscus amounting in some cases to 10 cm. upon the screen.
It was not compensated by the use of any external E.M.F., but the
pressure was altered so as to bring the meniscus up again to its
proper position. During the presence of this permanent demarcation
effect each single excitation of the plexus, whether electrical or
mechanical, is followed by a visible displacement in the level of the
image. The photographic record, see fig. 1 (ii), shows a rapid
upward movement, followed by a prolonged tail in place of the
downward movement obtained with uninjured nerve, thus indicating
a more persistent change of the same sign as the initial one ; this
disappears comparatively slowly, and is of much lower E.M.F.
than that which produces the initial rise.

Excised Nerve kept in the Cold from 24 to 90 hours in 0'6 per cent.
NaCl made with Tap-water containing Traces of Calcium Salts.

That nerves kept in this way retain their excitability is shown by
the fact that if the muscles are not detached they respond to excita-
tion of the nerve trunks.

On connecting such an excised nerve with the electrometer, no

Response of Nerve investigated with Electrometer. 305

marked difference of potential is found to exist between the cross-
section and any point on the surface.

A single excitation of the plexus rarely produces a displacement
of the image of the meniscus which is visible to the eye, but in the
photographic record such displacement is indicated by a definite
excursion of the character shown in fig/1 (iii). The form is a spike,
the limbs of which are more widely separated than those of the
uninjured fresh nerve fig. 1 (i). It indicates that the proximal
electrometer contact becomes first negative and then positive to the
distal one, but as the period at which the change of sign occurs is
later than in the fresh nerve the rate of transmission of the excitatory
process, of which the electrical change is an index, must be slower in
the kept than in the fresh nerve.

If a new cross-section is made at the knee end and the distal
contact placed upon it, the resting demarcation change is at once
produced causing a marked downward displacement of the meniscus.
Each single excitation of the plexus now causes a change plainly
visible to the eye and the record shows as in fig. 1 (iv) that there is
an, excursion of considerable size, the initial rise being followed by
the prolonged tail, which is seen in the freshly injured nerve.

The Alterations produced by the passage of a Polarising Current.

It is well known that the passage of a galvanic current through
a portion of nerve profoundly modifies its electromotive conditions.
During the passage the regions outside the part traversed by the
polarising current are the seat of changes such that currents of
similar direction to the polarising one are present in the extrapolar
regions.

It has been shown by Bernstein, Hermann and others that the
excitatory effects are modified under these conditions, and a consider-
able part of the present investigation has been devoted to the deter-
mination of the character of the change evoked by a single stimulus
under these circumstances.

The experiments were arranged along the lines shown in fig. 2.
The excitation was restricted as before to the sciatic plexus, but an
additional pair of non-polarisable contacts was connected with a
circuit comprising a rheochord and two Daniell cells. These
polarising contacts were placed either between the exciting and the
electrometer ones as in arrangements A and B of fig. 2, or on the
distal side of the electrometer ones as in arrangements C and I). In
each case the polarising current may be reversed in direction and
four different modifications can be thus studied. It will be observed
that there is a fundamental difference as regards the position of the
electrometer contacts, and this is accompanied by corresponding

z 2

306

Prof. F. Gotch and Mr. G. J. Burch. Electrical

1 x

Fia. 2.

''A

n x

VrW
VT

A

r- x

^ si. pu^

x^«_J|_3?^ X) ^

'--- c -*— •* a

X

r j i j

w^

M

X indicates the seat of excitation on the sciatic plexus ; M the muscles below the
knee; P indicates the circuit traversed by the polarising current; E the
electrometer circuit. The unbroken arrow indicates the direction of the
persistent polarising current in the nerve, the dotted one that of the persisjbent
extrapolar effect thus produced. The anode and cathode of the polarising
current are indicated by the letters a and c respectively. The signs ( + ) and
( — ) refer to the persistent difference of the electrometer contacts during
polarisation.

differences in their electrical state. The proximal electrometer
contact is that nearest the seat of excitation, and is represented in
the figure by the broad dark line. In arrangement A it lies in the
anodic extrapolar region, and owing to polarisation effects, is
rendered positive to the distal one during the polarising flow ; in B
it is in the cathodic extrapolar region, and is negative to the distal
one during such flow ; in C it is in the cathodic region, but, as in A,
is positive to the distal one, whilst in D it is in the anodic region,
but is negative to the distal one as in the case of B.

The results as regards the character of the excitatory change
differ in accordance with the particular arrangement employed, but
it will be seen that with arrangements fA and C, the records of the
response to a single stimulus resemble one another inasmuch as the
prolonged tail, previously referred to as characteristic of the nerve
with a fresh cross-section, now becomes strikingly evident. On the
other hand with B and D the records resemble that of the uninjured
nerve, the spike alone being present.

It will be convenient to describe the results under two headings
in accordance with this general subdivision ; and, as experiments
have been made on the preparations of all the types previously
referred to, the results under each heading comprise those observed
in fresh nerves uninjured and with cross-section, and in kept nerves.

Response of Nerve investigated ivith Electrometer. 307

Nerve during passage of a Polarising Current of such direction
that the Proximal Electrometer Contact is positive to the Distal One.

(a) Fresh nerve prepared with electrometer contacts on surface
and cross-section. The proximal contact is in this case positive to
the distal owing to the resting difference ; this is increased by the
anodic extrapolar effect of a polarising current as in arrangement A
(fig. 2). Each single stimulus of the plexus causes a very marked
displacement of the meniscus plainly visible to the eye. The photo-
graphic record is of the character shown in fig. I (v). The initial
rise is succeeded by a pronounced and prolonged effect of similar
sign : it indicates that the prolonged change present in the un-
polarised nerve and figured in fig. 1 (ii) is increased.

(6) Fresh nerve uninjured with both electrometer contacts
upon the surface. There is no difference of potential between the
contacts, but during polarisation the anodic extrapolar effect in
arrangement A and the cathodic extrapolar effect in arrangement
C are such that the proximal electrometer contact is positive to the
distal. This is particularly the case with arrangement A owing to
the nearer proximity of the contact to the polarised region.

The persistent extrapolar state is indicated by a downward move-
ment of the meniscus which reaches a certain level and is raised by
suitable alteration of pressure to the middle of the optical field.
Each single stimulus applied to the plexus, although in the unpolarised
nerve not followed by any displacement visible to the eye, produces
now a visible change. The records show that the initial rise is
still present, but that it is succeeded by a prolonged effect of similar
character to that obtained in fresh nerve with the distal contact upon
the cross-section. The curve given in fig. 1 (vii) shows its form.

(c) Nerve kept in 0*6 per cent. NaCl. It has been already
stated that after twenty- four hours, the excised nerve gives no
difference of potential when the electrometer contacts are placed
upon cross-section and surface.

Polarisation may be produced of such character that the proximal
electrometer contact (i.e., that nearest the seat of excitation) is posi-
tive to the distal one, by arrangement A or C, as in the case of unin-
jured nerve. The effect caused by the single stimulus of the plexus
is modified in the same way as in the previous class of observations.
Instead of the spike which characterises the unpolarised nerve, the
records show that the initial rise is followed by a prolonged effect of
the form shown in fig. 1 (ix). As in the case of the uninjured nerve,
this is more pronounced when the arrangement is that given in A
than that of C (fig. 2) for the reason previously referred to.

If the kept nerve is subjected to a fresh cross -section, then the
results of polarisation of this character resemble those described
under (a) as occurring in the fresh nerve with a cross-section.

308 Prof. F. Gotch and Mr. G. J. Burch. Electrical

Nerve during passage of a Polarising Current of such direction that
the Proximal Electrometer Contact is negative to the Distal One.

(a) Fresh nerve with electrometer contacts upon surface and
•cross-section. The arrangement made use of is that given in fig. 2,
B, and the resting demarcation difference is now largely diminished
or entirely overpowered by the polarisation extrapolar effect in the
•cathodic region. The single excitation of the plexus rarely produces
any visible movement of the meniscus, and the record upon the plate
is found to be of the character indicated in fig. 1 (vi) . It is evident
that this differs from both the unpolarised nerve, fig. 1 (ii), and the
nerve in the state of opposite polarisation, fig. 1 (v), by the circum-
stance that the early part of the effect now takes the form of a small
spike, and that the terminal prolonged portion forming the tail is
reduced to very small proportions. The curve thus indicates that
the proximal contact becomes first negative and then positive in
rapid succession, whilst the prolonged effect no longer masks the
second positive change as in the other instances just referred to.

(6) Fresh nerve uninjured, with contacts both upon the surface.
Polarisation effects resulting in relative negativity of the contact
proximal to the seat of excitation may be attained by either an
arrangement like that given in fig. 2 B, or one like that of D. In
the first case the electrometer contacts are in the cathodic extrapolar
region; in the second case they lie in the anodic extrapolar region.

With either arrangement a single stimulus applied to the plexus
produces no alteration in the level of the meniscus visible to the eye,
but each plate when developed shows a record of the type indicated
in fig. 1 (viii) ; the form of the photographed excursion is that of a
very small spike the two limbs of which follow each other in rapid
succession. The spike is sometimes, especially with arrangement D,
followed by a curved prolongation dipping for a short distance
below the resting level, but in no case has an effect in this direction
been obtained at all comparable with that already referred to as
producing the negative tail daring the oppositely directed polarisation.

(c) Nerve kept in O6 per cent. NaCJ. Polarisation producing
relative negativity of the electrometer contact proximal to the seat
of excitation can be attained by either of the two arrangements, B or
D (fig. 2). When present, a single excitation causes no visible dis-
placement of the meniscus, but the photographic records show that
there is an abrupt up-and-down excursion of the type indicated in
fig. 1 (x). When compared with that produced in the unpolarised
nerve, fig. 1 (iii)5 the form of the spike is seen to be one in whicli
the ascending and descending limbs are more closely approximated,
and a slight dip below the resting level follows the completion of
the excursion.

Response of Nerve investigated with Electrometer. 309

From the foregoing description it will be evident that when the
proximal electrometer contact is relatively positive to the distal one,
whether owing to the extrapolar changes due to the passage of a
polarising current, or to the presence, in the case of a recent cross-
section, of the resting demarcation difference, the electrical response
evoked by a single stimulus has certain definite characteristics ; the
most conspicuous of these are the increased magnitude of the initial
movement forming the ascending limb of the spike and the presence
of a more prolonged change of similar sign to this. On the other
hand when the contact proximal to the seat of the stimulus is rela-
tively negative to the distal one and this latter therefore relatively
positive, other characteristics of the response are accentuated ; the
initial movement forming the ascending limb of the spike is quickly
checked and succeeded by one of opposite character, whilst the
prolonged change disappears.

It would be beyond the scope of the present communication to
enter upon any discussion as to the physiological meaning of the
changes here referred to. It may, however, be pointed out that the
results fully support the conclusions arrived at by Hermann from
rheotome observations, viz., that those portions of the extrapolar
region nearer the anode are during polarisation capable of a more
pronounced excitatory electrical change than those more remote,
whilst those portions of the cathodic region nearer the cathode are
susceptible of a less pronounced change than those more remote.*
New features are, however, brought to light by the present research
as indicated in the preceding paragraphs.

The Electromotive Force of the Changes.

The records allow of the calculation of the E.M.F. of the potential
difference between the contacts. The table appended to this com-
munication gives five examples of the results of the method of
analysis introduced by one of us f (G. J. B.) The five examples
selected are the analyses of excursions such as are figured in curves
(i), (ii), (iii), (vii), and (viii) of fig. 1. In addition to the intrinsic
interest which attaches to the estimation of the E.M.F. of the electrical
response to a single stimulus, the analyses present certain features
which may be briefly alluded to.

The maximum E.M.F. ifc will be observed may reach as much as
O032 volt (Table IY), a suggestive fact in relation to the view held
by us as to the nervous origin of the E.M.F. of the response in the
electrical organ of fishes. % This maximum is attained very rapidly

* See Hermann, ' Fandbuch der Physiologic,' vol. 2 (i), p. 167.

f Pmrch, ' Phil, Trans.,' A, vol. 183 (1892), pp. 81—105.

J Gotch and Enroll, ' Phil. Trans.,' B, vol. 187 (1896), p. 382.

olu Electrical Eesponse of Nerve investigated ivith Electrometer.

Analysis of Five Records of Single Response. '

The difference of potential between the proximal and distal contacts is given in
terms of relative negativity ( — ) or positivity ( + ) of proximal as compared
with distal contact. (Distance between contacts = 10 mm.) The differences
of potential are given in decimals of a volt.

I.

II.

III.

IV.

V.

Time
after ex-
citation
of nerve
30 mm.
from
proximal
contact.

Uninjured
nerve.
Electrometer
contacts
10 mm. apart
and both on
uninjured
surfaces.

Fresh nerve
with cross-
section.
Proximal
contact on
uninjured
surface + to
distal on
cross-section.

Nerve ex-
cised and
kept 24 hours
in 06 per
cent. MaCl.
Proximal
contact on
surface, dis-
tal on end.

Fresh unin-
jured nerve.
Polarisation
such that
proximal
contact is
persistently
+ to distal
one.

Fresh unin-
jured nerve.
Polarisation
such that
proximal
contact is
persistently
— to distal
one.

sec.

0-0020

start

start

nil

nil

nil

0 -0025

-0-0218

-0-0262

55

J5

start

0-0030

-0-0218

-0-0176

))

})

-0-0056

0-0035

-0-0218

-0-0144

»

start

-0-0081

0-0040

-0-0002

-0-0127

J5

-0-0083

-0-0115

0-0045

+ 0 -0145

-0-0103

start

-0-0135

-0-0162

0-0050

+ 0-0128

-0-0081

-0-0093

-0-0182

-0-0220

0 -0055

+ 0-0113

-0-0054

-0-0145 ! -0-0250

-0-0115

0-0060

+ 0-0101

-0-0029

-0-0178 i -0-0329

-o-oooi

0 -0065

+ 0 -0099

- 0 -0004

-0-0093 i -0-0328

+ 0-0051

0-007

+ 0 -0054

+ 0-0015

-0-0002 ! -0-0328

+ 0-0099

0-008

+ 0-0007

+ 0-0016

+ 0 -0041

-0-0003

+ 0-0084

0-009

+ 0 -0004

+ 0 -0020

+ 0 -0050

+ 0-0002

+ 0-0070

0-010

+ 0 -0000

+ 0-0023

+ 0-0113

o -oooo

+ 0 -0058

0-011

+ 0-0023

+ 0-0116

o-oooo

+ 0-0037

0-012

+ 0-0023

+ 0 -0024

-0-0001

+ 0-0019

0-013

+ 0-0026

+ 0-0011

-0-0002

o-oooo

0-014

+ 0-0029

+ 0-0010

-0-0005

0-016 1 .. -0-0002

+ 0-0007

-0-0011

0-018

-0-0019

+ 0-0003

-0-0016

0-020

-0-0023

0 -0000

-0-0022

0-030

% .

-0-0019

-0-0016

0-040

-0-0013

-o-ooio

0-050

_ 0-0006

. ,

0 -0000

0-060

O'OOOO

especially in the fresh, nerve ; the first indications of its presence in
fresh nerve at 6° C. occur O002 second after the stimulation of the
plexus when the seat of this stimulation is 30 mm. from the proxi-
mal electrometer contact. The response is thus propagated from
the seat of stimulation at a rate of from 10 to 15 metres per second
under these conditions. This is confirmed by the time relations of
the culmination and commencing decline in the change, for in fresh
nerve this begins in about O'OOl second with a distance of 10 mm.
between the proximal and distal contacts. In the example of kept

On the Magnetic Susceptibility of Liquid Oxygen. 311

nerve given in the third column, both the commencement and the
culmination of the initial change are retarded, the propagation rate
in this nerve at a temperature of 6° C. being slowed to 6 metres per
second. A comparison of the fourth and fifth columns shows the
retardation in the anodic as compared with the acceleration in the
cathodic extrapolar region. Finally the time relations and the
relative E.M.P. of the prolonged effect present in the instances given
in the second and fourth columns may be compared with those of
the initial change present in all the examples. It will be seen that
the change producing the prolonged tail of the photographic record
is one which differs from that producing the initial spike in the
following important particulars : it develops slowly, taking from
O'OOG to O01 second to culminate, its maximum E.M.F. is only one-
tenth of that of the initial change, and it subsides slowly. It is not
present in the instances given in columns I, III, and V.

In a more extended communication the authors hope to bring
forward other features of the response of nerve, particularly the
characters exhibited by the records of the changes produced by a
series of stimuli and of those produced during reflex discharge of the
central nervous system.

" On the Magnetic Susceptibility of Liquid Oxygen." By J.
A. FLEMING, M.A., D.Sc., F.R.S., Professor of Electrical
Engineering in University College, London, and JAMES
DEWAR, M.A., LL.D., F.R.S., Fullerian Professor of
Chemistry in the Royal Institution, London, &c. Received
May 9,— Read May 12, 1898.

In a previous communication* we have described the initial
investigations made by us to determine directly the numerical value
of the magnetic permeability of liquid oxygen, and we there indi-
cated that we hoped before long to present to the Royal Society the
results of other experiments made by a different physical method
which we anticipated would enable us to state whether liquid oxygen
has a constant magnetic susceptibility, or whether, like a ferro-
magnetic substance, its magnetic susceptibility alters when subjected
to different magnetic forces.

We have recently obtained results which, though limited to a
certain range of force, we think afford fairly trustworthy values of
the magnetic susceptibility of liquid oxygen under magnetising forces
varying from 500 to 2500 C.G.S. units, and place them therefore on
record.

* ' Koy. Soc. Proc.,' 1896, vol. 60, p. 283, " On the Magnetic Permeability of
Liquid Oxygen and Liquid Air."

VOL. LXIII. 2 A

312 Profs. J. A. Fleming and J. Dewar.

The method used by us in these last experiments depends on the
well-known fact that if a body, either paramagnetic or diamagnetic,
is placed in a magnetic field of variable strength, it is subjected to a
mechanical force tending to displace it in the direction in which the
field varies most rapidly.

If the susceptibility of the body is so small that it does not
sensibly disturb the distribution of the field, the measurement of this
mechanical force may be made to furnish a knowledge of the abso-
lute value of the magnetic susceptibility.

The necessary conditions are, however, that the volume (V) of the
body must be of such small magnitude relatively to the form of the
field that its magnetisation is not sensibly different from that which
it would obtain if immersed in a uniform field, and also that the
magnetic susceptibility (&) of the substance must be of small absolute
value. Under these circumstances, if /is the mechanical force
(reckoned in dynes) acting ou the body, and H is the strength of
the field at its centre, then the force in the direction x is given by
the equation

/=^YHf?.
ax

The value k thus determined is a difference value, that is, it is
equal to the difference between the susceptibility of the body and
that of the medium in which it is immersed. Hence if one and
the same body is placed in the same divergent field, but alternately
surrounded by different media, the difference in the apparent suscep-
tibilities of the body in the two cases will give us the difference of
the true susceptibilities of the media. The experimental method em-
ployed by us consisted, therefore, in determining the forces acting on
a small sphere of known susceptibility when suspended first in air,
and next in liquid oxygen, and hence deducing the difference of the
susceptibility of liquid oxygen and air, and therefore the absolute
value of the susceptibility of liquid oxygen, knowing that of air.

The first step was the construction of an electro-magnet capable of
producing the required field. From the above-named conditions of
success it will be seen that since the volume and susceptibility to be
measured are both small, it is essential that the magnetic field shall
not only be large but must vary very rapidly, or else the forces to be
measured will be small.

An electro-magnet giving the required field was therefore designed
as follows : —

The exciting bobbin consists of a single coil of double cotton-
covered copper wire, No. 14 S.W.G. in size.

The coil is 30 cm. long, 18'5 cm. in outside diameter, and the
aperture in the coil 9'5 cm. in diameter. The total weight of

On the Magnetic Susceptibility of Liquid Oxygen. 313

double cotton-covered copper wire on the bobbin is 71 Ibs., and the
total length of wire is roughly about 3300 feet. The total number of
turns of wire on the bobbin is 2478. The wire is capable of carry-
ing 12 or 14 amperes for considerable periods of time without
dangerous heating. The total resistance of the wire is very nearly
5-5 ohms at 20° C.

This bobbin of wire is enclosed in a cylinder of mild steel
of the same height as the bobbin, the walls of which are
2 '5 cm. thick. This cylinder has movable circular end plates of
steel 2 '5 cm. in thickness fitting it, and in these plates are circular
holes 9 cm. in diameter. A sofb steel core was also provided,

V, vacuum vessel ; B, ball weighed ; W, wire windings of magnet ; S, C, steel
shell and magnet core.

37 cm. in length and 9 cm. in diameter, and having steel studs
screwed into *j it so that the core could be held in he position
shown in the diagram. The end surface of the inner core was
7'5 cm. below the upper surface of the wire coil. The steel used
is high permeability magnet steel.

2 A 2

314 Profs. J. A. Fleming and J. Dewar.

On passing a current through the magnet coils a magnetic field
is created in the space just above the upper end of the inner
steel core, which is very divergent, and which is not only strong,
but varies very rapidly in an axial direction.

This magnet was placed underneath a shelf on which stood a very
sensitive short-beam chemical balance capable of weighing to one-
tenth of a milligram. From one pan depended a fine wire passing
through a hole in the balance case and shelf, and served to suspend
a ball just within the field of the magnet.

If the ball was counterpoised by weights and the magnet then
excited, the ball was subjected to an upward or downward force
which either decreased or increased its apparent weight, according
as it was diamagnetic or paramagnetic. If "W is the gain or loss in
weight on exciting the magnet, V the volume of the ball, H the
strength of the field at its centre, and dB./dx the rate of change of
the field in a vertical direction, then the equation

981W = ^VH

ax

gives us the value of the apparent magnetic susceptibility (A^) in
air of the body weighed.

In order to apply the method we require to know the value of the
field H at different parts along the vertical axis of the magnet and
also the value of the field for various exciting currents.

A careful preliminary investigation on this point was therefore
made. Constant currents varying from 1 to 12 or 14 amperes were
passed through the magnet coils and by means of a small secondary
coil attached to a calibrated ballistic galvanometer the field strength
at various points in the vertical central axis of the magnet was
measured. These measurements extended from close contact with
the magnet core to a point about 10 cm. above the end surface of
the recessed polar end of the inner steel core.

The distance in centimetres of any point from the end polar sur-
face of the inner steel core is denoted by x, this measurement
being made as exactly as possible along the central vertical axis of
the magnet. The strength of the field at this point in C.G.S. units
is denoted by H, and the space rate of change in the x direction by
dH/d*.

The following tables give the exciting currents (A) in amperes
measured by a Weston ammeter, No. 3134, and the values of x and H.

The value of dHjdx at any point can be at once determined from
the curve of H in terms of x.

On the Magnetic Susceptibility of Liquid Oxygen. 315

Table I. — Magnetisation Curves of Tubular Electromagnet, the
Induction Density or Field being measured at a point x centi-
metres from the Pole Face on the Axial Line.

Exciting

Induction density (H) at various distances

current by

True current

x from the pole.

Weston

in amperes.

ammeter,

A.

No. 3134.

x = 0 "15 cm.

x = 2 "70 cm.

x = 5-25 cm.

15

15-15

4374

__

_

14

14 -141

4200

—

_*.

13-9

14 -010

—

3269

13

13 -127

4054

3194

12

12 -094

3848

3070

2002 -5

11

11-124

3648

2888

1897

10

10-075

3407

2712

1782 -5

9

9-082

3194

2543

1682

8

8-059

3014

2310

1557

7

7.059

2764

2153

1418 -5

6

6-020

2504

1957

1273

5

5 -015

2220

1740

1139

4

3-968

1884

1459

955-5

3

2-994

1481

1161

749

2

1-958

992

767

491-5

The induction density or field along the axial line was also
measured for two constant excitations corresponding to currents of
12'094 and 6*020 amperes at various distances along the axial line,
and the results are given in Table II.

The results in Tables I and II were then set out carefully in a
curve, and from these curves an interpolation table constructed,
showing the axial field at various points on the axis for different
exciting currents, and these values are given in Table III.

Having calibrated the magnet, the following objects were provided
to be used as bodies to weigh in the field, viz. : —

(1) A silver ball, (2) a rather smaller copper ball, (3) several
hollow glass balls containing a little mercury, and (4) a bismuth
ball.

In order to test the method and obtain confidence in the results, we
made a number of preliminary measurements on the magnetic suscep-
tibility of water, solutions of manganese sulphate, and ferrous sulphate
of known densities.

These experiments were made by weighing the silver ball or hollow
glass ball when immersed in these liquids contained in a beaker
placed in the field cavity of the magnet.

Five weighings were always made —

(1) The weight of the ball in air, magnet not excited.

(2) The apparent weight of the ball in air, magnet excited.

316

Profs. J. A. Fleming and J. Dewar.

(3) The apparent weight of the ball in water, magnet not excited.

(4) The apparent weight of the ball in the solution used, magnet

not excited.

(5) The apparent weight of the ball in the liquid, the magnet

being excited with a known current, and the position of the
ball in the field accurately known.

From these weighings we obtain all the required information. For
from (1) and (3) we obtain the volume of the ball, and from (1),
(2), and (3) the magnetic susceptibility of the ball, and from (4) and
(5) the magnetic susceptibility of the liquid.

The sphere used as a testing substance was suspended by a long
fine platinum or gold wire from one pan of the balance. A small
beaker filled with water or the salts solution under test was placed
over the pole of this magnet and the sphere suspended in it.

In some cases when using strong exciting currents we found it

Table II.— Induction Densities (H) of Field of Tubular Electro-
magnet at various distances x along the Axial Line.

Distance
from pole face
= x cm.

Field = H in C.G-.S. units.

For 6 -020 amperes.

For 12-094 amperes.

0'15

2485 -5

3853

0-58

2475-5

3825

1-01

2404

3711

1-44

2307 '5

3582

1-87

2196-5

3419

2-30

2068

3225

2-73

1935

3016

3-16

1794

2830

3-59

1666

2624

4-02

1557

2453

4-45

1455 -5

2291

4-88

1346

2128

5-31

1253

1960

5-74

1151-5

1820

6-17

1052

1666

6'60

965-5

1521

7'03

867

1385

7-46

770

1260

7-89

680

1099

8-32

596

955

8-75

509-5

805

9-10

425

681

9-61

356-5

564

10-04

294-5

462

10-47

231-4

368

10-91

189-9

289

11-33

142-1

228

11-76

114-2

175

On the Magnetic Susceptibility of Liquid Oxygen. 317

Table III. — Summary of Results of Field Measurements of Axial
Field of Tubular Electromagnet.

Current

L

Distance from pole face
on axial line.

Ratios of induction density or
field H to field corresponding to

by

Western

6 *0 or 12 '0 true amperes.

ammeter,

No. 3134.

0 '15 cm.

2 -70 cm.

5 '25 cm.

0'15 cm.

2 -70 cm.

5-25 cm.

0

0

0

0

0

0

0

2

994

762

492

0 -3989

0-3908

0 -3862

3

1476

1148

742

0 -5923

0-5887

0-5825

4

1778

1460

952

0-7135

0 -7487

0 -7473

5

2220

1726

1128

0-8908

0 -8852

0-8854

6

2492

1950

1274

1 -0000

1 -0000

1 -0000

7

2760

2158

1422

1 '1075

1 -1066

1 -1161

8

2996

2346

1556

1 -2022

1 -2031

1 -2213

9

3226

2534

1678

1 -2945

1-2995

1 -3171

9

3226

2534

1678

0*8402

0-8363

0-8466

10 '

3438

2712

1782

0-8954

0-8950

0 -8991

11

3650

2880

1890

0-9506

0 -9504

0 -9536

12

3840

3030

1982

1 -0000

1-0000

1-0000

13

4028

3178

2080

1 -0490

1 '0488

1 -0494

14

4208

3320

2168

1 "0959

1 -0957

1 -0939

14-5

4292

3390

2210

1-1177

1 -1188

1-1153

15

4374

3460

2254

1 -1391

1 -1420

1 -1372

necessary to pack round the beaker of liquid with crushed ice in
order to keep the temperature of the water or solution from being
raised by radiation of heat from the magnet coils. Any rise of tem-
perature in the liquid under test, by causing variation in density,
introduces a difficulty in obtaining exact and comparable weighings
of the ball.

The position of the ball in the magnetic field was very carefully
adjusted, so that the centre of the ball was as nearly as possible on
the axial line of the magnet. The distance of the centre of the ball
from the end of the magnet core was also measured with as much
accuracy as possible when the balance was lifted off its supports, and
yet the balance index was in the zero position.

The distance from the pole face measured in centimetres is called
the distance from the pole in the following tables. Corresponding to
this distance (#) we know from the preliminary experiments and the
results given in Tables I, II, and III the strength of the magnetic
field (H) and its axial rate of variation dlBi/dx.

The dimensions and weights of the balls used were as follows : —

Profs. J. A. Fleming and J. Dewar.

Mean co-

Ball
made of

Weight
in
grams.

Dia-
meter
in cm.

Density.

Yolume
in c.c.
at
15° C.

Yolume
in c.c.
at
-182°C.

efficient of
cubical
expansion
between
0° C. and

-182°C.

Silver

132 -010

2'90

10 -334

12 -775

12-654

0 -0000518

Copper ......

37 -610

2-00

9-92

4-226

4-190

0 -0000427

Bismuth ......

62 -220

2-27

9-836

6-326

6 '287

0 -0000320

Glass ball con-

taining mer-

cury, No. 1 ..

18 -663

2-32

—

6-539

6-513

0 -0000200

Glass ball con-

taining mer-
cury, No. 2 . .

3-4CO

1-40

,

1-462

1-456

M

Glass ball con-

taining mer-

cury, No. 3 . .

32-500

2-68

—

10 -343

10 -340

»

Glass ball con-

4

taining mer-

cury, No. 4 . .

5-95

1-03

""

0-588

0-586

n

In each case a measurement was made of the magnetic suscepti-
bility in air of the ball used, by weighing it in a known magnetic
field and observing the loss or gain in weight.

In this manner the following determinations were made : —

The Magnetic Susceptibility of the Silver Ball.

Weight of silver ball in air at 15° C. = 132-010 grams.
Weight of silver ball in water at 2° C. = 119-235 grams.
Yolume of silver ball at 15° C. = 12" 775 c.c.

I.

II.

III.

IV.

Loss in weight in grams of silver
ball when weighed in field
— "VV

0-0287

0 -0284

0 '0142

0 -0132

Exciting currents of magnet in

12

12

6

6

Magnetic field in C.G.S. units
— H

3320

2820

1798

2206

426

459

308

258

Distance of centre of ball from

1-96

3-18

3-18

1-83

Calculated apparent suscepti-
bility — kllQ~6

1-56

1-68

1-97

1-78

The absolute 'magnetic susceptibility of air is 0'024 X 10 6.

The mean apparent susceptibility of silver in air is therefore from

On the Magnetic Susceptibility of Liquid Oxygen. 319

the above figures equal to — 1*75 xlO~6, and the absolute value k =.
-1-73X1CT6.
E. Becquerel gives — l'74x 10~6 as his observed value for silver.

The Magnetic Susceptibility of the Bismuth Ball.

Weight of bismuth ball in air at 15° C. = 62'220 grams.
Volume of bismuth ball at 15° C. = 6'326 c.c.

I.

II.

III.

Loss in weight in grams of bismuth
ball when weighed in field = «;...
Exciting current of magnet in am-

0-085
14-5

0-067
12

0-030
6

2383

2135

1355

415

372

236

Distance of centre of ball from pole
— x in cm ... ................

4*86

4-86

4'86

Calculated apparent susceptibility =
&1J.O-6

— 13 '4

-13-3

-14-6

The absolute magnetic susceptibility of air is 0'024 x 10 6. The
mean apparent susceptibility of bismuth in air is, therefore, from the
above figures equal to — 13*77 X 10~6, and the absolute susceptibility
k - - 13-75 xlO-6.

Recent values found by ether observers are — 13*4 xlO~6 (P.
Curie), and — 13*3 xlO~6 (L. Lombard]'). Hence our own is in
accordance with these.

The Magnetic Susceptibility of the Copper Ball.

Weight of copper ball in air at 15° C. = 37*610 grams.
Volume of copper ball in air at 15° C. = 4*226 c.c.

I.

II.

III.

IV.

Gain in weight in grams of
copper ball in field

G'009

0-005

0 -0055

0-0035

Exciting currents of magnet in

6

3

6

3

Magnetic field

1220

709

518

298

227

132

193

111

Distance of cenlre of ball from
pole in cm

5 '46

5 '46

8-72

8-72

Calculated apparent suscepti-
bility - FlO"6

+ 7-6

+ 12-5

+ 12-9

+ 28

320

Profs. J. A. Fleming and J. Dewar.

The copper ball proved to be ferromagnetic, owing, no doubt, to
traces of iron. We constructed a curve by which its susceptibility
in various fields could be deduced from the above observations, but
the only reason we employed it was because it seemed desirable to
determine the absolute susceptibility of the liquid oxygen with bodies
as far as possible different in susceptibility. Hence we selected
silver, bismuth, and the above slightly ferromagnetic copper ball for
the purpose.

The Magnetic Susceptibility of various Glass Sails partly filled with

Mercury.

No. 4 ball

No. 1 ball.

No. 2 ball.

No. 3 ball.

(nearly full
of

mercury).

Gain or loss in
weight in grams
of ball when
weighed in field

-o-ooi

fThis ball proved t<f|
be quite neutral j
•{ in the strongest }>
field we could j
^ produce J

-0-0044

-0-0007

Exciting current

of magnet in

amperes .... .

Q

12

12

Magnetic field ....

1330

—

3180

2418

Field variation . . .

231

—

474

391

Distance of centre

of ball from pole

of magnet in cm.

4-96

—

2-38

4-115

Calculated appar-

ent susceptibil-

ity = /fc^o-6. . . .

-0-5

zero

-0-277

-1-23

We have, then, the following data for the glass balls : —

No. 1 ball.

No. 2 ball.

No. 3 ball.

No. 4 ball.

Weight in grams. . .
Yolume in c.c. at
15° C

18 -663
6*539

3-400
1-462

32 -500
10 -3427

5-95

0 -5882

Diameter in cm. . . .
Absolute magnetic
susceptibility in

2-32
-0'48xlO-6

1-40
-0-024xlO~6

2-68
-0-25xlO~6

1-03
-l-21xlO-8

As a further check on the method we employed the above deter-
minations of the susceptibilities of the silver and glass ball, No. 3,
to obtain the value of the susceptibility of distilled water. The
measurements were as follows : —

On the Magnetic Susceptibility of Liquid Oxygen.

Magnetic Susceptibility of Water.
I, with silver ball ( ^sceptibility of ball = -1'73 x 10-.

Tt/Vli-i-mn nf I™!! 1O-'7h7^ n n,

321

I volume of ball = 12775 c.c.

II, with glass ball, No. 3 ( s™cePtilf ^ of bal] = ~^ *

I volume of ball = 1O3427 c.c. '

I.

I.

II.

Gain or loss in weight of ball when
weighed in field and in water ....

Exciting currents of magnet in am-

-0-0146
gram loss

12

-0-0163

loss

14-5

+ 0 '0053
increase

12

]Vf a^netic field

2802

2848

3180

Field variation. .

456

465

474

Distance of centre of ball from pole

3 '22

3-79

2-38

Apparent susceptibility of ball in
water — klIQ~6

-0-878

-0-945

+ 0 -333

The absolute susceptibility of water is, therefore,
-(173-0'88)10-6 = -0-85 xlO-8

and — (173— 0'94)10-6 = — 079 X 10~6 from the experiments with
the silver ball; and -(0'333 + 0*253) 10~6 = 0'59 X 10~6 from the
experiments with the glass ball No. 3. The mean of these values
gives — 074xlO~6 as the absolute susceptibility of water. The
following are some of the values obtained for the magnetic suscepti-
bility of water by older and by more recent observers.

Yalue of
Observer. Jc 10~6 for water.

Faraday O72

E. Becquerel O67

P. Curie 079

Townsend 0*77

Quincke O81

Du Bois 0-84

Mean value = 077

Hence our value for water 0*74 = H0~6 is not far from the mean
of the above results.

Many other experiments were then made with various solutions
of salts of iron and manganese, which satisfied us that we could
place reliance upon the results of this method in measuring the
magnetic susceptibility of a liquid, and we then proceeded to
experiments with liquid oxygen.

322

Profs. J. A. Fleming and J. Dewar.

The balls were accordingly all weighed in liquid oxygen contained
in a vacuum vessel placed over the pole piece of the magnet. This
vacuum vessel contained mercury in its vacuum space and was of an
unusually excellent kind. In it liquid oxygen could be preserved
for periods of many hours without a trace of ebullition, and no
difficulty was experienced in making the weighings with great
accuracy. These weighings of course served also to determine the
density of the liquid oxygen used. The results are embodied in the
following tables.

In each case the weighings give the apparent susceptibility of the
liquid oxygen, and these figures have to be corrected by adding or
subtracting a number representing the absolute susceptibility of the
ball at the liquid oxygen temperature. Thus in the case of the
silver ball the figure subtracted is two, as the nearest integer repre-
senting the susceptibility of silver at — 182° C. In the case of the
bismuth ball the figure subtracted is sixteen, in the case of the glass
balls it is zero or at most unity, and in the case of the copper ball
the correction is additive, depending on the value of the field.

Table Y. — Determinations of the Magnetic Susceptibility of Liquid

Oxygen.

[I. With the Silver Ball.

Volume of ball = 12'684 c.c. at temperature of liquid oxygen.
Density of liquid oxygen = 1*1376.

Distance of centre of ball from pole of magnet = 5*37 cm.
Magnetic susceptibility of silver ball = 1'73 x 10~6.

Exciting
current by
Weston

Field.
H

Field
variation;

Loss in
weight of
ball in

Apparent
susceptibility,

Absolute
susceptibility
of liquid

ammeter,

dUjdx.

grams.,

&jlO 6.

oxygen,

No. 3134.

W.

*10-«.

15

2218

408

3 -7585

322

320

14-5

2174

400

3 '6242

323

321

12

1950

359

2 -8845

319

317

9

1646

302-5

2 -0365

317

315

6

1242

228

1 -2303

337

335

4

928

170-4

0 -6855

336

334

3

723

132-7

0 -4243

343

341

Mean value of susceptibility of liquid oxj'gen as determined
the silver ball = 326 x 10~6.

On the Magnetic Susceptibility of Liquid Oxygen. 323

II. With the Bismuth Ball.

Volume of ball at temperature of liquid oxygen = 6'287 c.c.
Density of liquid oxygen = 1'1397.
Distance of centre of ball from pole = 4*865 cm.
Magnetic susceptibility of bismuth ball = 13'75 X 10~6 at 15° C.

= 15-9xlO-6at-182°C.

Exciting
current by
"Weston

Field.

Field
variation.

Loss in
weight of
ball in

Suscepti-
bility,

Absolute
susceptibility
of liquid

ammeter.

grams.

oxygen,

12

2135

373

1 '655

325

309

6

1356

236

0-705

344

328

Mean value of susceptibility of liquid oxygen as determined with
the bismuth ball = 319 X 10~6.

III. With the Copper Ball

Volume of ball at temperature of liquid oxygen = 4' 190 c.c.
Density of liquid oxygen = 1*140.
Distance of centre of ball from pole = 5*46 cm.
Magnetic susceptibility (varies from 8 X 10~6 to 15 x 10~6).

Exciting
current by
Weston

Field.

Field
variation.

Loss in
weight of
ball in

Apparent
susceptibility,

Absolute
susceptibility
of liquid

ammeter.

grams.

oxygen,
HO-6.

6 1220

227

0 -3721

315

323

5

1080

201

0 -2930

316

325

4

911

169-5

0 '2096

318

329

3

709

131-9

0 -1282

321

333

2

470

87-4

0-0546

311

326

Mean value of susceptibility of liquid oxygen as determined with
the copper ball = 327 x 10~6.

324

Profs. J. A. Fleming and J. Dewar.

IV. With the Glass Ball No. 1.

Volume of' ball at temperature of liquid oxygen = 6'513 c.c.
Density of liquid oxygen = 1*1391.
Distance of centre of ball from pole = 4'9b* cm.
Magnetic susceptibility of glass ball = 0*48 x 10~6.

Exciting
current by
Weston

Field.

Field
variation.

Loss in
weight of
ball in

Apparent
susceptibility,

Absolute
susceptibility
of liquid

ammeter.

grama.

1

oxygen,
Tc . 10-6.

7

1480

257

0-815

323

322-5

6

1330

231

0-671

329

328-5

3

777

134-9

0-229

329

328-5

Mean value of susceptibility of liquid oxygen as determined with
the glass ball No. 1 = 326 x KT6.

V. With the Glass Sail No. 2.

Volume of ball at temperature of liquid oxygen = T456 c.c.
Magnetic susceptibility of ball = 0'024 x

Distance
of ball
from
pole.

Exciting
current
of
magnet.

Field.

Field
variation.

Loss in
weight
of ball
in grams.

Apparent
suscepti-
bility,

^lo-6.

Absolute
susceptibility
of liquid
oxygen,

TC . io-6.

4-57

14-5

2500

427-5

0 -4919

310-1

310

14-5

2500

427-5

0-4916

309-9

310

13

2350

402

0-4333

309-1

309

12

2240

383

0-3936

309-1

309

12

2240

383

0 -3947

310-0

310

6

1422

236-5

0-1721

344-8

345

6

1422

236-5

0-1723

345 -2

345

7-04

12

1379

317

0 -2260

348-4

348

12

1379

317

0 -2252

347 -1

347

6

865

215

0-0894

323-9

324

6

865

215

0-0894

623-9

324

Mean value of susceptibility of liquid oxygen as determined with
the glass ball No. 2 = 325 x 10 -6.

On the Magnetic Susceptibility of Liquid Oxygen. 325

VI. With the Glass Boll No. 4.

Volume of ball at temperature of liquid oxygen = 0'585S c.c.
Magnetic susceptibility of ball = — T23 x 10~6.

'

Absolute

Distance
of ball
from pole.

Exciting
current of
magnet.

Field.

Field
variation.

Loss in
weight of
ball in
grams.

Apparent
suscepti-
bility,

suscepti-
bility of
liquid
oxygen,

4-935

15
15

2392
2392

437
437

0-1912
0 -1902

306
305

305
304

12

2102

384

0 -1475

306

305

6

1337

234

0-0628

336

335

12

2102

384

0 -1477

306-5

305

6

1337

234

0 -0620

332

331

4-115

12

2418

391

0 -1795

318

317

6

1532

238

0 -0790

361

360

Mean value of susceptibility of liquid oxygen as determined with
glass ball No. 4 = 320 x lO"6.

The absolute susceptibility is derived from the apparent suscepti-
bility by adding or subtracting the susceptibility of the ball used
according as it is paramagnetic or diamagnetic.

In the case of the copper ball, owing probably to traces of iron, the
paramagnetic susceptibility is rather large and varies with the field.
The proper additive correction was obtained by drawing a curve
and setting off the observed values of the copper ball susceptibility
as ordinates corresponding to the proper field strengths.

The mean value from all the six sets of observations comprising
thirty-six determinations with the silver, copper, bismuth, and four
glass balls is to give a value of 324 x 10~6 as the mean co-efficient of
magnetic susceptibility of liquid oxygen. From the relation
fji=l+4:7rk, the magnetic permeability can be deduced, and if
k = 324 x 10~6 we have p = 1*0041, as the value of the permeability
of liquid oxygen.

The value of fi we gave (see ' Proc. Koy. Soc.,' vol. 60, p. 292)
as the result of our former experiments by a totally different method
was fi = 1-00287, or nearly, 1-003.

Hence these two methods agree in giving values of the magnetic
permeability of liquid oxygen differing only by about one part in a
thousand.

The results of the present work must, however, be taken as giving
a much more probable value of the magnetic susceptibility.

On examining the above results it will be seen that there is a

326 Profs. J. A. Fleming and J. Dewar.

general tendency for the susceptibility with large fields of the order
of 2500 to be less than the susceptibility for fields of the order
of 500. The average susceptibility in fields of from 2500 to 1900
is more nearly 310 x 10~\ and that in fields from 1100 to 500 more
nearly 330xlO~6.

The difference only amounts to about 10 per cent, of the lower
value, and it cannot be said that the observations are all of exactly
equal weight.

The general result is to show that between the limits of H = 500
and H = 2500 the average magnetic susceptibility of liquid oxygen
has a value which does not differ much from 324 X 10~6, but with a
small but decided tendency to decrease in strong fields.

The determination of the variation of susceptibility in much
weaker fields is left undecided by these experiments, but by the
employment of a torsion balance we hope to be able before long to
give the ratios of the susceptibility in various fields much weaker
than those employed in the foregoing experiments.

In connection with the determination of the absolute magnetic
susceptibility of liquid oxygen, our attention has been much directed
to the important matter of the determination of magnetic suscepti-
bilities of substances in general at very low temperatures.

Having regard to the great loss in magnetic susceptibility
experienced by the ferromagnetic metals in heating beyond a certain
temperature, it has been frequently suggested tbat bodies of small
susceptibility might become strongly magnetic if cooled to a
sufficiently low temperature. Faraday made many experiments on
this question, using solid carbonic acid as a refrigerating agent, but
was not able to arrive at any conclusions.

A difficulty which presents itself in the use of liquid oxygen as
a refrigerating agent for this purpose is the strongly magnetic
quality of the liquid itself. All bodies except iron, nickel, and
cobalt, and the strongly ferromagnetic bodies, become apparently
diamagnetic when placed in liquid oxygen and in a non-uniform
magnetic field.*

Moreover, for obvious reasons it is easy to weigh a diamagnetic or
apparently diamagnetic body in a non-uniform field because the forces
restoring the disturbed body to its original position increase with

* An interesting experiment was made with a ball of ebonite which illustrates
this fact. Ebonite is slightly magnetic in air, owing no doubt <o iron impurity.
Ebonite is denser than liquid oxygen. Accordingly, a small ball of ebonite
dropped into the liquid oxygen contained in the vacuum vessel of the pole of the
magnet sunk to the bottom of the vessel. On exciting the magnet the ebonite
became apparently strongly diamagnetic and was repelled by the pole. It floated
up in the liquid until it reached a level at which the diamagnetic repulsion just
balanced the apparent weight of the ball in the liquid oxygen. Instructive
lecture experiments can be made in this manner.

On the Magnetic Susceptibility of Liquid Oxygen. 327

the displacement. If, however, an attempt is made to determine the
force acting upon a paramagnetic body in a non -uniform field by a
balance, the body weighed is in unstable equilibrium.

We have only recently overcome these difficulties. The method
we have adopted for cooling the body under test, is to suspend it
freely near the bottom of a test-tube, which is placed in a vacuum
vessel, the interspace between the two being filled with liquid air.
In this way the body is cooled by radiation to the temperature of
liquid air, and yet it is suspended in, and surrounded by, gaseous air,
the magnetic susceptibility of which is exceedingly small compared
with that of liquid oxygen or liquid air.

By limiting the vibration of the balance within small limits by
the stops, or by gradually varying the field of the magnet with a
carbon rheostat, until the field is just able to move the object from a
standard position against the fixed restraining force supplied by a
constant counter-balancing weight, we have been able to effect the
measurements of the apparent weight of the tested object at a given
distance from the pole, and in a known field, even though the
equilibrium is not stable. In this way we have made preliminary
experiments on the variation in the diamagnetic susceptibility of
bismuth, and of the paramagnetic susceptibility of manganous sulphate
in the solid condition.

We made a preliminary experiment by weighing in and out of
the magnetic field a small closed glass bulb, exhausted of its air
both when in ordinary air at the normal pressure and temperature,
and then suspended on the dense gaseous air in the inner test-tube,
which is at a temperature of —182° C. lying at the bottom of the
inner test-tube, placed as above described in a vacuum vessel. We
found the magnetic susceptibility of the dense air at — 182° C. to
be -fO'2Sx!0~6, in other words about 10 times the susceptibility
of air at the normal temperature and pressure. This number O28
is quite insignificant compared with numbers of the order of 100 or
300. Hence an object suspended in the above described manner, can
be reduced to the temperature of liquid air without changing the
susceptibility of the surrounding medium by an amount which is at
all comparable either with that of liquid oxygen, or with the value
of the susceptibility of bismuth, or of most paramagnetic bodies
-such as the salts of iron, nickel, cobalt, manganese, or of palladium,
or any of the strongly paramagnetic bodies.

In this manner we have made a determination of the change in
paramagnetic susceptibility of crystallised manganous sulphate in
the form of powder.

We find that the susceptibility of the salt at 25° C. is to that
at —182° C. in the ratio of 105 to 349 or 1 to 3'32.

These centigrade temperatures, 25° C. and — 182° C , correspond to

VOL. LX1U. 2 B

328 On the Magnetic Susceptibility of Liquid Oxygen.

298 and 91 on the absolute thermometric scale, and it is obvious
therefore that the paramagnetic susceptibility of solid maiiganons
sulphate is increased by cooling so that its value varies inversely as
the absolute temperature, and is increased threefold by cooling to the
temperature of liquid oxygen.

It has been shown by P. Curie, that the above law holds good for
oxygen, palladium and other paramagnetic bodies at high tempera-
tures ; and E. Wiedeman'n (Pogg. Ann., vol. 126, p. 1, 1885) and
Plessner (Wied. Ann., vol. 39, p. 336, 1890) have shown that for
limited ranges of temperature, 16° to 60°, it is true for paramagnetic
salts in the liquid and solid condition.

Our experiments show that this law may be valid over very wide
limits, and to very low temperatures. We hope to fully examine this
matter shortly, and to make a full examination of paramagnetic
susceptibility at very low temperatures.

We have also made measurements of the magnetic susceptibility
of bismuth at the liquid oxygen temperature.

From the mean of three experiments, we find that the diamag-
netic susceptibility of bismuth is increased by cooling, and that it
has the following values : —

Diamagnetic susceptibility of bismuth at 15° C. = 13*7,

- 182° C. = 15-9,

thus showing an increase of 16 per cent, on the lower value.

The diamagnetic susceptibility of bismuth is therefore not increased
inversely as the absolute temperature on cooling.

The above considerations suggest that the very large paramagnetic
susceptibility of liquid oxygen, which is five or six times greater
than that of a saturated solution of ferric chloride, may in part be
due to its low temperature.

Some experiments we have made on the susceptibility of nian-
ganous sulphate indicate that paramagnetic susceptibility varies
directly as the density.

The density of liquid oxygen is 806 times that of gaseous oxygen
at 0° C. and 760 mm. /and its absolute temperature is just one-
third.

Hence if the law that susceptibility varies as the density and
inversely as the absolute temperature holds good down to the tem-
perature of —182° C., and over the physical change of state, we
should expect the susceptibility of the liquid oxygen to be 2418
(= 806 x 3) times that of the gas.

The magnetic susceptibility of gaseous oxygen as determined
Faraday, E. Becquerel, and others is 0'13xlO-6. Now 2418x0'
X 10-6 = 314 x 10~6.

Aluminium as an Electrode in Cells. 329

The mean value we have found for the susceptibility of liquid
oxygen is 324 x 10~6, and many of our values for it are exactly
314 Xl0-6.

It seems therefore possible that for paramagnetic bodies over wide
limits of density and temperature we may find that the magnetic
susceptibility varies directly as the density and inversely as the
absolute temperature.

We desire to add that our thanks are due to Mr. J. E. Petavel
and Mr. J. T. Morris, for their assistance in carefully carrying out
the tedious work of the ballistic observations, necessary to determine
the field of the electro-magnet we have used.

" Aluminium as an Electrode in Cells for Direct and Alternate
Currents." By E. WILSON. Communicated by Dr. J. HOP-
KINSON, F.R.S. Received May 11,— Read May 26, 1898.

This paper deals with the apparent great resistance which alumi-
nium offers to the passage of an electric current when used as an
anode in cells containing, for instance, such an electrolyte as alum in
water. The following are references to papers which deal in whole
or in part with this or other properties of aluminium when employed
as an electrode in electric cells.

Wheatstone. ' Eoy. Soc. Proc.' Read April 26, 1855. This is the
earliest paper I have found dealing with the metal aluminium in
voltaic cells, but Wheatstone does not appear to have noticed the
apparent great resistance mentioned above.

Heeren. ' Mittheil. des Gewerbevereins fur Hannover,' Jahrg.
1855, p. 342. Reference is made in this paper to Wheatstone's
experiments.

Buff. ' Liebig's Annalen,' 1857, vol. 102, p. 269. The author of
this paper points out that nine Bunsen elements were not able to
pass a current through a cell having aluminium as an electrode.
This is the first mention of this property I can find.

Ducretet. ' Comptes Rendus,' 1875, vol. 80, p. 280 ; also ' Journ.
de Phys.,' 1875, vol. 4, p. 84. Observed great resistance in dilute
sulphuric acid due to aluminium plate.

Beetz. ' Wied. Ann.,' 1877, vol. 2, p. 94. Supposes oxygen to be
the cause of this apparent high resistance.

Winkelmann. ' Wied Ann.,' 1883, vol. 20, p. 91.

Wright and C. Thompson. ' Phil. Mag.,' 1885, Part 9, Series 5,
vol. 19, pp. 27, 116, 203. Call attention to the non-compliance of
aluminium with thermochemical data. Reference is made to the
work of Julius Thomsen.

2 B 2

330 Mr. E. Wilson. Aluminium as an Electrode

Laurie. ' Phil. Mag,,' 18S6, Series 5, vol. 22, p. 213. Investigates
the effect of amalgamating aluminium, and points out the important
part played by the oxide or suboxide of aluminium.

Streintz. ' Wied. Ann.,' 1887, vol. 32, p. 116; also ibid., 1888,
vol. 34, p. 751. Suggests a kind of dielectric polarisation distinct
from ordinary electrolytic polarisation as cause of the apparent high
resistance of aluminium.

Herroun. 'Phil. Mag.,' March, 1889. Refers to the disconformity
of aluminium in voltaic cells with ordinary theory.

Hutin and Leblanc. ' Etude sur les Courants Alternatifs et leurs
Applications Industrielles,' Part 2, Chap. 10, p. 135.

Graetz. ' Wied. Ann.,' 1897, vol. 62, No. 10, pp. 323—327 ; also
* Journ de Phys.,' 1898, Series 13, vol. 7. This paper specially deals
with alternate currents and will be referred to again. With regard
to direct currents, Graetz gives 22 volts as the electromotive force
which aluminium as anode is able to oppose.

Pollak. ' Comptes Rendus,' 1897, vol. 124, p. 1443. With alka-
line solutions, Pollak says he can overcome 140 volts continuous
pressure. Proposes to use aluminium as one pole of a cell for the
purpose of producing a uni-directional current from alternate
currents.

Lang. 'Wied. Ann.,' 1897, vol. 63, pp. 191—194. Uses an
electric arc with aluminium and carbon poles for the purpose of
rectifying an alternate current.

PART I.
Direct Currents.

Two sizes of cells have been used in these experiments, each
having aluminium and carbon electrodes. The large size consists
of one aluminium plate, -^ inch thick, and one carbon plate, \ inch
thick, separated by ebonite bolts and nuts, the distance between the
plates being J inch. The surfaces thus opposed to one another in an
electrolyte of saturated potash alum in water have each an area of
36 square inches. The aluminium plate was not bought as being
specially pure, and may have 2 per cent, impurities. After making
preliminary experiments with alternate and direct currents over a
lapse of four days, the following experiment was made with this cell
and was repeated.

An exploring electrode was inserted midway between the plat(
and consisted of a platinum wire sealed into a glass tube. The wii
beyond the tube had a length of about 2 inches, and was coiled int
a small spiral, the plane of the spiral being parallel with the surfa<
of the plates. A Kelvin quadrant electrometer was arranged with
two-way switch, so that the potential between this electrode an<

in Cells for Direct and Alternate Currents.

33 L

either the carbon or aluminium plate could be observed. The cell
was placed in series circuit with another, similar in all respects,
except that the distance between the plates was §• inch instead of
i inch, an adjustable resistance, and an ammeter. By means of a
reversing switch this circuit could be reversed across the poles of
twenty-two storage cells having a potential difference of 44 volts.
The temperature of the cell was about 12° C. The negative pole of
the storage cells was connected to the aluminium plate and the
current adjusted to 3*6 amperes, the potential difference between the
aluminium and carbon plates being 4'4 volts, and gas evolved freely.
On reversing the connections, that is, placing the positive pole of the
charging battery to the aluminium plate, the current, so far as this
ammeter could show, was zero, the potential between carbon and
aluminium being about 22 volts. The surface of the fluid was
maintained in a state of agitation, but no gas was evolved, except
in very small quantity, if any.

The figures in Table I show how the potentials between the

Table I.

Keversal from Al anode to
Al cathode.

Keversal from Al cathode to
Al anode.

Volts be-

Volts be-

Volts be-

Volts be-

Time in
minutes
after
reversal.

tween Al
plate and
exploring
electrode.

tween C
plate and
exploring
electrode.

Amperes.

tween Al
plate and
exploring
electrode.

tween C
plate and
exploring
electrode.

Amperes.

0

+ 16-6

+ 1-63

0

-1-74

-2-73

-3-56

About £

-3-81

-2-04

-3-35

+ 14-3

+ 0-30

+ 1-20

1

-2-48

-2-40

-3-42

+ 18-2

-t-1-57

+ 0-64

2

-2 23

-2-79

-3-47

+ 19-1

+ 1-64

0

3

-1-9

-2-84

-3-49

+ 19-6

+ 1-67

0

4

-1-9

-2-84

-3-50

+ 20-0

+ 1-68

0

5

. .

. ,

. .

+ 20-5

+ 1-67

0

7

-1-65

-2-84

-3-55

13

-1-74

-2-73

-3-56

190

••

••

••

+ 17-9

+ 1-76

0

•

exploring electrode and the carbon and aluminium plates respec-
tively, as also the current, varied in terms of time after reversal
took place. The time between the two reversals in Table I was
27 minutes. There is no doubt but that the current, when reversal
took place from 3*6 amperes, first crossed the zero and acquired an
opposite sign, finally coming to zero of the instrument.

This is an important point, and was fully established during

332 Mr. E. Wilson. Aluminium as an Electrode

another set of experiments undertaken to find the resistance of the
electrolyte. For this purpose the plates were separated to the extent
of 1T3¥ inch, and two platinum exploring electrodes used, the dis-
tance between them in the electrolyte being Tf inch, along a straight
line perpendicular to the parallel surfaces of the plates. Each time
reversal took place from negative to aluminium, to positive to
aluminium, the potential between these electrodes changed sign, and
gradually returned to near zero. The results of the experiments on
resistance show that at this temperature the resistance of a layer of
electrolyte of area equal to the area of the plate submerged, and of
length equal to the distance between the electrode and the plate,
that is |- inch in the experiment of Table I, is 0'063 ohm. The cor-
rection is therefore small with current 3'6 amperes, and is negligible
when the positive pole is connected to the aluminium.

The next set of experiments were carried out with aluminium
Y1^ inch thick, of 99 '5 per cent, purity, the electrolytes being specially
pure, and only distilled water used. The cells used are of a smaller
size, and each consists of one aluminium plate, 1J inches wide,
having a carbon plate on each side of it, the distance between the
aluminium and carbon being g-5^ inch, the carbon plates being 2f inches
wide and J inch thick. The aluminium plate was submerged
2f inches in the electrolyte, so that the total area for current is
8J square inches.

Two such cells were prepared, one with a 10 per cent, by volume
solution of H3S04 in water, the other with a saturated solution of
potash alum, and left for forty-seven hours with a current of ¥a¥ ampere
passing through each in series, the positive of charging cells being
connected to aluminium. At the end of this time, and with this
current, the potentials across the cells were 2*4 volts for the H2S04
solution, and 9 volts for the alum solution. On breaking the
circuit, the potential of the H2S04 solution cell fell to about 0'38 volt
in one minute, and rose fairly gradually to 2*4 volts on making circuit.
The alum solution cell lost its potential immediately on breaking
circuit, that is, the electrometer needle appeared to return to zero,
as though there were no opposing electromotive force. When the
current was reversed, that is negative to aluminium, and still of the
value ¥V ampere, the H2S04 solution cell gave 0'24, and the alum
solution 1'29 volts.

The aluminium plate which was formed in the H2S04 solution,
together with its carbon plates, were next washed in distilled water,
and placed in a saturated solution of alum. Eleven storage cells
were connected without extra resistance in circuit to each of these
cells positive to aluminium, and the resulting current noted. The
plate which had been formed in H2SO4 allowed about 0'2 ampere
to pass, and in 4 hours 10 minutes this current had risen to about

in Cells for Direct and Alternate Currents.

333

1 ampere, the temperature of the cell having risen. The plate
formed in alum solution only allowed 0'083 ampere to pass. The
two cells were then placed in series and left for 13 hours, with
gSj- ampere passing from the aluminium to carbon plates in each.

The following test was then made. The cells had opposed to
them, aluminium to positive, in turn from 1 to 20 storage cells,
without extra resistance, rising a cell at each step, the resulting
current and potential across the terminals being noted. The results
are given in Table II. We see that from 1 to 18 storage cells the

Table II.

Number

Plate formed in dilute H2SO4.

Plate formed in alum solution.

of storage
cells
applied.

Yolts
across cell.

Amperes.

Tempera-
ture C.

Yolts
across cell.

Amperes.

Tempera-
rure C.

1

1-89

0-0005

13

1-89

0-0009

13

2

3-78

0-026

3-87

0-026

3

5-67

0-034

5-76

0-036

4

7-65

0-036

7-56

0-053

5

9-54

0-036

9-45

0-053

6

11-3

0-050

11-3

0-077

7

12-6

0-055

12-6

0 -062

14

8

14-4

0-062

14-4

0-098

9

17-1

0-069

16-2

0-108

14-5

10

19-8

0-070

19-8

0-12

15-5

11

21-6

0-079

21-6

0-13

15-7

12

23-4

0-089

23-4

0-144

16

13

25-2

0-096

25-2

0-161

17

14

27-9

0-120

27'9

0-178

15

29-2

0-127

20

29-2

0-20

18

16

31-5

0-191

31-5

0-191

18

34-2

0-987

35-1

0-34

20

39 -I

increased

ii*

39-6

increased

19i

rapidly, to

rapidly to

4 amperes,

1 ampere,

circuit then

circuit then

broken

broken

16

29-7

0-9

23

30-6

0-29

currents gradually increase in each, the plate formed in H2S04
having an apparent greater resistance, up to about 16 cells. With
20 cells applied the H2S04-formed plate gave way with great
rapidity, and in a very short, time, about fifteen seconds, the current
was 4 amperes, the temperature of the cell rising also from 21° C.
to 23° C. The alum-formed plate seemed more stable with 20 cells,
but speedily allowed a current of over 1 ampere to pass. On going
back to 16 cells the currents were 0'9 ampere in the HjSCVformed
plate, and 0'29 ampere in the alum-formed plate.

334

Mr. E. Wilson. Aluminium as an Electrode

Tliis brings us to the effect of temperature upon potential for a
given current. The cell containing the aluminium, plate formed in
alum solution above referred to was placed in an oil bath, the tem-
perature of which could be varied. The current was that due to
56 storage cells, through a considerable external resistance, about
650 ohms during heating, and 2280 during cooling. There was an
excess of alum in the cell, and the solution was kept saturated. The
variation of potential between the aluminium and carbon electrodes
was noted, as also the temperature of the cell. The results are
given in Table III.

Table III.

Time.

Amperes.

Volfs.

Temperature
C.

Remarks.

h. m.

Current switched on

0 0

0-16

rising

13-5

+ to Al

0 5

0-124

29

»

»>

0 10

j*

30

5>

0 15

0-169

1-3

14

- to Al

0 16

0-122

32

»

+ toAl

1 55

0*132

26-1

20-4

»

2 0

0-172

1-1

»

- toAl

1

0-124

31

+ to Al

8

0 -132

24-7

25

5>

12

0-139

20-2

29-5

»

20

||

11-7

36-5

»

22

0-141

7-65

43

J>

27

0 -143

7-2

52

5>

28

0-155

1-1

- to Al

30

0-141

7-2

56

+ to Al

33

0-143

5-4

61

»

37

0-148

3-0

70

j>

44

0 -0518

0-18

72

?>

3 15

n

0-72

63

»

25

»>

1-3

56-5

5>

31

0-0509

2-3

51

))

50

j j

2-7

40

,,

22 50

0-018

10-3

12

5>

We see that as the temperature of this cell rises from 13*5 to 70° C.,
the potential difference falls from 30 to 3 volts. The experiments
already made on the resistance of the electrolyte will only account for
0-043 volt at 13-5° C., and 0'025 volt at 57° C. with the currents 0-124
and 0-141 ampere as given in Table III. The conclusion is that
temperature has an effect upon the apparent high resistance of an
aluminium plate and its film, the subject of this paper. This points
to the fact, that in practice for high apparent resistance, it would be
necessary to cool or circulate the electrolyte with such dissipation of
energy, that the cell would otherwise acquire a high temperature.

in Cells for Direct and Alternate Currents. 335

In Table III we see that as the cell cools with a smaller current of
about 0'051 ampere, the potential between the aluminium and carbon
plates rises. In this case at 56, and 12° C., the electrolyte would
account for O0093 and O017 volt respectively.

It was thought that if a plate of aluminium with its film were
submerged in mercury, the resistance between the metal and mercury
might give an idea as to whether resistance, pure and simple, played
an important part in the effects observed. The plate originally
formed in H2S04 solution was carefully removed, washed in distilled
water and dried, and half submerged in clean mercury. Storage
cells ranging in number from 1 to 15 were applied as in Table II,
but in each case the poles were also reversed so as to test the insula-
tion with the two directions of currents. The results show that this
film on aluminium is a fairly high insulator, but it was not stable.
At times .the resistance was zero, when a sharp noise occurred in the
cell like sparking between points in air, and the insulation was
immediately restored. With 16 volts applied, the apparent resistance
was about 10,000 ohms, whereas from Table II we see the apparent
resistance of the whole cell is 230 ohms at 14 volts, the positive pole
being connected to aluminium. I should say, judging from the
number of times the film broke down, that it was more stable when
the positive pole of the charging battery was connected to the
aluminium ; but in either direction the resistance, when established,
had the same order of magnitude. Up to six cells, no extra resistance
was included in the circuit as the film was stable, after this a resist-
ance was inserted so as to keep down the current when the film broke
down, as then the potential between Al and Hg was zero. Even at
30 volts the film was able to restore its insulating properties, but very
rarely. On removing the plate, a film was left on the mercury where
it had been in contact with the film on the aluminium plate.

Another set of experiments was made with two cells having
as electrolytes a 5 per cent, solution of H2S04 in water, and a saturated
solution of potash alum in water. The area of the pure aluminium
plate exposed to the fluid was 17 square inches in each cell. A
current of 1 ampere was passed for four hours through the HzSO*
solution cell, and three hours through the other. At the end of these
times the temperatures were respectively 33 and 51° C. With the
1 ampere passing from Al to C, the potentials between the plates were
respectively 6'3 and 20 volts. The cell containing the plate formed
in potash alum solution was then heated, the current through it being
kept fairly constant by means of a considerable external resistance
and 110 volts. It was then cooled by placing it in a freezing mixture
of ether and carbonic acid snow. The temperature in this case was
reduced somewhat rapidly, and a portion of the electrolyte at the
bottom was frozen, probably a cryohydrate, leaving liquid above.

336

Mr. E. Wilson. Aluminium as an Electrode

The temperature of this liquid portion did not fall below zero centi-
grade. The results are given in Table I HA. When comparing these

Table HlA.

Time.

Amperes.

Yolts
across
one cell.

Tempera-
ture.

Remarks.

Seating.

12.45 p.m.

0-154

28-8

17

Al connected to positive pole of

1.0 „

0-154

27-0

18

charging cells.

3.40 „

0-174

15-3

24

4.20 „

0-170

16-2

25

6.40 „

0-187

16-6

26-5

Cooling.

11.0 a.m.

0-161

29-2

13

The temperatures are those of the

11.8 „

0-160

30-1

11

liquid electrolyte.

11.35 „

0-158

30-8

3

12.0 noon.

0-160

31-0

1

12.30 p.m.

0-168

26-3

2

Bottom portion of electrolyte found

i.o „

0-170

25-2

2

frozen.

1.10 „

0-055

4-95

2

1.12 „

0-058

1-35

2

Al to negative.

1.14 „

0-235

2-25

2

>> >»

1.15 „

0-165

26-6

2

Al to positive.

2.50 „

0 158

31-2

not known

Fluid portion of electrolyte poured

away, only frozen portion remain-

ing.

with the results of Table III, one must remember that the areas
of the plates in the electrolyte are 17 square inches in Table IIlA
and 8£ square inches in Table III. This paper does not deal with
the chemistry of the effect discussed. It is known that a clean
aluminium plate acquires this film, when simply submerged in alum
solution, in the presence of oxygen, without the passage of currents.
We have seen that with a given film time is required to develop the
effect.

[Note added 19th May, 1898.

The film on these plates has been examined by Mr. Herbert Jack-
son, of the Chemical Department, King's College, London, and the
following is his communication.

" King's College, London,

" May 12, 1898.
" DEAR WILSON,

" I waited to send you the results of my examination of the
aluminium plates until I had looked at them carefully with the

in Cells for Direct and Alternate Currents. 337

microscope. Not much information, however, is to be gained from
this. The skin over the plates is, however, seen to be full of minute
cracks in everj direction, giving the impression of a dried gelatinous
pellicle; not an unexpected appearance if the plate had been covered
when wet with a thin coating of the gelatinous aluminium
hydroxide. The analysis of the film over the metal shows it to
consist of basic aluminium sulphate. The origin of this may of
course have been the formation in the first place of aluminium
hydroxide which subsequently reacted with some of the alum solu-
tion to give the basic compound. How far the formation of this
may have anything to do with electrolysis would, I should think,
be difficult to say without further and more elaborate experiment,
and it must be remembered that a similar coating can be obtained
on an aluminium plate by immersing it in an alum solution and
leaving this freely exposed to the air.

" Yours sincerely,

" HERBEKT JACKSON."

I have tried an experiment which I think shows that a film formed
on aluminium by first being placed in contact with an alum solu-
tion and then exposed to the air, gives the same effect as a film
formed in the cell when a current is passed from the aluminium to
a carbon plate through the electrolyte. Two similar bright alu-
minium plates were prepared with carbon plates on either side of
them, the area of aluminium in the electrolyte being 8J square
inches. The electrolyte consisted of a saturated solution of potash
alum in water. One plate was left in the solution for seven hours
with no current passing, and then exposed to the air for 16f hours.
The other plate was submerged in the fluid and immediately read-
ings were taken of the current passing and potential difference in
volts between the aluminium and carbon plates. The effect in this
case was exactly what was previously observed. That is to say, the
current being maintained constant at 0'055 ampere by about 2000 ohms
being inserted in circuit with the cell across about 110 volts,
the potential difference immediately passed from a small negative
value through zero, and after three minutes and forty minutes, had
respectively the values 1'8 and 2'27 volts ; the temperatures being
12^ and 15^° C. The test was continued. For the next 5£ hours
the current was 0'204 ampere, it was then dropped to 0*055 ampere
and kept at this value for 16J hours. At the end of this time the
potential was 10 volts with 0'055 ampere, and 28*6 volts with 0'163
ampere, the temperature being 15° C.

The other plate was submerged in its solution, the potential differ-
ence and current being immediately noted as before. The results in
this case show that the potential, with 0'054 ampere, rose immediately

338 Mr. E. Wilson. Aluminium as an Electrode

from a small negative value of about O2 volt to a positive value of
1*8 volts. After four minutes and forty minutes respectively the
potential with current O054 had the values 2*07 and 2'56 volts, the
temperatures being 13 and 15'5° C. This, I think, shows that a film
formed by exposure to the air after being submerged in a saturated
alum solution, has the same effect as another formed in this electrolyte
during the passage of current. This test was continued. After
twenty-four hours, during which the current was O0523 ampere, the
potential was 11 volts, with this current passing, and the temperature
16° C.

The two cells were then placed in series and an average current of
0'048 ampere passed through them from the aluminium to carbon
plates for fifty hours. At the end of this time, with current 0 048
ampere, the potentials were 10 in the case of the plate partially
formed without current, and 10*3 in the case of the other; the
temperatures being 19 and 17J° C. respectively. With current O121
ampere, the potentials were 26'2 and 27'4 respectively at tempera-
tures 21 and 19J° C.]

Sodium hydrate forming a weak solution in water was tried as an
electrolyte, the area of the Al plate being the same as before, 17 square
inches. The forming current of 0'8 ampere was passed from Al to C
for 2 hours 20 minutes, when the potential between the plates was
13*6 volts, the aluminium plate being covered with a thick black
deposit.

PART II.
Alternate Currents.

The experiments with alternate currents were undertaken in order
to investigate the instantaneous values of potential and current.
One object was to see if the effect we have dealt with in the first
part of this paper has time to properly develop with ordinary
frequencies, and if so under what conditions. Another object was to
see if aluminium is a valuable metal for use in condensers for alter-
nate currents.

Aluminium- Carbon Cells.

If the time taken to develop the effects dealt with in the first part
of this paper were very small compared to the time of a complete
period of an alternating potential applied to the cell, one would
expect to get a practically uni-directional current in the circuit of
the cell under favourable conditions as to temperature and applied
potential. This is not the case with the cells and frequencies dealt
with in this paper. In all these experiments the author has
endeavoured to make the cells the controlling part of the circuit,

in Cells for Direct and Alternate Currents.

339

that is to say between the terminals of the alternate current machine
a small non-inductive resistance and a Siemens dynamometer were
the only part of the circuit other than the cells experimented upon.
The copper resistance of the circuit including armature was from 1
to 5 ohms.

In the first portion of these experiments, the results of which are
given in Table IV, the instantaneous values of the current, and the

Table IY.

First half period.

Second half period.

a

.

•t

4

0

,

&

E

!

1

*°

11

o> a

£
1

£
^

i!

15

£
£

'i

Si

i

£f

II

nperatu

•

>>

£

£

« Ji
aa s

£

g

^s

Ii

E

'St^

& •

£

g

3

s

s

t ii

^s

•

<u C

<a

C

5

fi

£

« "

Ej

£

o.2

•

cu c

?o

1

I

1

\

P

03

£B

11

•^

|I

I1

(1)

92

8-9

5-2

24°

26

4-0

56°

1 -35

26-8

3-28

27

(2)

91

7-3

1-6

57

8-9

1-5

69

i-or

2-65

1-10

9

(3)

91

14-2

16-2

6

33

9-9

42

1-97

120

8-99

26

(4)

74-5

21-1

39-8

3

18-6

26'5

3

1-78

294

21-0

36

(5)

52

13-4

14-5

6

20'2

9'6

24

1-54

86

8-16

35

potential difference between the terminals of the cell, were observed
by aid of a Kelvin quadrant electrometer and a revolving contact
maker. The cell across which the potentials were observed con-
sisted of one aluminium plate TTg- inch thick separated by J inch from
a carbon plate J inch thick, the electrolyte being a saturated solution
of potash alum in water. The surfaces thus opposed to one another
in this electrolyte have each an area of 36 square inches. Another
cell of the same size as the above was placed in series with this cell.
Four smaller cells were used in some of the experiments as will be
set forth. Each of these consists of a thin aluminium plate opposed
to a carbon plate, the opposed surfaces in a saturated solution of
alum have each 8 square inches area, the distance between such
surfaces being J inch.

In Table IV the arrangement of these cells was as follows : —
Experiments (1) and (2) all the six cells in series. Experiment (3)
the two large cells in series with one another and with the four
small cells arranged 2 series 2 parallel. Experiments (4) and (5)
only the two large cells in series were used. No attempt was made
to cool or circulate the electrolyte, but it had considerable volume
and took some time to heat and cool. In all cases there was an
excess of salt to insure saturation. Table IV contains the important
information obtained from the tests.

These figures show that small currents are accompanied by large

340

Mr. E. Wilson. Aluminium as an Electrode

phase difference but the effect we are looking for, namely, a large
ratio between the maximum coulombs in the two halves of a period,
mainly develops with large currents for a given frequency accom-
panied by high temperature and small phase difference. The average
watts have been deduced from the product of instantaneous volts
and amperes at twenty equal intervals during a period.

The experiments in figs. 1, 2, 3 give results obtained with an
exploring electrode inserted between the plates in the electrolyte as
in the first portion of this paper. The aluminium and carbon plates
in one of the large cells were separated to J inch, and the two cells
kept in series as in experiments (4) and (5) Table IV. The curves
refer to this cell, and provision was made for obtaining the instan-
taneous values of the current in the cell, and the potentials between
the exploring electrode and either the aluminium or the carbon
plate.

In figs. 1, 2, the Siemens dynamometer in the circuit registered
the same current, namely 3*97 amperes, but the frequencies are 16
and 98'5 respectively. We see that TT¥ second is too short to allow
the effect we are looking for to fully develop, since the ratio of the
maximum coulombs is 1'47. On the other hand, if we examine the
two sets of curves we see that at 98 periods per second the potential
difference between the exploring electrode and aluminium has a
maximum value of 3'63 volts during the half period when the
coulombs have the smaller maximum, whereas at 16 periods per
second, the same maximum current is produced with a larger

in Cells for Direct and Alternate Currents.

341

fn qu<

rnc

9B-5

\

20

6(J

V\

/\

*f.S

50

Frtquency

/of

/C

/o

'bo*,

I

40

60

20

W

so

maximum potential, namely, 6'27 volts. That the aluminium plate
was an anode during the half period when the maximum coulombs
were a minimum, was proved by noting the direction of the electro-
meter deflection, when the positive pole of a Clark's cell was con-
nected to the insulated quadrant, and examining the observed
direction of the deflection during the experiment. Experiments
made upon the resistance of the electrolyte with two exploring
electrodes, employing alternate currents, show that at the tempera-

342 Mr. E. Wilson. Aluminium as an Electrode

ture afc which these experiments were made, namely, 13|-0 for the 16
frequency, and 11J° C. for the 98'5 frequency, the resistance of a
layer of the electrolyte of area equal to the area of the plate
submerged, and length equal to the distance between the electrode
and the plate, has a value of about 0'063 ohm. The curves of
potential in fig. 2 have been corrected for this, and the dotted lines
show the results. The average watts dissipated by electrolytic
hysteresis at the carbon and aluminium plates at 98'5 periods per
second, fig. 2, are 0'69 and4'5 respectively. This takes no account of
the resistance of the electrolyte, and has been obtained by taking
instantaneous products of potential and current at twenty equal
intervals during the period. During the first half -period work is
supplied at the carbon plate on the average at the rate of 4*1 watts ;
during the second half-period the plate does work on the system
at the average rate of 2' 7 watts. The aluminium plate returns
practically nothing to the system.

In fig. 3, the frequency is 101, the ratio of the maximum coulombs
in the two halves of the period is 1*7, and the Siemens dynamometer
in the circuit registered 2O6 amperes. The average temperature
during this experiment was about 55° C., but had a maximum of
64° C. at the end of the test. Under these conditions, evaporation of
the electrolyte was rapid. The experiments on the resistance of the
electrolyte at this frequency and temperature give 0'033 ohm, and
the potential curves have been corrected, the result being shown by
the dotted lines. The average rate of dissipation of energy due to
electrolytic hysteresis at the aluminium plate during the period is
153 watts, whereas at the carbon plate this rate is only 9'8 watts.
We see that the maximum volts during the half period when the
maximum coulombs are a minimum have risen to 13, whereas during
the other half period the maximum volts are only 7^-.

The paper by Graetz already alluded to, deals with alternate
currents ; and two groupings of cells with aluminium plates as the
one electrode are given, whereby he proposes to rectify alternate
currents. He gives 22 volts as the potential an aluminium cell is
capable of opposing, and states that the current could not be
measured with a delicate galvanometer. The first grouping of these
cells consists of placing between the poles of the alternator two
circuits in parallel, in each of which he places four cells in series.
The poles are reversed so that in the one circuit the predominating
current will be positive, whereas in the other it will be negative.
The other grouping of these cells is shown in fig. 4, and the author
states that he gets a unidirectional current in the circuit xy. In
this circuit he has operated a direct current motor, and deposited
copper. By superposing one of tho current curves in figs. 1, 2, or 3
on the same curve, but with reversed phases, one can form an idea

in Cells or Direct and Alternate Currents.

343

as to what the resulting current would be in the circuit xy. Curves
in fig. 5 were obtained by observing the instantaneous value of the
potential difference between the ends of a non-inductive resistance of
0'349 ohm, forming the circuit xy, fig. 4. Four small cells

were

FIG. 4.
ALTERNATOR.

HHHHH4HHhlh
HHHHWHHHF

used, each one taking the place of the group of four in the diagram ;
each or these consists of a thin aluminium sheet and a carbon plate,
the opposed surfaces in a saturated alum solution having each
10 square inches, separated by a distance of -/% inch. In fig. 5,

curve I, is the current in xy, when the current from the alternate
current machine through the system was 3'96 amperes, as given by
a Siemens dynamometer. Curve II is the current in xy, when the
Siemens dynamometer read 10'4 amperes. The frequencies were
74 and 73'3, and the temperatures of the cells 25° C. and 44° C.
respectively in the two experiments. Graetz states that with cells
VOL LXIIF. 2 c

344

Mr. E. Wilson. Aluminium as an Electrode

of sufficient size 95 to 96 per cent, of the energy of the alternate
current can be changed into direct current. The efficiency of
such a system as shown in fig. 4 will obviously be the ratio of the
rate at which work is done on xy to the rate at which work is done
on the whole system by the alternate current machine. If this is to
be 95 per cent., then only 5 per cent, must be dissipated in the cells.
An important point in connection with the working of these cells
is the wearing away of the aluminium. The thin metal used in the
small cells above alluded to is perforated with small holes, but I
have not noticed so much deterioration in the thicker sheet. The
evaporation of the electrolyte is another matter which needs con-
sideration if the temperature is raised fairly high in working.

Two Aluminium Plates in Alum Solution.

These experiments were undertaken to find what effect as a con-
denser this metal with its film has with varying frequency tempera-
ture and current. The aluminium plates in the two large cells above
experimented upon were opposed to one another in a saturated alum
solution. The distance between them was |- inch, and the opposed
areas in the solution are 36 square inches on each plate.

The important data have been collected in Table V. As a corn-
Table V.

!>£

mi

•8*8 .

Experi-
ment.

Fre-
quency.

Max.

volts
across
one cell.

Max.

amperes.

Current */me
as given
Siemens dy
mometer.

Temperature.

I'fi

*1 1

alhj

«| £ 01 QiS

Average pli
difference. '
= one period

Average rate
dissipation
energy in eel

Plates.

(<*)

96

25-0

30

Amperes.,
21-6

°C.
82

_

12°

Watts.

Al

.3 '35

24

9

—

Fe

(8

17

4"'0

8

3-9.3

53

0-72

12

150 ,

Al

1-1

11

no

—

Fe

(c)

100 32 v>

2-6 1-3

14

lti'0

54

42

Al

0-25

9

Fe

(?)

92-4 : 21-0

1-48 ! 11

11-2

60

9-l?4

Al

$

92 '4 8*0 0-51

134

- 16-6

57

I'll

Al

-1

parison two plates of ordinary sheet iron of the same area and the
same distance apart as in the aluminium cell were placed in a saturated
solution of alum and placed in series with the aluminium cell. As
before the circuit included a Siemens dynamometer and non-induc-
tive resistance, and potentials were observed for different positions of
the phase across the non-inductive resistance, and each cell, by aid
of a Kelvin quadrant electrometer and revolving contact maker.
On account of the irregular wave form of the curves of potential and

in Cells for Direct and Alternate Currents. 345

current, the ratio per period of the energy returned to the system by
the cell to the energy supplied to the cell, is given as a percentage.
If the electrolytic process were perfectly reversible, we shonld expect
the curves of cnrrent and potential to have a phase difference of one
quarter period, if they were sine curves. An examination of
Table V shows that maximum phase difference develops with the
smaller currents at lower temperature. In experiment (c) the
maximum amperes are 2'5, the maximum volts 53. The curve of
potential difference has a maximum rate of change of about
57'5 volts in g^Q- second, so that an ordinary condenser with
maximum current 2 '5 amperes would have a capacity of about
72 microfarads. We see, therefore, that aluminium is suited for the
plates of condensers. The average watts in Table V have been
deduced from the instantaneous product of potential and current at
twenty equal intervals during a period.

The foregoing experiments employed saturated potash alum solu-
tion as electrolyte. The following experiments deal with soda,
ammonia, and potash alums, first when the solutions were saturated,
and second when non-saturated. In each of the non-saturated
solutions the proportions were thirteen parts of saturated solution at
about 12° C. by volume and seventy equal parts of distilled water.
Three cells were constructed, each containing two aluminium plates
of 99*5 per cent, purity, separated ^ inch apart, and each having
33 square inches of surface in the electrolyte opposed to the other.
The results of the experiments are given in Table VI.

With regard to the saturated solutions one may say that at the
low frequency 7'5 Table VI the results are not so good as at the
high frequency 92'4 Table V. The non-saturated solutions also
show a better result with regard to efficiency at the higher
frequency.

These plates were not specially formed with direct currents and
carbon cathodes before starting the above experiments. In a pre-
liminary experiment of about one hour's duration, before the first
series at frequency 33 in Table VI were made, and starting with
clean polished plates, the maximum volts for the soda, ammonia, and
potash were, a few minutes after starting, 4*4, 21'5, and 32. The
maximum current was 0'48 ampere and the phase differences in each
case about 70°. The frequency was 23 and the temperature of each
cell about 14° C.

An experiment was tried in which two aluminium discs 6 inches
diameter and separated -^ inch on an ebonite spindle were sub-
merged to within % inch of the centre in a saturated potash alum
solution and rotated at 108 revolutions per minute by a small electric
motor. In this manner more than half the discs were continuously
exposed to the atmosphere. Two brushes bearing on copper discs,

2 c 2

346

A luminium as an Electrode in Cells.

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Contributions to the Study of " Flicker" 347

pressed into good contact with the aluminium discs, served as a
means of transmitting current through the electrolyte between the
discs. The frequency was 73, the temperature 18° C., and square root
of mean square value of current about 1 ampere. No perceptible
difference was observed in phase difference between potential and
current when the discs were rotated and at rest in the electrolyte.

The conclusion is that the effect investigated in this paper takes
time to develop, and is not fully developed with alternate currents of
frequencies sixteen and'ninety-eight complete periods per second. It
can be increased by increasing the current density for a given film, and
is greatly influenced by temperature. The metal aluminium with its
film is suitable for use as the plates of condensers, if due regard be
given to current density and temperature. It might in some cases
be found useful as an equivalent to a metallic resistance.

Messrs. Simpson, Greenbank, and Davy, Student Demonstrators in
the Siemens Laboratory, King's College, London, have given me
valuable assistance in the experimental part, and in the working out
of results. To these gentlemen I tender my thanks.

4i Contributions to the Study of < Flicker.' " By T. C. PORTER,
Eton College. Communicated by LORD RAYLEIGH, F.R.S.
Received May 13,— Read May 26, 1898.

Much work has already been done on this subject, though little of a
quantitative character. Many observers have described the curious
colour sensations which rapid alternations of light and darkness can
excite under certain conditions, admirably exemplified in the " spec-
trum tops." Foremost amongst those whose experiments and writings
have led to the present very general interest in the subjects of flicker,
and of the sensation of light and colour, may be mentioned Helmholtz,
Silvanus Thompson, Shelford Bidwell, Henry, Charpentier, and
Rood ; whilst the first to try experiments on the relative sensitive-
ness of the eye to flicker in light of different colours, seems to have
been J. Plateau, who, however, employed pigments, and not the
colours of the spectrum.

The writer's first experiments were made to ascertain the exact
relative rotations at which the flicker just vanishes in the different
colours of the same spectrum, and were carried out (a) as suggested
by Professor Rood in his ' Modern Chromatics,' with a balanced,
blackened, opaque disc, having a broad semicircular arc removed,
and (6) on a cardboard disc, half black, half white, viewed in the
different colours of the spectrum of the second order of a Rowland's
plane diffraction grating of 14,434 lines to the inch. Two sources of
light were employed, (a) direct sunshine, (b) lime-light. The results

348

Mr. T. C. Porter.

are conveniently expressed by curves (fig. 1) ; along one axis of which
the spectrum is plotted, on the other the rate of rotation of the disc.

H

\F p\E Soter \DSpectrum\C \B \& A\

This last was found from the pitch of the note, obtained by blowing air
gently through a known number of equidistant holes pierced in the
circumference of the disc, and comparing these notes with those of a
set of standard forks. Where the lime-light was used, great pains
were taken to keep the intensity of the light constant throughout
each experiment, though in these, first experiments the intensity
varied for the different curves. It may be well to point out that
owing to the nature of the spectrum of lime, the orange is somewhat
brighter and the blue and violet darker, relatively, than they are in
sunshine. It is for a similar reason, as well as for others too obvious
to mention, that the arc light was not employed. It will be seen,
that in fig. 1, the intervals of the chromatic scale are plotted in
equidistant order, and it should be remembered that the arithmetic
increase in the number of revolutions to raise the pitch of the note
from C (128 vibrations) to C (256), is only half that to raise it from
C (256) to C (512), and so on. The effect of plotting on the axis of
Y the actual number of revolutions, would be to make all the
curves a great deal steeper. It seems necessary, too, to mention

Contributions to the Study of " Flicker'." 349

that the writer's eyes are perfectly normal, and that he has a good
ear. There are so many experimental details, that to describe fully
a single observation, and to state the reasons for the many precau-
tions which mast be taken if the result is to be of any value, would
take up so much space that the writer thinks it best only to mention
a few of the more important : — The same spot on the lime was never
used twice ; the width of the slit was kept unaltered ; each disap-
pearance of nicker was witnessed by two, sometimes three, observers ;
the same time as nearly as possible was maintained between the
observations, and used in making them, in order that the retina as
well as the lime might be in approximately the same condition for
each ; the room was completely dark* and the eyes rested between the
observations, never looking at any bright objects, and, above all, not
at the lime ; the oxygen and coal gas were conveyed by special metal
pipes from gasometers in which they were stored under constant
pressure outside the building, but since the composition of both
gases is liable to variation, the intensity o? the light was maintained
constant, by regulating the supply of the gases till the nicker of a
half and half disc in the yellow vanished at the same speed of rota-
tion (generally A'). After every set of experiments, to make sure
that the illumination had not sensibly changed, the note for vanish-
ing nicker in the yellow was again observed. Experience teaches
that the blue-green is rather better than the yellow for this purpose,
and accordingly it was used in later experiments. Not more than
two curves, often only one, were drawn in twenty-four hours, and to
check the effects of contrast in consecutive experiments in different
colours, a curve was drawn (a) by taking the colours of the spectrum
from red to violet and vice versa in their natural order, and (6) by
finding the pairs of colours on either side of the yellow for which
nicker vanished at the same rate of rotation. The results of
experiments made thus agree very closely, and the writer may
say here that throughout the eight years during which the research
has been carried on, the feeling has steadily grown that in sub-
jective vision we have to do with immutable quantities, capable of
exact measurement, and which vary but slightly, if at all, with
different people.

A glance at the curves in fig. 1 will show that there is a very
great difference in the rates of rotation necessary for the disappear-
ance of nicker in the different parts of the spectrum, the speed for
the yellow being very nearly double that for the violet.

Also, that on each side of the yellow the rate decreases, until the
flicker disappears for the last distinctly visible red at the same rate
at which it vanishes for the full green.

Fig. 2 presents this last fact iu a somewhat different way, and, if
* So far as external light is concerned.

Mr. T. C. Porter.

FIG. 2.

fiw.perse^. Note for 24 holes in disc,

Ye/tow. - G(768>

• Greenish-Yellow. - F

- te/lom'sh-Green. ~E

22,

te

-I8-B

-D
Blue-Green. - c#

-•Blue. -A*

anything, nioie clearly ; the yellow and the violet — the two extremes
so far as the pteseut considerations go — are placed at the top and
bottom of the central vertical line, and the number of rotations per
second necessary for flicker just to vanish, given in the column on
the left, is seen to be (for this half-white, half-black disc) 32 for
the yellow, and 16 for the violet, and 24 for the last pair of
colours — crimson and full green. The comparative rates of rotation
for these colours thus bear the ratios of 2 : 3 : 4, which are easily
remembered.

To return to fig. 1. The curves II and IX lie considerably
above the others : they are the expression of observations made,
as suggested to Professor Rood by Dr. Woolcott Gibbs, by
viewing the spectrum through a rotating disc having a sector
of 180° removed, using a telescope. Though the form of these
two curves is practically the same as that of the others, their
higher position, due to the superior intensity of the light received
by the eye in this direct vision method, proves clearly what is already
well known for white light, that the speed necessary for the disap-
pearance of flicker increases with increase of the intensity of the
light, whatever its colour may be. No. II is for lime-light, No. IX
for sunlight, the rays of the sun being reflected through the slit by
means of a heliostat.

Of the other curves in fig. 2 not much need be said ; they are all
for lime-light, the spectrum being thrown on the rotating cardboard
disc half white and half black. The writer has thought it better not
to smooth the curves in any way.

These curves, then, not only confirm the already known fact that

Contributions to the Study of " Flicker" 351

the stimulus given to the retina lasts undiminished a shorter time
for the yellow than for any other colour, but they give the very
approximately exact relative " last " for the different colours. The
general form of the curves following very closely the curve which
expresses the luminous intensity of the spectrum obtained by
Newton, Abney, and others.

The next point seems to the writer very important, especially with
reference to what follows. Numerous experiments were made to find
out how the "last" (undiminished) for any one colour varied with
the intensity of the light ; for the present it is sufficient to say that
in every case the more intense the illumination the more rapid must
the rotation of the disc be made before nicker will vanish* Hence
we are bound to infer that as the stimulus applied to the retina
increases in intensity, the impression produced retains its maximum
value for a shorter and shorter time.

That a brighter illumination does produce a greater stimulus (i.e.,
that neither the contraction of the pupil, nor any other cause, over-
comes the effect of brighter illumination) is conclusively proved by
the fact that the brighter the light the brighter on the whole is the
disc when nicker has just vanished.

Research was next made to find out in what way the rotation of
a disc must be varied for flicker to vanish when the proportion of
the coloured to the black sector varied, the intensity of the illumina-
tion remaining constant.

Two discs were taken : one painted with Indian ink laid on as dry
as possible, and the other of the whitest cardboard procurable ; these
were dovetailed after Maxwell's method and mounted on a motor
with a tk syren " disc. This last was pierced with six, twelve, or
twenty-four holes, that the note emitted might lie within the octaves
which are both easy to sing and in which intervals can be most
correctly judged.

As the experiments took many days and nights, and it was most
important that the conditions should be as similar as possible 011
different occasions, the whole of the apparatus remained unmoved
throughout the whole set of comparative experiments ; the lime-light
burner was firmly screwed down to the base-board of the lantern.
The rotating disc was most carefully screened from extraneous light,
though if the writer repeated the experiments he would wear a black
mask to prevent the illumination of the dark sector of the disc by
even the faint light reflected from the observer's face. The writer
thinks this may account partly, though not wholly, for the asym-
metry of the curves of fig. 3 in the case of the red and yellow. The
grating was surrounded by a screen coated with the dullest optical
black, whilst another screen allowed only the special colour required
to fall on. the half of the disc viewed. Each observer regarded the

352

Mr. T. 0. Porter.

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disc from practically the same stand-point and distance, the latter
being that of most distinct vision ; moreover, he kept his eyes fixed
on the same part of the disc, so that the image of the disc did not
travel over the retina. AJ1 these are important details as will appear
later.

Before examining the curves in fig. 3, consider a disc rotating under
a fixed degree of illumination, i.e., in a light of constant intensity.
Suppose that the light is of a certain colour, e.g., yellow, and that

Contributions to the Study of " Flicker" 353

certain sector only, reflects the yellow light to the eye, the rest of
the disc being of a perfect black. Let the disc be rotating very
slowly : then, as the yellow sector passes before the eye, it will
appear as bright as possible under the giren illumination, i.e., it will
appear of no less bright a yellow than it would, if the whole disc
were yellow, i.e., the stimulus given to the part of the retina on
which its image rests, is the maximum possible to this yellow, under
this particular and constant illumination. Now, suppose the rate of
rotation to be raised until flicker has just vanished, no part of the disc
now looks so bright as the sector did at first, and since the final
brightness of the disc varies directly as the width of the yellow
sector (this is the fundamental assumption on which all the colour
equations rest, and is verified by experiments described later), then,
when the flicker has vanished, the effective stimulus at any point of the
retina is to the original and maximum stimulus as the angle of the yellow
sector is to the angle of the whole disc, i.e., 360°, the illumination being
constant throughout.

Moreover, since the mere increase in the rate of rotation has no
effect whatever on the real width and brightness of the yellow
sector, but only diminishes the time during which its stimulus is
applied to the retina, and diminishes, in the same ratio, the time the
black sector takes to pass (and the more rapid passage of the black
sector must, considered alone, tend to increase the brightness of the
disc), whilst it (the increase in rate of rotation) increases to the same
extent 'the number of stimuli applied to the retina per second, and
the number of transits of the black sector ; it follows, since the final
apparent brightness of the disc is less than if it were all yellow,
that the yelloiv sector requires a finite time in order to produce its maxi-
mum effect, and the same argument applies to any colour. This
conclusion is in complete accordance with the results of other
experimentalists.

But this is not all that these considerations prove : for since the
increase in speed of rotation diminishes in the same ratio both the
time the image of the yellow sector takes to pass over a point on the
retina, and also the time the image of the black sector takes to pass
(i.e., the time the sensation evoked by the yellow sector must neces-
sarily last undiminished, if there is to be no flicker), the increased
speed would have no effect whatever on the flicker except to multiply
the number of times it occurred per second, if it were not that a
weaker stimulus has a longer " last " (using the word " last " to
mean the duration of the sensation undiminished, after the stimulus
has been withdrawn). This is a second proof of the principle
established in a different way earlier in the present paper (p. 351).

Experiments were next made to measure directly the apparent
brightness of rotating flickerlcss discs, and to find an expression for

354 Mr. T. C. Port or.

the effect of successive equal increments to the bright sector. The
method used was to measure the distances from a movable source of
light, of the rotating disc, and of a fixed disc, of the same colour as
the bright sector of the rotating disc, when the brightness of the
two discs appeared equal. It was found that for illuminations about
the same as those used in the other experiments recorded in this
paper, the law which connects the apparent brightness with the
width of the bright sector is that enunciated before, i.e., that a
flickerless half-and-half disc appears half as bright as the fixed and
wholly white or coloured disc, at any rate within the errors of
experiment which, however, in this part of the research were not
inconsiderable. When the width of the white or coloured sector
was increased in steps of 10° at a time, the increment of the
apparent brightness in the flickerless disc followed, within the errors
of experiment, the series 1/0, 1/1, 1/2, 1/3, 1/4, &c., as it should ; and
since these fractions express the ratio between the increase of
stimulus caused at any stage by an additional 10° of coloured
sector, and the stimulus already existing before its addition, it follows
that we can, with the help of the principles established already,
predict how the rate of rotation for the disappearance of flicker must
vary with the growth of the white or coloured sector. We should
expect the first few additions of the 10° to produce the most marked
alteration (a rise, as we already know) in the rate of rotation neces-
sary for the disappearance of flicker, since the diminution in the
amount of the black sector is trifling in comparison with its total
width. Towards the final additions of 10°, we shall reach a stage
when the effect of the increment of 10° of white or colour is almost
negligible in comparison with the total width of the white or
coloured sector, but just at this time, the relative diminution of the
black sector will be most rapidly increasing, and in order that
flicker may only just be invisible, the rate of rotation must
be considerably diminished, and this diminution will bear to the
total velocity almost the ratio the diminution of the black sector
(10°) bears to its total width ; but not exactly this ratio, for since
the effective stimulus is still increasing, though the increase is small
compared with its total magnitude, and since this implies — apart
from any effect of change in the width of the black sector — that the
rate of rotation must be raised for the flicker to vanish, it follows
that the rate of rotation will not diminish at so rapid a pace as the
shrinkage of the black sector's width would demand, if it alone had
to be considered. So far, therefore, the " flicker " curve (for a disc
with a growing white or coloured sector, the angle of the bright
sector being measured on the axis of Y, and the speed of rotation on
the axis of X) will be, on the whole, symmetrical with respect to the
straight line passing through the point on the axis of Y correspond

:

Contributions to the Study of " Flicker" 355

ing to the half-and-half disc, but not completely so, for the con-
sideration just mentioned would cause the curves which are repre-
sented in fig. 3 to be steeper on the right than on the left, viewing
the curves from the axis of Y. It will be seen at once that in prac-
tice the converse is true, and the writer believes that this is due to
the fact that the black sector is not completely black. The effect of
the small percentage of light reflected from the black sector will be
at first to diminish the rate of growth of the speed necessary for
flicker to vanish, for it diminishes the contrast between the coloured
sector and the black — a contrast on which the flicker primarily
depends. The curves will therefore rise more gradually on the
right, holding the figure as already described. When there is little
of the black left, there will be proportionately little of the light
reflected from it, — and if this light be bright enough to have any appre-
ciable effect, the effect must be to make the decrease of the speed of
rotation (necessary to cause the flicker to all but reappear) more rapid,
because it lessens the effect of the narrow black sector left, giving
the impression that all the coloured sector's light has survived the
passage of the black sector, for a rate of rotation at which, in reality,
a part failed to survive, and would have produced flicker if unaided
by the light reflected from the black sector.

Thus any want of blackness in the black sector will have con-
siderably more effect during the early part of the growth of the
coloured sector, whilst the black sector is very large, than afterwards,
and this completely explains the observed departure from symmetry
in the curves constructed from actual observation. It should be
noted that from the way in which the disc is illuminated by the
spectrum, any light reflected from the black sector is of the same
colour as that of the bright .sector. If pigment had been used to
colour the bright sector, and the disc viewed in white light, white
light would have been reflected from both the coloured and the
black sector, and the effect of this would be very much harder to
explain.

Five curves will be seen in fig. 3 ; they are for different colours of
the same lime-light spectrum ; each of the capital letters gives the
exact result of an observation, carefully verified in every case. The
actual number of rotations per second can be easily found for any
point on the curves by dividing the number of vibrations of the cor-
responding note found on the axis of X by 24, the number of holes in
the syren disc. The musical intervals, so far as the diatonic scale is
concerned, are the true chromatic, and not the equal temperament
system.

The information conveyed by the position of any point on one of
the curves may be stated as follows, taking, for example, (r on the
160° line of the yellowish-green : —

356

Dr. J. W. Capsiick.

The excitation of the retina caused by the stimulus of the yellow-
ish-green light of the lime-light spectrum, reflected from " white "
cardboard in 1/72 sec. (i.e., 160/360 of 1/32) lasts undimiuished for
5/288 sec. (i.e., 200/360 of 1/32), i.e., about 1/58 sec.

Taking the next point G (180°) above this last point, we find that
the " last " of the stimulus of the same yellowish-green, applied for
1/64 sec. is 1/64 sec. Thus, tabulating the results for a few more
points including the above two,

Stimulus for Y.G. applied 1/72 sec. lasts 5/288 ; & 288/5 x 72/1 = 4147

1/64 „ 1/64 „ 64x64 =4096
1/58 „ 1/72 „ 58x72 =4176
1/49 „ 1/92 „ 49x92 =4508
1/40 „ 1/120 „ 40x120 =4800
1/32 „ 1/160 „ 32x160=5120

Hence the duration of the impression on the retina undiminished
appears to decrease as the time of stimulation increases, though
within narrow limits of variation one of these quantities is nearly
inversely proportional to the other.

With regard to the total duration of a luminous impression, the
writer would point out that nothing has been said in this paper ; the
few experiments he has made to measure this, lead to the belief that
it is almost of a different order of magnitude from the time during
which an impression remains undiminished, and is to be measured
by whole minutes rather than by small fractions of a second.

«0n the Kathode Fall of Potential in Gases." By J. W.
CAPSTICK, M.A., D.Sc., Fellow of Trinity College, Cam-
bridge. Communicated by Professor J. J. THOMSON, F.B.S.
Received May 17,— Read May 26, 1898.

It has been shown by Hittorf* that when an electric current passes
through a tube containing a gas at a pressure of a few millimetres,
there is a rapid fall of potential near each of the electrodes, with a
much more gentle fall in the space between, and whilst the fall near
the anode and in the positive column varies with the density of the
gas and the current strength, the fall near the kathode is constant.
Warburgf has made careful experiments on the kathode fall, and has
fully established its constancy. If the gas is pure and dry, the
electrodes clean, and of a metal not acted on chemically by the gas,

* ' Wied. Ann./ vol. 20, p. 705.

f ' Wied. Ann.,' vol. 31, p. 545 ; vol. 40, p. 1.

On the Kathode Fall of Potential in Gases.

357

and the current not so strong as to make the negative glow cover the
whole kathode or extend to the walls of the tube, the kathode fall
has a definite value for each gas — a value that is independent of the
pressure of the gas, or of the current strength, and that appears, in
fact, to be a constant of the gas.

This being the case, it is probable that the kathode fall will prove
to be connected with other physical and chemical constants of the
gas, and the aim of the experiments described below was to find
whether there is any intelligible relation amongst the kathode falls of
three gases, one of which is formed by the combination of the other
two.

The choice of suitable gases is very limited, for there must be no
deposition of solid matter by the current, and no chemical action
between the gas and the electrode, so that organic gases and gases
containing a halogen cannot be used — at least with metal electrodes.
The present investigation has been confined to water vapour, ammonia,
and nitric oxide and their constituents.

The general plan of the apparatus was the same for all the gases,
and is shown in the figure below.

The gas generating apparatus was sealed on at A, and a mercury
pump at L. In order to isolate the generating flask from the rest,
the mercury trap B was used. By raising the reservoir C, the mer-
cury could be made to rise above the bend at B, and thus everything
to the right could be exhausted. D is a small bulb to catch stray mer-
cury. E is the purifying apparatus, and F the vessel in which the
discharge took place. This vessel consisted of a globe 15 cm. in
diameter, into which were sealed three wires ; Gr, the anode of alumi-
nium, 2 mm. thick ; K, the kathode of platinum, 2 mm. thick, and
extending 10 cm. into the globe, so as to afford plenty of free space
for the negative glow ; and H, a thin platinum wire, covered with
glass to within a millimetre of the tip.

358 Dr. J. W. Capstick.

The parts of the apparatus were sealed together without glass taps
or india-rubber connections.

The difference of potential to be observed is that between H
and K when the current is passing between G and K. There is no
need for accurate adjustment of the distance between H and K, for
in the dark space the potential gradient is very slight for two
or three centimetres, so that all that is required is that the end of
H should be outside the negative glow. In the present experiments
it was about a centimetre from the end of the kathode.

In the earlier experiments the difference of potential was measured
by a bifilar quadrant electrometer, whose constant was determined by
means of a battery of Clark cells. In the later experiments a Kelvin
multicellular voltmeter was used.

The current through the discharge tube was supplied from 600
storage cells, a lead pencil line of variable length, drawn on a slate,
being included in the circuit, to vary the current strength.

The current is not always continuous, but sometimes consists of a
rapid succession of discharges, and when this is the case the observed
kathode fall is not generally constant. Hence a telephone was
inserted in the circuit to show when the current was continuous.
With the elementary gases the telephone was generally silent, but
with the compound gases the humming was so persistent as to come
near wrecking the work.

Hydrogen. — Warburg found the kathode fall in hydrogen to be
800 volts, but it seemed desirable to repeat the experiments, in order
to find the degree of concordance that can be obtained by different-
observers.

The gas was obtained from palladium that had been saturated
with hydrogen prepared by the electrolysis of dilute sulphuric acid.
It was purified by solid potash and phosphoric anhydride, and the
discharge tube contained a piece of sodium, to destroy the last traces
of moisture. The apparatus was repeatedly exhausted, heated, and
refilled with hydrogen, whilst the electrodes were kept red hot by a
strong current, to expel occluded gases.

The strength of the current was not measured during the experi-
ments, but it was varied by altering the resistance in the circuit, so
as to cover a varying length of the kathode with the negative glow,
and so to show whether the tube was large enough to allow the dis-
charge to pass without hindrance. The table below gives details of
the measurements.

The first column gives the pressure of the gas in millimetres of mer-
cury, the second gives the fraction of the kathode that was covered
with the glow, and the third gives the kathode fall in volts.

On the Kathode Fall of Potential in Gases. 359

p. Grlow. E.

6 J 298

Apparatus exhausted and refilled.
5 f 304

Apparatus exhausted and refilled.
2 ± 298

2 i 296

2 £ 298

More gas admitted without exhausting.
4 ± 297

4 £ 296

The mean result is 298 volts, which agrees so closely with the
value 300. found by Warburg, that no further experiments were
made.

Oxygen. — The gas was made by heating permanganate of potash,
and passed through a set of Geissler bulbs of sulphuric acid and over
lumps of potash and phosphoric anhydride before reaching the dis-
charge tube. The permanganate was twice recrystallised, dried, and
heated till it fell to a fine powder, before being introduced into the
apparatus, in order to ensure the absence of moisture, and so diminish
the risk of formation of volatile manganese compounds.

The degree of purity of the gas was tested by the spectrum of the
discharge, and it proved a difficult matter to get rid of the nitrogen.
By repeatedly exhausting and filling the apparatus with oxygen
while the glass was kept hot, the nitrogen lines were rendered very
faint, but they were not entirely removed even after continuing the
operations for a fortnight. The hydrogen lines soon disappeared
entirely, but the nitrogen lines were always faintly visible when the
current was strong enough to make the kathode red hot. As, how-
ever, a very small amount of nitrogen is sufficient to make the nitro-
gen lines far brighter than the oxygen lines, the quantity of nitrogen
present must have been extremely small.

In the observations recorded below, from two to six readings with
different current strengths were taken at each pressure. The mean
result is given for each set.

p. E

11 370

7 371

4 363

2J 370

H 373 Mean, 369

The tube was then heated, exhausted, arid refilled several times,
and a similar set of readings taken.

VOL. LXIII. 2 D

360 Dr. J. W. Capstick.

P. E.

12 370

9i 372

7 368

4± 360

3J 364

3 374

2i 374

2 374

li 373

1 373 Mean, 370

The mean of the whole is 370 volts.

Nitrogen. — Warburg's determination of the kathode fall in this gas
was made on atmospheric nitrogen containing argon, and hence it
was necessary to repeat the observations on chemically prepared
nitrogen.

In the first experiments the gas was prepared by heating ammonium
bichromate. If the bichromate is mixed with fine sand the decom-
position is easily controlled, but the gas is impure, and must be
passed over ignited copper and copper oxide, which involves the
use of hard glass and india-rubber connections. The joints were very
carefully made with thick-walled soft rubber tube, yet the observed
kathode fall, 355 volts, was the same as in air, and nearly the same as
in oxygen, and very much higher than what later experiments showed
was the true value for nitrogen. The result is interesting, as showing
the great effect of a small quantity of oxygen in the nitrogen, and
emphasises the necessity for scrupulous care in removing traces of
impurity.

The final experiments were made on gas prepared by the decom-
position of ammonium nitrite. A solution of pure ammonium
chloride was contained in a flask from the neck of which a tube a
yard long passed downwards into a mercury reservoir. When the
flask was exhausted along with the rest of the apparatus, potassium
nitrite solution could be sucked in as required by pouring a little on
the top of the mercury, and lowering the reservoir. At low pressures
the mixture of ammonium chloride and potassium nitrite does not
require heating, as the nitrogen comes off regularly and very slowly
at the temperature of the room.

The gas was passed over solid potash and phosphoric anhydrid<
and a piece of sodium was placed in the discharge tube.

In some of the experiments bichromate of potash was also added
to oxidise to nitric acid any oxides of nitrogen that might be
formed. The addition made the evolution of gas inconveniently
rapid, and the flask had to be kept cool by a water bath. The

On the Kathode Fall of Potential in Gasea. 361

difference between the measurements before and after the addition
was very small.

It is not necessary to give a detailed list of all the observations
that were made. It will be sufficient to say that before the bichromate
was added twenty-five observations were made, the mean value found
for the kathode fall was 231 volts, the extreme values being 223 and
241. After the addition of the bichromate twenty measurements
were made, the mean value being 233 and the range 225 to 238.
The mean of the whole is 232.

This is exactly the same as Warburg found for atmospheric
nitrogen, whence it appears that the presence of argon has no effect
on the kathode fall.

Water Vapour. — Distilled water from a clean silver still was
boiled to remove dissolved gases, and the apparatus was sealed up
whilst the water was still at the boiling temperature.

The greater part of the air was removed from the apparatus by
means of the pump, which contained some sulphuric acid above the
mercury, and the whole was then allowed to stand for a week, the
acid absorbing the vapour and keeping up a steady evaporation of
the water, thus gradually sweeping out any remaining air. The un-
condensed gas was ejected from the pump, and the acid renewed
from time to time. Incondensable gas never entirely ceased to pass
over, but before any experiments were made it appeared from an
estimate of the volume of water absorbed by the acid and the volume
of the air bubble in the pump, that the ratio of the pressure of the
air to the pressure of water vapour in the apparatus was reduced to
about one part in five millions. Of course, more gas came over when
the discharge was passing, but even then the quantity was very
small. Presumably the hydrogen and oxygen set free near the
electrodes recombine at other parts of the tube.

A compound gas naturally presents difficulties that are absent in
the case of an elementary gas, for as soon as the current is started
the gas becomes mixed with decomposition products, and is no longer
pure. The chief difficulty, however, arose from the intermittence of
the current. With elementary gases the current was seldom inter-
mittent, with the compound gases it was seldom constant. It was,
of course, useless to take any readings of the kathode fall when the
telephone was singing, and many [months were spent in a fruitless
attempt to find what circumstances determine the constancy or inter-
mittence of the current.

The rate of intermittence was not usually constant, as was evident
from the variation in the note given by the telephone, and the
change from sound to silence was sudden, and often accompanied by
other changes, such as the appearance of striae in the tube, and a
sudden change in the kathode fall. When the telephone was silent

362 Dr. J. W. Capstick.

it could always in the case cf the compound gases be made to sing by
a sufficient increase in the current, but a reduction of the current
density by the use of electrodes half an inch in diameter made it no
easier to obtain a constant current.

The method by which it was hoped that errors due to the decom-
position of the gas would be got rid of was to start the current, and
when by accident as it proved rather than by design, the telephone
was silent, to open the mercury trap and allow a stream of pure gas
to play on the electrodes, whilst the reading of the electrometer was
taken. It was not often that this could be carried out, for when
after repeated attempts the telephone was silenced, the usual result
of admitting fresh gas was either to make the current intermittent
or to stop it altogether.

The proceeding was carried out successfully only twice. In the
first experiment the current was steady as soon as the circuit was
closed. The negative glow covered half the kathode and the
kathode fall was 471 volts, but quickly rose to 484 as decomposition
proceeded. A little vapour was then admitted, and the fall of
potential at once sank to 467 but soon rose again to 482 when the
stream of gas ceased. More vapour was then admitted whereupon
the kathode fall sank to 469, and in half a minute rose again
to 478.

The second experiment was less satisfactory as only a single reading
was obtained. After the current had been running for a few minutes
the telephone became silent, the negative glow consisting of a bright
tip covering about a tenth of the kathode and the kathode fall being
484. On admitting more vapour it sank to 469, but before it had
risen more than a few volts the telephone begun singing again, and
could not be made to stop.

Thus we have four observations of the kathode fall in the
undecomposed gas, namely : 471, 467, 469, and 469, the mean being 469.

In both experiments the pressure of the vapour was about 2 mm.

Ammonia. — The gas was prepared by the action of soda on
ammonium sulphate that had been treated with nitric acid in the
ordinary way to remove organic substances. The ammonia was
dried with lime and absorbed in calcium chloride contained in a bulb
sealed to the apparatus.

Here, as with water vapour, the numerous attempts to secure a
constant current met with little success. Only two readings of the
kathode fall were obtained, and these were not very concordant. In
the first experiment the current had been running for half an hour
when the interim ttence ceased, and the kathode fall in the partially
decomposed gas was 510 volts. When a stream of pure ammonia was
allowed to play on the kathode, the reading of the electrometer rose
to 595, where it remained steady until, after a few seconds, the dis-

I

On the Kathode Fall of Potential in Gases. 363

charge stopped. In the second experiment the current had been
running for some time through gas at a low pressure, the kathode
fall being 410 volts. A stream of pure gas sent it up to 570, but the
telephone soon began singing, and the kathode fall sank rapidly
to 480. The mean of the two observations is 582 volts.

Nitric Oxide. — A mixture of nitre and ferrous sulphate was acted
on by dilute sulphuric acid, and the evolved gas washed with potash
solution and sulphuric acid, and absorbed in a saturated solution of
ferrous sulphate. This solution was contained in a flask, sealed to
the rest of the apparatus. The gas was given off readily without
warming when the pressure was sufficiently reduced, and was
passed over potash and phosphoric anhydride before reaching the
discharge tube.

In the case of water vapour and ammonia, when the current was
discontinuous the observed kathode fall was very variable and not
independent of the current strength, but with nitric oxide the
variation was within narrow limits, the readings always lying
between 340 and 380 volts, whether the telephone was silent or not,
and whatever the current strength, provided the kathode was not
covered with the negative glow.

The readings of the kathode fall and the appearance of the dis-
charge showed that the gas is rapidly decomposed by the current.
When the discharge first started, the kathode fall was always near
370 volts, and the glow at both anode and kathode was white. In
a few seconds the glow round the kathode began to grow blue, and
that round the anode turned pink, whilst the kathode fall slowly sank
to about 345 volts. Meanwhile the glow spread backwards along
the kathode, showing an increase of current, and hence a decrease in
the resistance of the gas.

The decomposition proceeded so rapidly that it was impossible to
get the kathode fall for the pure gas by taking the reading whilst a
stream of gas played on the electrodes, for the strength of stream
necessary to maintain the white glow of the pure gas was so great
that the pressure immediately rose high enough to stop the dis-
charge. Hence the only feasible plan was to allow the gas to
stream through the tube long enough to sweep out the products of
decomposition, then stop the stream by closing the mercury trap,
pump down to a suitable pressure, start the discharge, and take a
reading as quickly as possible.

Twelve readings were taken in this way, when the telephone was
either silent throughout or became silent a few seconds after the
current started. There wa3 never any change in the kathcde fall at
the moment when the current became constant. The readings
varied between 366 and 378, the mean value being 373.

This is so nearly the value for oxygen as to suggest a doubt of its

2 D 2

364 On tlie Kathode Fall of Potential in Gases.

accuracy. The earlier experiments on nitrogen showed that a very
slight trace of oxygen was sufficient to raise the kathode fall from
its true value 232 to 355. In fact, the values for oxygen, nitric
oxide, air, and nitrogen with a trace of oxygen, are all nearly the
same, which makes it not improbable that in each case the oxygen
alone acts as the carrier of the current.

We have, then, finally the following values for the kathode fall —

Hydrogen 298

Nitrogen 232

Oxygen 369

Water vapour 469

Ammouia 582

(Nitric oxide 373)

The last is enclosed in brackets in consequence of the doubts as to
its accuracy. If we leave the result for this last gas out of account,
it appears that the kathode fall is approximately an additive quan-
tity. Ascribing the values 149, 116, and 184 respectively to the
atoms of hydrogen, nitrogen, and oxygen, we get, by addition, 482
for water vapour and 563 for ammonia. As each of these depends
on three measurements, they may be taken as agreeing with the
observed values within the limits of experimental error. Hence, so
far as the evidence of these experiments goes, the kathode fall is a
property of the atoms rather than of the molecule.

As the kathode fall is constant for all pressures and currents
whilst the potential gradient along the rest of the tube is variable,
we may infer that no potential difference less than the kathode fall
is capable of causing a discharge through the gas. This conclusion
is consistent with the experiments of Mr. Peace,* who found that the
minimum difference of potential that gives a discharge in air is
something over 300 volts.

Assuming that the conduction is electrolytic, it seems likely, from
the analogy of the electrolysis of liquids, that the kathode fall may
prove to be a measure of the energy required to dissociate the gas
into the ions that carry the electricity, and the present experiments
were undertaken in the hope of finding some confirmation of this
hypothesis. They have not, however, provided the kind of evidence
that was anticipated. The results can only be reconciled with the
hypothesis if further assumptions are made that would put the con-
duction in gases on a very different footing from the electrolytic
conduction of liquids. The additive nature of the kathode fall
might, for instance, be taken as an indication that the carriers of the
current are provided by the disintegration of the atoms into much

* ' Eoy. Soc. Proc./ vol. 52, p. 99.

Electrodynamic Equations of a Moving Material Medium, $c. 365

smaller particles, as lias already "been suggested by J. J. Thomson
from entirely different evidence ; but the results are too few to make
further speculation on their meaning of much value.

" Note on the Complete Scheme of Electrodynamic Equations
of a Moving Material Medium, and on Electrostriction."
By JOSEPH LARMOR, F.R.S., Fellow of St. John's College,
Cambridge. Received May 17,— Read May 26, 1898.

This note forms a supplement to my third memoir on the " Dynam-
ical Theory of the ^Ether,"* to the sections of which the references
are made.

1. It is intended in the first place to express with full generality
the electrodynamio equations of a material medium moving in any
manner, thus completing the scheme which has been already devel-
oped subject to simplifying restrictions in the memoirs referred to.
To obtain a definite and consistent theoretical basis it was necessary
to contemplate the material system as made up of discrete molecules,
involving in their constitutions orbital systems of electrons, and
moving through the practically stagnant aether. It is unnecessary,
for the mere development of the equations, to form any notion of
how such translation across the aether can be intelligibly conceived :
but, inasmuch as its strangeness, when viewed in the light of motion
of bodies through a material medium and the disturbance of the
medium thereby produced, has often led to a feeling of its impossib-
ility, and to an attitude of agnosticism with reference to eethereal
constitution, it seems desirable that a kinematic scheme such as was
there explained, depending on the conception of a rotationally elastic
tether, should have a place in the foundations of aether- theory. Any
hesitation, resting on a priori scruples, in accepting as a working
basis such a rotational scheme, seems to be no more warranted than
would be a diffidence in assuming the atmosphere to be a continuous
elastic medium in treating of the theory of sound. It is known that
the origin of the elasticity of the atmosphere is something wholly
different from the primitive notion of statical spring, being in fact
the abrupt collisions of molecules : in the same way the rotational
quality of the incompressible aether, which forms a sufficient picture
of its effective constitution, may have its origin in something more
fundamental that has not yet even been conceived. But in each
case what is important for immediate practical purposes is a con-
densed and definite basis from which to develop the interlacing
ramifications of a physical scheme : and in each case this is obtained
by the use of a representation which a deeper knowledge may af ter-
* ' Phil. Trans.,' A (1897).

3(56 Dr. J. L arm or. Complete Scheme of Electrodynamie

wards expand, transform, and even modify in detail. Although,
however, it is possible that we may thus be able ultimately to probe
deeper into the problem of aethereal constitution, just as the kinetic
theory has done in the case of atmospheric constitution, yet there
does not seem to be at present any indication whatever of any faculty
which can bring that medium so near to us in detail as our senses
bring the phenomena of matter : so that from this standpoint there
is much to be said in favour of definitely regarding the scheme of a
continuous rotationally elastic sether as an ultimate one.

A formal scheme of the dynamical relations of free aether being
postulated after the manner of Maxwell and MacCullagh, and a
notion as clear as possible obtained of the sethereal constitution of a
molecule and its associated revolving electrons, by aid of the rota-
tional hypothesis, it remains to effect with complete generality the
transition between a molecular theory of the asthereal or electric
field which considers the molecules separately, and a continuous
theory expressed by differential equations which take cognizance
only of the properties of the element of volume, the latter alone
being the proper domain of mechanical as distinct from molecular
theory. This transformation is, as usual, accomplished by replacing
summations over the distribution of molecules by continuous inte-
grations over the space occupied by them. In cases where the
integrals concerned all remain finite when the origin to which they
refer is inside the matter so that the lower limit of the radius vector
is null, there is no difficulty in the transition : this is for example
the case with the ordinary theory of gravitational forces. But in
important branches of the electric theory of polarised media, some of
the integral expressions become infinite under these circumstances ;
and this is an indication that it is not legitimate to replace the effect
of the part of the discrete distribution of molecules which is adjacent
to the point considered by that of a continuous material distribution.
The result of the integration still, however, gives a valid estimate of
the effect of the material system as a whole, if we bear in mind that
the infinite term coming in at the inner limit really represents a
finite part of the result depending solely on the local molecular con-
figuration, a part whose actual magnitude could be determined only
when that configuration is exactly assigned or known. The con-
sideration of this indeterminate part is altogether evaded by means
of a general mechanical principle which I have called the principle
of mutual compensation of molecular forcives. This asserts that in
such cases, when a finite portion of the effect on a molecule arises
from the action of the neighbouring molecules, this part must be
omitted from the account in estimating the mechanical effect on an
element of volume of the medium ; indeed otherwise mechanical
theory would be impossible. The mutual, statically equilibrating,

Equations of a Moving Material Medium. $c. 367

actions of adjacent molecules determine the structure of the medium,
and any change therein involves change in its local physical constants
and properties, which may or may not be important according to
circumstances : but such local action contributes nothing towards
polarising or straining the element of mass whose structure is thus
constituted, and therefore nothing to mechanical excitation, unless at
a place where there is abrupt change of density.* In the memoir
above mentioned this molecular principle was applied mainly to
determine the mechanical stress in a polarised material medium. It
necessarily also enters into the determination of the electro dynamic
equations of a moving medium treated as a continuous system, and
even of a magnetised medium at rest, from consideration of its
molecular constitution. It is here intended only to record in precise
form the general scheme that results from it, details of demonstra-
tion being for the present reserved. Everything being expressed in
a continuous scheme per unit volume, let (u')V',iv') denote the
current of conduction, (u,v,w) the total current of Maxwell, (/,#, h)
the electric displacement in the aether and (/', g', hf) the electric
polarisation of the molecules so that the total so-called displacement
flux of Maxwell is (/+/, g+g'> h + ti) ; let p be the volume-density
of uncompensated electrons or the density of free charge, let (A, B, C)
be the magnetisation, and (p, q, r) the velocity of the matter with
respect to the stagnant sether. As before explained (§ 13, footnote),
the convection of the material polarisation (/', #', h') produces a
g^ast-magnetisation (rg'—gh1, ph' — if, 2jP~-jPflO which adds on to
(A, B, C). Also, as before shown, the vector potential of the
Bsthereal field, so far as it comes from the molecular electric whirls
which constitute magnetisation, is given, for a point outside the
magnetism, by

dz dy/ r

(Imn) being the direction vector of cS, and therefore is that due to
a bodily current system (-5 — ,...,...) together with current

sheets on the interfaces. When the point is inside the magnetism,
there are still no infinities in the integral expressing F, and this
transformation of it by partial integration is still legitimate. But

* This exception explains why the mechanical tractions on nn interface, deter-
mined in § 36 as the limit of a gradual transition, are different from the forces on
the Poisson equivalent interfacial distribution.

368 Dr. J. Larinor. Complete Scheme of Electrodynamic

the spacial differential coefficients of (F, Gr, H) are also involved
in the forcives of the eethereal field, and with them the case is
different : the transformation by parts is then analytically wrong,
owing to neglect of the infinite elements at the origin, while
in actuality a finite portion of the whole effect arises from the
influence of the neighbouring molecules. We have, therefore, by the
molecular principle, to separate the infinite elements from the
integrals and leave them out of account ; and this is effected by
employing the second form above for F, which differs from the first
form only in having got rid of the local terms at the origin in its
differential coefficients. Thus it is not merely convenient, but even
necessary for a mechanical theory, which considers distributions
instead of individual molecules, to replace magnetism by its equival-
ent continuous current system as here. The g^£m'-magnetism arising
from electric convection adds to this equivalent current system
the additional bodily terms

together with surface sheets : thus the volume current so added has
for aj-component

dx

_
dy V*'

where ~- represents -: + -r- + -5— + -7- > or the rate of cnange

~- represents -4: + -^r- + -5— + -7-
dt dt dx dy dz

f supposed associated with the moving matter. Combining all
these parts, the current and magnetism together are completely
represented as regards determination of electric effect by what we
may call the total effective current («15 vh w\) where

dC dE

Bf

dpg' dph'

together with superficial current sheets arising from the true
magnetism (A, B, C) and the electric convection. Since p is
equal to

d(f±f)_
dx

dz

we may write

in

which the last term may be expressed as —

lunations of a Moving Material Medium, cj-c. 369

It is to be observed that this effective current satisfies the condi-
tion of incompressible flow,* which by definition (or rather by the
aethereal constitution) is necessarily satisfied by the total current
(u, v, w) of the previous memoirs ; for the additional terms which
represent the magnetism clearly satisfy the stream relation. f The
remainder of the scheme of electrodynamic relations is established as
in the previous memoirs. Thus (F, G, H) now representing simply
j(^i> ^i> Wi)r-1^T, which satisfies the stream relation dFldx + dGldy +
dH/dz = 0 because (uit v-^ Wi) is a stream vector, we deduce an
electric force (P, Q, R) acting on the electrons, where

also an aefchereal force (P', Q', R') straining the aether, where
P' = -lire3-1/ =

the function % being determined in each problem so as to avoid
aethereal compression.

Across an abrupt transition, F, G-, H and the normal component
of («i, ri, w\) must be continuous, thus making up the four necessary
and sufficient interfacial conditions. The gradients of F, G, H are,
however, not continuous when there is magnetisation or dielectric
convection, on account of the effective interfacial current sheets
before mentioned.

The exact value of the mechanical force (X, Y, Z) per unit
volume, comes out as

Q , A , r> , n

X — (v—~ 7— (w— -y-)/3+A— + B — -f C-y
\ dt ! \ dt / dx dy dz

where a = dHe— dGtfc— 4wA.

* It is proposed to call a flow-vector which obeys this condition a stream, the
more general term^ow ovjlitx including cases like the variable stage of the flow of
heat in which the condition of absence of convergence is not satisfied. The two
main classes of physical vectors may be called fluxes and gradients, the latter name
including such entities as forces and being especially appropriate when the force
is the gradient of a potential. Lord Kelvin's term circuital flux has previously
been used to denote a stream vector ; but it is perhaps better to extend it to a
general vector which is directed along a system of complete circuits.

f The («, v, w} of § 13, however, included a part arising from convection of
electric polarisation. Notice that when this is transferred to the magnetism, as
here, we have u — n' + dfldt + dfldt+pp: thus when there is no conduction and
p is therefore wholly convected so that Spjdt is null, the stream character of the
total current simply requires d(f+f'}ldx + d(g+g')ldy + d(h->rh')ldz =«= p. so that
the formulation is now easier and more natural.

370 Dr. J. Larmor. Complete Scheme of Electrodynamic

In these formulae, with the exception of the one for («ls vh w^
above, (A, B, C) includes the quasi-magnetism arising from electric
convection, while («, r, w) is the total electric current that remains
after all magnetic effect of whatever type has been omitted. It is
to be noted that the final terms in X involve in strictness the
asthereal force, instead of the electric force as in § 39.

It follows from the formula for (P, Q, R) that

^?_^9- _?^ / — j,jL A

dy dz dt \ dx dy dz

hence Faraday's circuital relation holds good provided the velocity
(pj q, r) of the matter is uniform in direction and magnitude.
Again, since (F, Gr, H) is a stream vector,

dc db _ 2-Bi _ / ,dG
dy dz \ dy

where («, v, w) represents the total current of Maxwell, and (A,
B, C) the whole of the magnetism and the quasi- magnet ism of con-
vection : hence

dy dz

so that Ampere's circuital relation holds, with the above definition of
(a, /3, 7). under all circumstances.

But in circumstances of electric convection these two circuital
relations would not usually by themselves form the basis of a com-
plete scheme of equations, as they do when the material medium is
at rest.

To complete the scheme, the above dynamical equations must be
supplemented by the observational relations connecting the conduc-
tion current with the electric force, the electric polarisation Avith the
electric force, and the magnetism with the magnetic force. In the
simplest case of isotropy these relations are of types

u' = ffP, f — (K — l)/47rC2P, A — Kx + (rg'—qhf).

It is to be observed that the physical constants which enter into the
expression of these relations will presumably be altered by motion
through the aether of the material system to which they belong :
but because there is nothing unilateral in the system, a reversal of
this motion should not change the constants, therefore their altera-
tion must depend on the square pf the ratio of the velocity of the
system to that of radiation, and would only enter in a second
approximation.

The various problems relating to electric convection and optical

Equations of a Moving Material Medium, fyc. 371

aberration worked out in §§ 14 — 16, pp. 225 — 229, will be found to
fit into this scheme. I take the opportunity of correcting an erratum
in p. 226, lines 16, 17, which should read

with of course different values of the constants.

2. In a material dielectric the bodily mechanical forcive is derived
from a potential — (K— l)F2/87r, and there is also a normal inward
traction KP2/87r where it abuts on conductors. For the thin dielec-
tric shell of a condenser this forcive could be balanced by a hydro-
static pressure (K— l)F2/8:r together with a Maxwell stress
consisting of a pressure F2/8;r along the lines of force and an equal
tension at right angles to them : in fact this reacting system gives
the correct traction over the faces of the sheet and the correct
forcive throughout its substance. If the sheet has an open edge the
tractions on that edge are however not here attended to ; when the
sheet is thin these are of small amount, and their effect is usually
local, as otherwise the nature of the edge would be an important
element. Moreover, in the most important applications of the
formula the edge is of small extent, so that they form a local
statically balanced system. The stress above specified will thus
represent the material elastic reaction, provided the strains in the
different elements of volume, which correspond to it, can fit together
without breach of continuity of the solid material. This condition
will be secured if the shell is of uniform thickness so that F is constant
all over it : in that case, therefore, the elastic reaction in the material
will make up a pressure KF2/8w along the lines of force and a
pressure (K— 2)F2/87r in all directions at right angles to them, which
is the result obtained for solids in § 76.

If, however, the coatings of the condenser are not supported by the
dielectric shell, the elastic reaction in the shell will be simply a
pressure (K— l)F2/87r uniform in all directions. This is what
actually occurs in the case of a fluid dielectric, where such support
is not mechanically possible.

It appeared from § 79 that in glass there is actually an increase of
volume under electric excitation, while the mechanical forces would
produce a diminution : and the same is true for most dielectric
liquids, the fatty oils being exceptions,* though by a confusion
between action and reaction the result was there stated as the
opposite. It thus appears that in general an intrinsic expansion, in
addition to the effects of the mechanical force, accompanies electric

* In the cognate case of magnetisation of ferrous sulphate solution, Hurmuzescu
iiiuls a contraction of volume.

VOL. LX1I1. 2 E

372 Electrodynamic Equations of a Moving Material Medium, $c.

excitation of material dielectrics. This circumstance will perhaps
recall to mind Osborne Reynolds' theory of the dilatancy of granular
media, which explains that the discrete elements of such media
tend to settle down under the mutual influences of their neighbours so
as to occupy the smallest volume, and therefore any disturbing cause
has a tendency to increase the volume.

In § 80, on the influence of electric polarisation on ripple velocity,
the result stated for dielectrics should be doubled. It is to be
remarked that a horizontal dielectric liquid surface becomes unstable
in a uniform vertical electric field when the square of the total con-
tinuous vertical electric displacement exceeds the moderate value

Kl.K.2iK2 t- wl){Q*-/»QyT}* electrostatic units, T being the capil-
27r(K2— KI)^

lary tension. For a conducting liquid instability ensues when the

K 2
square of the surface electric density exceeds — ~{pz— pi)gT}* elec-

2?r

trostatic units. In exciting a dielectric liquid by the approach of an
electrified rod it must often have been noticed that when the rod is
brought too near, the liquid spurts out vigorously in extremely fine
filaments or jets : the fineness of the filaments may be explained, in
part at any rate, after Lord Rayleigh (' Phil. Mag.,' 1882, " Theory of
Sound," § 364), without assuming an escape of electricity into the
liquid, as arising from the circumstance that it is only narrow crispa-
tions of the surface, and not extensive deformations, that become
unstable.

The opportunity is taken to correct other errata in the memoir,
' Phil. Trans.,' A, 1897, as follows :—

page 252, line 15, read Sir for 47r.

„ 253, „ 18, the factor c2 is omitted.
, 297, 4, dele m.

Proceedings and List oj Papers read. 373

June 9, 1898.

The Annual Meeting for the Election of Fellows was held this day.
The LORD LISTER, F.R.C.S., D.C.L.., President, in the Chair.

The Statutes relating to the election of Fellows having been read,
Professor Bonney and Mr. R. H. Scott were, with the consent of the
Society, nominated Scrutators to assist the Secretaries in the examina-
tion of the balloting lists.

The votes of the Fellows present were collected, and the following
Candidates were declared duly elected into the Society : —

Baker, Henry Frederick, M.A. j Preston, Professor Thomas, M.A.

Brown, Professor Ernest William.
Buchan, Dr. Alexander, M.A.
Harmer, Sidney Frederic, M.A.
Lister, Arthur, F.L.S.
McMahon, Lieutenant - General

Charles Alexander.
Osier, Professor William, M.D.
Parsons, Hon. Charles A., M.A.

Reid, Professor Edward Way-
mouth, M.B.

Scott, Alexander, M.A.

Seward, Albert Charles, M.A.

Shenstone, William Ashwell,
F.I.C.

Taylor, Henry Martyn.

Wimshurst, James.

Thanks were given to the Scrutators.

June 9, 1898.
The LORD LISTER, F.R.C.S., D.C.L., President, in the Chair.

Professor W. Haswell (elected, 1897) and Professor Amagat
(elected a Foreign Member, 1897) were admitted into the Society.

The following Papers were read : —

I. " On a New Constituent of Atmospheric Air." By Professor
W. RAMSAY, F.R.S., and MORRIS W. TRAVERS.

II. " On the Position of Argon, Helium, and Krypton in the
Scheme of Elements." By Sir WILLIAM CROOKES, F.R.S.

III. " Experimental Investigations on the Oscillations of Balances."
By D. MENDELE"EFF, For. Mem. R.S.

IV. " Experiments on Aneroid Barometers at Kew Observatory
and their Discussion." By Dr. C. CHREE, F.R.S.

VOL. LXIIi. 2 F

374 Mr. E. Edser. An Extension of

V. " The Nature of the Antagonism between Toxins and Anti-
toxins." By Dr. C. J. MARTIN and Dr. T. CHERRY. Com-
municated by Dr. HALLIBURTON, F.R.S.

VI. " Some Differences in the Behaviour of Real Fluids from
that of the Mathematical Perfect Fluid." By A. MALLOCK.
Communicated by Lord EAYLEIGH, F.R.S.

VII. " On the Heat dissipated by a Platinum Surface afc High
Temperatures." By J. E. PETAVET. Communicated by
LORD RAYLEIGH, F.R.S.

" An Extension of Maxwell's Electro-magnetic Theory of Light
to include Dispersion, Metallic Reflection, and allied Phe-
nomena." By EDWIN EDSER, A.R.C.S. Communicated
by Captain W. DE W. ABNEY, C.B., F.R.S. Received
February 18,— Read March 10, 1898.

The Electro-magnetic Theory of Light, as left by Maxwell, gave no
explanation of dispersion, and led to conclusions in some respects
inconsistent with the results of experiments on metallic reflection.
There seems to be little doubt as to the general direction in which it
would be necessary to modify that theory in order to give a satis-
factory account of these phenomena. Electrical conduction has been
considered by many to be inseparably connected with the motion of
charged atoms, whilst the properties of a dielectric have been found
to admit of an explanation on somewhat similar lines ; consequently
it would appear necessary, where fluctuations in the electric field of
frequencies as great as those of light are concerned, to expressly
formulate the reactions of the atoms or molecules composing the
medium through which the disturbances are propagated. The
mechanical theories of light, when modified in a similar manner, have
been found capable of giving a more or less comprehensive account of
dispersion and metallic reflection; and it would appear that the
assumptions necessitated in the present case are at least as admissible
as those which have been made elsewhere. No doubt a theory with
any pretension to finality must include a satisfactory account of the
nature of the luminiferous ether and of electricity, perhaps even of
the ultimate constitution of atoms ; and Mr. Larmor's investigations
show how far we can even now go in this direction. On the other
hand, a less comprehensive theory, depending only on the known laws
of electrical actions, may prove not without value, if, whilst explaining
the observed phenomena, it enables us to form a clear mental picture
of the processes involved.

Maxwell's Electro-magnetic Theory of Liylit. 375

In what follows, I have endeavoured to extend Maxwell's theory so
as to include dispersion and metallic reflection. The initial assump-
tion that both conducting and dielectric media consist of molecules,
each comprising (in the simplest case) two oppositely charged atoms,
is essentially that made by Helmholtz in his paper on the " Electro-
magnetic Theory of Dispersion."* The methods I have employed are
however different, and my final results, though bearing a general
resemblance to those obtained by HelmhoUz, differ from them in some
important particulars, besides being simpler and more directly related
to the results of investigations on other theories of the nature of light.
But besides the gain in simplicity and consequent physical definiteness,
I have had other reasons for not following Helmholtz's method. The
utility of employing the principle of least action in this case may be
questioned, since the only difficulty appears to lie in formulating the
reactions due to the charged atoms, and the nature of these reactions
is implied in the energy equations assumed. Moreover, the energy
equations obtained by Helmholtz are themselves open to criticism,
and some of the results obtained do not reduce to Maxwell's equations
when the terms involving the polarization of the dielectric are equated
to zero.f

2. This paper contains (I) a simple explanation of the fundamental
phenomena observed in connection with a state of steady electrical
strain in a dielectric ; (2) a consideration of the law of propagation
of electrical disturbances in a polarizable medium ; equations are
obtained which explain dispersion, both ordinary and anomalous ; (3)
and a consideration of metallic reflection, especially in connection
with Kundt's experiments on the velocity of light in metals.

State of Steady Electrical Strain in a Dielectric.

3. It is here sought to explain Faraday's discovery, that the intro-
duction of a material dielectric between the plates of a charged
condenser, diminishes the potential difference between the plates.

* H. von Helmholtz, 'Wied. Ann.,' 1893, vol. 48, pp. 389-405, 723—725.
Translated by Dr. Howard in the 'Electrician,' vol. 37, pp. 404 — 408.

t Helmholtz's Theory of Dispersion has been criticised by Kieff (' Wied. Ann.,'
1895, vol. 55, pp. 82—94) and Heaviside ('Electrician,' vol. 37, Aug. 7, 1896). In
addition it would appear that the employment of a term expressing the dissipation
of energy (other than Eayleigh's " dissipation function ") is inadmissible in the
principle of least action (Larmor, * Brit. Assoc. .Report,' " On the Action of Mag-
netism on Light," 1893 (Nottingham)). The final equations obtained by Helmholtz,
when the terms relating to the polarization of the medium are equated to zero, are
of the nature

B = curl E and — 4?rD = curl H,

where B, E, D, and H represent the (vector) magnetic induction, electromotive
intensity, displacement, and magnetic force respectively. They differ in sign from
Maxwell's equations.

2 F 2

376 Mr. E. Edser. An Extension of

Let us consider a dielectric medium, other than the ether, to be
composed of molecules each comprising, in the simplest case, two
oppositelj charged atoms at a definite distance apart. The volume
actually contained by the atoms is provisionally assumed to be small
in comparison with the volume of the interatomic spaces.

In what follows the" term axis of a molecule will be applied to the
vector distance between a negative and its associated positive atom.
In an isotropic medium the axes of the various molecules will, in the
absence of electrical strain, be inclined indifferently in all directions,
so that any element of volume will have no resultant electric moment.
If now a difference of potential be established between any two
parallel planes in the medium, the positive atoms will all move toward
points of lower, and the negative atoms toward points of higher
potential. As a result each element of volume will now possess a
resultant electric moment. Also, if we define a molecular electric
moment as the product of the atomic charge (taken as positive) into
the vector distance between a negative and its associated positive
atom, the resultant electric moment due to a strained element of
volume containing a number of molecules, will coincide in direction
with the direction of fall of potential.

In the unstrained medium we may represent the several moments
of the molecules contained in an element of volume by lines radiating
uniformly from a point, and ending on the surface of a sphere.*

To find the electric moment of an element of the strained medium,
it is only necessary to determine the sum of the alterations of the
component molecular moments in the direction of the fall of potential.

4. Let P be the electromotive intensity at a point in the dielectric,
and let q be the atomic charge, the distance between two associated
atoms being I. Then a molecule whose axis makes an angle 6 with
the direction of fall of potential, will be subjected to a couple
Pql sin 0 tending to decrease & and each atom will be subjected to a
force Pq cos 9 tending to increase I. Assuming that the forces of
restitution called into play by the displacement of the atoms are in
both cases proportional to the linear displacements, we shall have

1 0 = KxP2 sin 0, ^ = K2P2 cos 0,

where 0 indicates the (infinitesimal) molecular rotation, and JAZ is
the linear displacement of either atom in a line with the axis of the
molecule.

The increase of the component molecular moment in the direction of
the fall of potential due to these strains, will be

gZ0 sin 0 + gAZ cos 9.
* Maxwell's ' Electricity and Magnetism,' vol. 2, § 443.

Maxwell's Electro-magnetic Theory of Light. 377

Substituting for 0 and A? this expression becomes
2KlP2 sin2<9 + 2 K2P8 cos20.

Also, if dv — the volume of the element of the dielectric, and if there
are n molecules per unit volume, the number of molecules whose axes
are inclined at angles between 9 and 9 + d9 will be

ndv .

sin o . d9.

Hence the resultant moment of the element dv of the strained
medium will be

r f ' r77 i

ndvPq* < Ki sin30 dO + K2 cos20 sin 9 de \

^ Jn •*

(1),
if M = W22(|K14-1K2) (2).

The electro-motive intensity, parallel to the direction of the fall
of potential, due to this element of the strained medium, at a point
distant r from it in a direction making an angle 9 with the direction
of the resultant moment, will be

™, (1-8008*0)

— PM.dv » •

v

Taking the point at which we wish to determine the electromotive
intensity as origin, and the axis of x parallel to the direction of fall
of potential, we shall have for the electromotive intensity due to a
slab of the strained dielectric, perpendicular to x and at a distance x
from the origin (if dx = the thickness of the slab, and h = r sin 9)

The only slab of the dielectric which contributes anything to the
electro-motive intensity at the origin is that lying between the
planes at — \dx and +^dx. The electro-motive intensity due to this
will be

7^w= "4srpM-

2 / /

Hence if D be the displacement other than that produced by the
polarization of the medium

P = 47rD— 47rMP
.*. P(l + 47rM) = 4?rD (3).

378 Mr. E. Eclser. An Extension of

Hence (l-f-47rM) is the value of the specific inductive capacity
measured in the electro-static system. In the electro-magnetic
system (3) must be written

where K is the dielectric constant of the ether.

5. A few remarks may be made in connection with the assumptions
made in the course of the above argument. An objection might be
raised to the supposition that two oppositely charged atoms could
remain in equilibrium at a definite distance apart. To this it may be
replied that the form of the . argument does not necessitate the
assumption that electrical forces are the only forces acting ; and
even if these were the only forces, it would be possible to account for
the atomic separation by supposing both atoms to be revolving about
their common centre of gravity.

If the atoms are considered to be small conducting spheres, and if
the volume actually occupied by the atoms is a large fraction of the
volume occupied by the dielectric, a correction on the lines of the
Mosotti-Clausius dielectric theory would become necessary. On the
other hand, if electrical conductivity is inseparably connected
with the motion of charged atoms, it would appear to be wrong to
consider the atoms themselves to be conductors.

If finite motions of the atoms were necessary to explain the
properties of a dielectric, a treatment of the problem similar to that
used by Weber, in his molecular theory of magnetism would be
necessitated. It may, however, easily be shown that infinitesimal
atomic displacements will account for the observed phenomena. Take
the case of two plane and parallel charged condenser plates. Let P be
the electro- motive intensity at a point between the plates when
charged in vacuo. If now, the charge remaining the same, pure water
is introduced between the plates, the electro-motive intensity will
become

4 irnqt)

K

if c = the average molecular displacement. Taking Cohn and Arons's
value for the specific inductive capacity of water, viz., 76, we havo

Let P = 100 volts. Then, since nq will equal the total charge
carried by the oxygen in 1 gram of water, we shall have

Maxwell's Electro-magnetic Theory of Light. 379

Hence the magnitude of the displacement, necessary to account
for the dielectric properties of a medium possessing the highest
specific inductive capacity known, is small, even when compared with
molecular magnitudes.

In determining the force acting 011 a charged atom within a
polarised dielectric, a difficulty arises somewhat similar to that expe-
rienced when the force on a magnetic molecule within a magnet is
sought.* The above method, I think, is not open to very serious
objection, and as the results obtained give a fair explanation of the
experimental facts, it may, perhaps, be tentatively adopted.

[Added May 10. — Mr. Larmorf gives P + f?rI as a first approxima-
tion to the value of the total electric field at a point within a polarized
dielectric, I denoting the intensity of electrification, or the electric
moment of the polarized medium per unit volume. As a consequence,
the Lorenz refraction equivalent is obtained, whilst the relation
(/i2— I)oo density follows from the reasoning employed in the present
paper. Further, a dispersion formula, differing somewhat from that
of Ketteler, is obtained by Mr. Larmor ; it would be interesting to
know with what degree of accuracy this formula is capable of repre-
senting the dispersion of transparent substances, as determined, for
instance, by Paschen and Bubeiis.J

The following somewhat simple argument is submitted in justifica-
tion of the assumption made above, that the field in a polarized
medium is equal to P.

Let the space between two plane and parallel condenser plates,
separated by a distance small in comparison with the area of either,
be filled with an isotropic polarizable medium, such as that assumed
above. The molecules are assumed to be in a state of equilibrium
amongst themselves when the two plates are at the same potential ;
consequently the potential energy W, due to the small rotations
0i, 02, 03, .... of the several molecules composing the medium maybe
represented by a quadratic function of the form

W =

A similar expression would obtain for the potential energy due to
the separation of the atoms within the molecules. The conditions
connecting the various coefficients are such that W is essentially
positive.

Considering for a moment only the molecular rotations, the force

* See Maxwell's ' Electricity,' vol. 1, p. 83, 1892 edition, footnote by Professor
J. J. Thomson.

f " A Dynamical Theory of the Electric and Luminiferous Medium, Part III,"
' Phil. Trans.,' A, vol. 190 (1897), § 18—21, pp. 232—236.

J Paschen, 'Wied. Ann.,' 1894, vol. 53, pp. 812—822; Kubens, ' Wied. Ann.,'
1895, vol. 54, pp. 476—485.

380 Mr. E. Edser. An Extension of

of restitution Fl called into play by the rotation fa will be equal
to dwjdhu where hi = -fa. Thus

The first term represents the force acting on an atom of the mole-
cule whose subscript is unity, when that molecule alone is displaced ;
the succeeding terms represent the force on the same atom, due to
the displacement of the remaining molecules throughout the medium.
A number of relations, similar to those given by Maxwell,* may be
deduced, but require no further notice here.

Let the conducting surfaces, each of area A, and separated by a
distance D, be charged by means of a battery to a constant potential
difference V. Let 0t, fa, fa. . . . be the molecular rotations produced.
If, when electrical equilibrium has been acquired, the molecular
rotations are further increased by dfa, d02, dfa. . . . , the increment of
electrical energy supplied by the battery will be equal to A . Vdl.
Further, writing V = PD, we obtain for this energy E, the equivalent
expressions

E = AD . Pdl! = P27(/ sin 0 dfa

where 2 indicates summation for the whole of the molecules through-
out the medium. Since, on releasing the molecules, the above amount
of electrical energy will be returned to the battery (the resistance of
leads being considered negligible), we must have

sin 0n dfa = 22d0» {a»0» + bnlfa + bnzfa + ----
Since the dfa's are arbitrary,
Ply sin. 6i dfa =

Hence F! = Pq sin 0i. Consequently the couple acting on a polar-
ized molecule will be equal to that due to a field P. Further, if P
= 4*7rff, it is easily seen that

2

— a^ = 4 TTff . q sin 0lt

Similar reasoning will apply when the inter-atomic separations
are considered. Consequently the total electrical field contributed
by the molecules throughout the medium is numerically equal to
4jrli, and acts in a direction opposed to P, the result formerly
obtained.]

* ' Treatise,' vol. 1, chap. 3, §§ 87, 88.

Maxwell9 8 Electro-magnetic Theory of Light.

381

Propagation of Electrical Disturbances.

6. Only a very slight modification of Maxwell's equations appears
to be necessary in order to determine the law governing the pro-
pagation of electrical disturbances in a polarized medium such as
that previously considered.

Let P, Q, R be the components of the electromotive intensity at a
point, F, Gr, H being the components of the vector potential there.
The electromotive intensity due to the displacement of the atoms
may, if the velocity of the atoms is small compared with the velocity
of light, be derived from a potential y^.

Hence

P= — 77 —-

at

_
dt dy

dt d><

Here it must be remembered that ^ will be a function of t.
We may define the vector potential so that

(5).

In that case

dF dG dR

T~ ~**~~T +^T~ = 0.
ax ay dz

<__

dx ^d T <fa

(6),

since any element of volume, if taken so as to comprise a sufficient
number of molecules, will contain as many positively charged as
negatively charged atoms.

Let a, 6, c represent the components of magnetic induction.
Then

_^H__^G
a~ dy dz '

with similar equations for b and c.
Hence, from (5),

da __ dQ_dR^\
dt ~ dz Ty |

^____

dt ~~ dx ds

dc
dt

dy

382

Mr. E. Edser. An Extension of

These equations are identical with those used by Professor J. ,] .
Thomson in his developments of Maxwell's theory.* They express
the law that however the electromotive intensity at any place may
be modified by the presence of the charged atoms, its line integral
round a closed curve will be equal to the rate of decrease of the
induction through the curve.

These equations differ from those obtained by Helniholtz.f
7. If a, fi, 7 are the components of the magnetic force, and «, r , w
those of the electric current, then

dv dfi •}

= -±—

ay dz

da, d*t I

4 TTV = - -- -7-

dz dx

doc.
—
ay

,
(8),

The current component u will include the total displacement
current in the direction of x, i.e., not only that due to the variation
of the induced electromotive intensity, but that also due to the
continual alteration in position of the atoms throughout the medium.
This will be equal to Kpi'4ar. Mr. HeavisideJ has further shown that
in order to close the displacement current produced by a charge 5,
moving with a velocity vit we must add at the position occupied by </
a current element such that its moment is qi\. Hence in the present

case the value of u will be given by — +2^%, where ^qvx indi-

4?r

cates the summation, for unit volume, of the products of the several
charges into their respective velocities parallel to the x axis.
Hence (8) may be written

dy dz

doc. </7
dz dx

(9).

* l Recent Researches in Electricity and Magnetism,' p. 252.

f The equations obtained by Helmholtz, besides diifering in sign from the corre-
sponding equations of Maxwell, would lead to the conclusion that the displace-
ment produced by the charged atoms is circuital.

J O. Heariside, * Phil. Mag.,' April, 1889. p. 324 ; see also J. J. Thomson, ' Phil.
Mng.,' April, 1881, July, 1889 ; also ' Recent Researches,' p. 19.

Maxwell's Electro-magnetic Theory of Light. 383

For a medium whose permeability is unity, we shall finally obtain,
-eliminating a, /3, 7 between (9) and (7),

8. Consider the propagation, parallel to the axis of z, of a train of
plane waves, the electrical disturbances being parallel to the x axis.
(10) reduces to

<f-P d'P d

It only remains to express the last term on the right-hand side in
terms of P.

Consider a molecule whose axis, as previously defined, makes an
-angle 0 with the axis of ST. For simplicity, suppose both atoms com-
prised in the molecule to have equal masses. It has been shown by
Mr. Heaviside and Professor J. J. Thomson,* that a charged sphere
moving with a velocity small in comparison with the velocity of

light, has an apparent mass greater than its true mass by — — ,

3 a

where q is the charge, and a is the radius of the sphere. When
other charged spheres are moving in the neighbourhood, a further
correction might be necessary. Let, then, m represent the apparent
mass of either atom in the molecule. The differential equation for
the rotational displacement of the molecule will be of the form

Here 7 is the molecular viscosity, the other letters having the
same meaning as in § 4.

If 7 is so small that the time of free rotational vibration is not
appreciably affected thereby, this equation may be written

fZ20 7 (70 , 4?r2 , 2gP

-J&+ ---£ + — ^ -- 7 sm0 = 0,
dt2 m at TI ml

where r^ = 27rv/(Kim) = time occupied by a complete rotational
vibration.

* O. Heaviside, ' Phil. Mag.,' April, 1889 ; ' Electrical Papers,' p. 505 ; J. J.
Thomson, ' Recent Researches,' p. 21.

384 Mr. E. Edser. An Extension of

As we are here concerned only with forced vibrations, and there-
fore the particular integral of the above equation alone is required,
we may write the solution to the above equation

mi -lp> <12>'

where Dx 1 indicates the inverse of the operator D1? and

T) — I *_ I

dt~ m dt Ti2

Similarly the equation to the atomic vibration along the axis of
the molecule will be of the form

The particular integral of this equation may be written

(Dr'P). (13),

where Do"1 is the inverse of the operator D2, and

D2 ~'*4.xA+ IT

rf^m #~ T./

T2 = 27Tv/(K2m).

It has been assumed that the coefficient of viscosity is the same
for both kinds of vibration.

Now the component of 2pvx contributed by the two atoms com-
posing the molecule under consideration will obviously be obtained
by differentiating with regard to time, the expression

Eliminating 0 and AZ by the aid of (12) and (13), this expressioi
becomes

^21 {sin2 0 (Dr1?) + cos2 0 (Da-'P) }.

1Yl>

Hence employing precisely similar reasoning to that used in § 4,
we finally determine that 5Zqvx will be obtained* by differentiating
with regard to time the expression

* [Added June 13. — The possible presence of free ions, considered merely as
isolated charged atoms, is not considered capable of materially affecting the dis-
persion formula for light waves. This would follow no less from theoretical con-
siderations than from sucli facts as that the absorption of dilute sulphuric acid is
not appreciably different from that of pure water. For very long electrical waves
the case would be different.]

Maxwell's Electro-magnetic Theory of Light. 385

2£ { (Dr'P) Tsin3^ dG+ (D2-'P) I cos2 0 sin 0 dO \
m <• J J J

9. Substituting this value in (11), we obtain

Performing the operation denoted by T)iD2 on the whole expres
sion, we get

Let P = Aievrv~ (15).

Then since DXP = ( ^ — i — — H ) P, with a similar expression

\ T mr T! /

for D2P, we obtain as the condition that (15) should be a solution
of (14)

4 2 \

5 ,+

27T<y 4>7T' 47T2 27T7 4 TT2

1)17 T2 T22 1UT T2

Also /c = — £, where V0 is the velocity of propagation of electrical

» 0

disturbances in vacuo. Substituting this and simplifying we obtain

_,_^ .i ±_, ir

.. (16).

2 — 22 °

Here u is the refractive index of the medium, and

m?r

For transparent media, 7 will be small, and the above equation
may be written

386 Mr. E. Edser. An Extension oj

Since both ct and c2 are directly proportional to n the number of
molecules per unit volume, it f ollows that in a medium which can be
compressed without appreciably altering TJ and TS we shall have

/r— -1 cc density.

When ju, is very nearly equal to unity, this may be written
JLI— 1 cc density,

which is Gladstone and Dale's well-known law.

Further, the refractive index for infinitely long waves is obtained
from the equation.

Ac =

_ 4.M
~KT

which is the value obtained for the specific inductive capacity of a
medium by (4).

Further, we may re-write (15),

Also if Vo^ = AJ, , V0T2 = X2, VOT = X,

this may be written

~"\

where c' = Ci^2 , c" = c2T23.

This is Ketteler's dispersion formula, which he has shown is capable
of representing the optical properties of a large number of substances
over a great range of values of X. It is the same as that obtained by
Mr. Glazebrook in his paper " On the Extension of Lord Kelvin's
Contractile j^Bther to include Dispersion, &c.,"* and by a slight
alteration in form reduces to Lord Kelvin's dispersion formula. f
As its properties have been fully discussed in the papers referred to,
nothing further need be said about it here.

The molecular constitution considered above is, of course, the
simplest imaginable. With a more complicatedj-rnolecute, since each

* E. T. Glazebrook, ' Phil. Mag.,' December, 1888.
f Lord Kelvin, Baltimore Addresses, 188 i.

Maxwell's Electro-maynetic Theory of Light. 387

atom may have its own vibration periods, a much more complicated
dispersion formula might be anticipated. In this connection the
fact that the absorption spectra of the permanganates of potassium,
sodium, lithium &c., are identical* appears to be very suggestive.

For infinitely quick vibrations /t becomes equal to unity. If the
radiations discovered by Rontgen are ultimately proved to be due to
transverse periodic disturbances of the ether, of very short wave
length, this would explain why no refraction of these radiations is
produced by material media.

10. The application of (16) to explain the optical properties of crys-
tals and metals is obvious. In a crystal the co-efficients of the terms
involving ^ and T2 will depend on the direction of vibration, which
will result in 11 varying with the direction of propagation of light.
Further, in accordance with a well-known mechanical principle 7
must be taken into account, when T is nearly equal to TI or T3. In
this case (16) may be reduced to the form

yti2 = R2 (cos 2a + 1 sin 2a) .

Sin 2a is essentially positive, whilst cos 2a may be either positive or
negative. This is generally considered sufficient to explain the
optical properties of metals, and of the quasi-metallic aniline dyes
when in a solid state.

Kundt has pointed out that the velocity of red light in a metal is
proportional to the electrical conductivity of that metal. A sug-
gestive relation in this connection may be derived from (16).

Let 2a = TT— 2x . Experiments with metallic films and prisms
alike show that 2a' is small for the majority of metals. We may
write

f.i = /R(cosa' — /sin a').

The real part of the refractive index is therefore equal to
R sin a.

(16) may also be written in the form

Then, since siii2a' = tan 2 a' = — j£-~ ,

R sin a' = — jLAli , approximately.
2\/(— /(T))

Mr. Tomlinsonf has shown that in a number of cases the' molecular X
viscosities of metals are in the same order of magnitude as their

* ' Ostwald, 'Zeits. Phys. Chem.,' TO!. 9, p. 579.
f II. Tomlinson, 'Phil. Trans.,' 1883, p. 168.

388 Extension of Maxwell's Electro-magnetic Theory of Light.

electrical resistances. Hence if 7 in the present instance might be
identified with the molecular viscosity as determined by Mr. Tom-
linson, a connection similar to that derived experimentally by Knndt
would be established. Calculating by the above approximate
process the real parb of the refractive index from Drude's experi-
mental data, a fair agreement, as to order of magnitude, is found
with the same quantity when calculated accurately. The agreement
is not, however, close enough to explain the very accurate propor-
tionality between the velocity of light in a metal and the conduc-
tivity of the latter which Kundt's figures imply. Since, however,
Pfliiger has shown that the temperature co-efficients of the velocities
of light and the conductivities are not of the same order of magni-
tude, the process employed above may perhaps represent the nature
of the physical connection between the two quantities to a sufficient
degree of approximation.

11. [Added May 10. — Another relation of some importance can be
readily obtained from (17). It is a well-established experimental
law, often made the basis of exact chemical determinations, that the
co- efficient of absorption of a solution of an absorbent substance
in a transparent liquid is proportional to the number of molecules
of the absorbent present in unit volume of the solution. A simple
extension of the reasoning formerly used will give for the square of
the refraction index of such a mixture the value

Cl«l , „ C&Z
.-1

TO" 27rmr

(18),

where Ci nx, T\ are constants for the transparent medium, whilst
c2, w2, T2, w, and 7 refer to properties previously defined of the
dissolved absorbent substance. Further we may write

ft = A + m2B,

where A, in dilute solutions, is nearly independent of the amount of
colouring matter present, whilst

27T7?IT

4?r2w T

for a substance possessing only one absorption band, and is to a first
approximation independent of the properties of the solvent.

Then /*~ = R2(cos 2z + 1 sin 2z) = A + m2B.

Photographic Investigation of Spectra of Chlorophyll, $c. 389

When a is small, sin 2a = tan 2x = — r— ,

A.

R2 = v/(A2-f WB2) = A, approximately.

-IT ft-aB

Hence p = \/ A -f t -— rr- •

*/ A.

Here nj&f»/h. is the coefficient of absorption of the solution, and is
proportional to n2, the number of molecules of the absorbent substance
present per unit volume. Since it is essential that (19) should
possess a well-marked maximum value for a certain wave-length (that
of the light absorbed), additional evidence is obtained in support of
the introduction of a viscous term into the equations to the atomic
vibrations.

The equation for the square of the refractive index of a substance
like crystallized copper sulphate, which possesses marked selective
absorption without exhibiting selective reflection to any extent,
might be represented by an equation of the form of (18) ; r2, &c.,
now referring to the conditions of motion of a particular atom, the
motions of the remaining atoms giving rise to the terms involving
T,, Ac.

" A Photographic Investigation of the Absorption Spectra of
Chlorophyll and its Derivatives in the Violet and Ultra-
violet Region of the Spectrum." By C. A. ScHUNCK.
Communicated by Dr. E. SCHUNCK, F.R.S. Received
March 17,— Read March 24, 1898.

[PLATES 3, 4, 5.]

As is well known from the investigations of Soret,* Gamgee,f and
others, haemoglobin and its coloured derivatives show a character-
istic absorption band lying between the lines Gr and M of the solar
spectrum. The band has been shown to vary in position between
narrow limits ; in some derivatives it is nearer the red, and in others
nearer the violet, end of the spectrum, and is of all the blood absorp-
tion bands the most stable.

The very near relationship that has been shown <o exist by Schnnck
and MarchlewskiJ between phylloporpbyrin (a chlorophyll deriva-
tive) and haematoporphyrin (a haemoglobin derivative), and the
remarkable resemblance of their absorption spectra — one may almost

* ' Arch, des Sciences Phys. et Nat.,' vol. 61, p. 322 ; vol. 66, p. 429.
f 'Arch, des Sciences Phys. et Nat.,' Dec., 1895.
J ' Roy. Soc. Proc.,' vol. 59, p. 233.
VOL. LXIH. 2 G

390 Mr. C. A. Sclmnck. A Photographic Investigation

say they are identical — led Tschirch to the belief that there must
also exist a like resemblance in the violet and ultra-violet region of
the spectrum. Tschirch in his investigations* shows this to be the
case, and finds a band in phylloporphyrin (termed by him phyllo-
purpuric acid) in the same position as the band observed in haema-
toporphyrin, and this ' corresponding to the characteristic band
which has been shown to exist in the blood colouring matter
derivatives. But further on I will show that this particular
resemblance in these two derivatives is only partly correct, the
band in the phylloporphyrin I examined being double, though
occupying the same position as the single one of hagmatoporphyrin.

Tschirch (in the same memoir) makes the further important dis-
covery that this band is not confined to phylloporphyrin alone, but
that it is distinctive of the chlorophyll derivatives generally, and
that it occupies (in the derivatives he observed) the same position
(varying between narrow limits) as that shown to exist in the blood
derivatives, and, like the blood band, the new chlorophyll band
shows much greater stability than any of the other bands, no
matter what chemical changes the derivatives have undergone.

The chlorophyll derivatives investigated by Tschirch are phyllo-
purpuric acid (impure phylloporphyrin), phyllocyanic acid (phyllo-
cyanin), and its zinc, copper, and iron compounds, in all of which
he finds a single band corresponding in position with the band in
the haemoglobin derivatives, in the zinc and copper compounds
shifted slightly towards the red end of the spectrum, and he also
finds it indicated iu the living leaf, whilst in chrysophyll and
carotin he observes three bands situated between the solar lines
P and H and in identical positions. By the kind permission of Dr.
B. Schunck I have had access to his beautiful collection of chloro-
phyll derivatives, and have b*>en able to examine spectroscopically
in the pure state solutions of chrysophyll, carotin, chlorophyll, phyll-
oxanthin, phyllocyanin and its zinc and copper compounds, alka-
chlorophyll, phyllotaonin, ethyl-phyllotaonin, and phylloporphyrin,
and a specimen of hcematoporphyrin kindly sent me by Dr. L. March-
lewski. In all there appears a characteristic absorption between
the solar lines F and M, which confirms the statement of Tschirch
that the chlorophyll derivatives, like the haemoglobin derivatives,
give a very characteristic absorption in this region of the spectrum,
and considering the very near relationship which exists between
phylloporphyrin and hasmatoporphyrin, is further evidence of the
supposition that there exists something in common to both chloro-
phyll and haemoglobin, the two great colouring matters of biological
importance in the vegetable and animal kingdoms.

* * Berichte der Deutschen Botaniachen Gresellscliaft,' vol. 14, Part 2, p. 76,
1896.

of the Absorption Spectra of Chlorophyll, $c. 391

As I have been able to examine many more derivatives than the
former investigator, and as the results of my observations differ
from his, inasmuch that I find only some of the derivatives are
characterised by the single band, whilst in others two are apparent,
and in chlorophyll itself and chrysophyll three, and also that my
method of procedure differs from his, it will perhaps be of interest to
give the results of my experiments as compared with his.

Method of Procedure.

The spectroscope was a single prism one of Iceland spar, which
just divided the sodium lines. The lenses were of quartz, the foeal
length of the collimator lens being 12'5 inches, and that of the
camera lens 42 inches. The dark slide which held the plate was
movable at fixed intervals, so that seven exposures could be taken on
the one plate. The solutions were examined in a glass cell with
parallel quartz faces, placed in front of the slit, the whole apparatus
being set up for me by Mr. A. Hilger, of London. The source of
light used was a Welsbach incandescent mantle of sixty-candle
power, no chimney being used, placed 8 inches distant from the slit.
For reference lines a hydrogen vacuum tube was used, from which
the lines F, S', L, and H' were obtained, and the violet potassium line
K/s was at the same time thrown in by volatilising a little of the salt
in a Bunsen burner in front of the slit. The plate used was Messrs.
Cadett and Neal's " lightning," pyrosoda being adopted as the
developer. The exposure given in each case was half an hour, which
was found to be the most advantageous after various trials of different
times of exposure had been made. Under these conditions the photo-
graphs extended distinctly as far as the solar line Q. On each plate
a spectrum of the source of light used was thrown in for a compari-
son with the light absorbed by the solutions of the different deriva-
tives. In every case the solutions had to be excessively diluted
before the characteristic absorption became apparent on the photo-
graphic plate, so dilute that, with the exception of chrysophyll, caro-
tin, and chlorophyll, only a faint indication of colour was visible in
the solutions to the eye by transmitted light, and of the bands in the
visible region of the spectrum, only the first, the characteristic one
in the red, was visible, and that in the majority of cases only faint.
In the case of the hydrochloric acid compounds of phjlloporphyrin
and hsematoporphyrin one might say the solutions were colourless,
and yet these two derivatives give the single band more pronounced
and better defined than any of the others. As a very slight differ-
ence in the strength of the solutions gave an appreciable difference
in the resulting absorption spectra, three solutions of slightly varying
strengths were photographed of each derivative, and the most charac-

2 G 2

392 Mr. C. A. Schunck. A Photographic Investigation

teristic of each were then selected and photographed together as
depicted in the plates. In no case on dilation were any further
bands observable, and in all I find this particular distinctive absorp-
tion situated between the lines F and L in chrysophyll, carotin, and
chlorophyll, and in the other derivatives between the lines Gr and L,
the mean position of the bands being situated at the K/a line, varying
sometimes slightly towards red and in others towards the violet.
The main difference in my procedure to that of Tschirch is that I
have made use of artificial light in the place of direct sunlight. By
this means I have been able to reproduce the bands as regards their
definition and their relative intensity in a far more distinct manner,
and though my photos, do not extend so far as his, mine going to Q
and his to S, yet as the cha.racteristic absorption does not extend
further than M this is not of great consequence.

Chlorophyll, Chrysophyll and Carotin.

The chlorophyll solution was prepared in the usual way. Fresh
leaves were extracted with boiling alcohol, and the solution filtered
off from the fatty deposit which usually forms on standing. When
the solution is diluted so that in the normal chlorophyll spectrum of
four bands only the characteristic one in the red is visible when
received by the spectroscope, and a photograph is now taken, three
bands are found lying between the lines F and K/s (Plate 3, figs.
1 and 2). The first two bands are the bands usually numbered
5 and 6 of the normal chlorophyll spectrum, and can be seen on
dilution by the eye when sunlight is used, and the first one, 5, when
artificial light is used. But the third band in the violet, having its
centre situated about the line h, has not, I believe, been observed
before. In weaker solutions still, one only gets a general absorption
in the ultra-violet, no further bands being discernible. As is well
known, chlorophyll solutions prepared from the leaves of different
plants vary slightly in their absorption spectra, which depends
upon the amount of acid present in the leaf. In the spectrum of
the purest chlorophyll solutions, the fourth band situated about the
line E is extremely faint ; the purer the solution the fainter it it
but where the least trace of an acid is present this band appeal
darker than the third, situated between the lines D and E, and 01
the solutions standing becomes darker still, while the third become
fainter, and has moved further away from the red end. If, how-
ever, a chlorophyll solution be exposed to the action of dim
sunlight for a few hours until the colour has become brown, or if
few drops of a strong acid, as hydrochloric, be added, and the solutioi
be allowed to stand for a few days, a further change in the spectral
takes place, by the formation of a fifth band situated between the lin<

of t lie Absorption Spectra of Chlorophyll ', $r. 393

E and F. According to the investigations of Schunck and March -
lewski,* these changes may be explained by the supposition that
phylloxanthin is formed in the first case, and phyllocyanin in the
second. These changes take place in a greater or less degree in
every chlorophyll solution on standing, according to the amount an.d
strength of acid present originally.

I have fonnd in all the various chlorophyll solutions I have
examined, even in those which from the commencement gave the
fourth band darker than the third, and those in which the same
change had taken place on standing, that no change had taken place
in the violet, the only change being that more and more of the
ultra-violet rays are absorbed. In the purest solution the total
obscuration started at the line N, while in others the total obscura-
tion commenced at the line H2. But in the case of a solution which
had been exposed to the action of direct sunlight and which showed
the fifth band, then the bands in the violet had disappeared alto-
gether, leaving only a general absorption in the ultra-violet. As
will be seen from Plate 5 (figs. 2 and 3), the second and third of
these violet bands are identical in position with the two bands found
in phylloxanthin, while the first corresponds in position to a new
sixth band I have found to exist in the spectrum of phyllocyanin
when the solution is examined in a more concentrated form than
usual, and which appears distinct but faint when photographed.

The chrysophyll was obtained by Schunck's methodf and
examined in an alcoholic solution ; the carotin crystals were
obtained from the carrot root by the process of Arnaud, and was
likewise examined in an alcoholic solution. In each three very
distinct characteristic bands were found, which agrees with the
statement of Tscliirch, but the bands from my photographs are not
in identical positions, those in the carotin being slightly shifted
towards the violet end.

Like Tschirch, I find that both these derivatives are very trans-
parent to the ultra-violet rays. From Plate 3 (figs. 2 and 3) it will be
seen that the three chrysophyll bands occupy intermediate positions
compared to the three chlorophyll bands, which seems to point to the
supposition that chrysophyll does not exist in chlorophyll solutions
as such, but under certain conditions only is formed by decomposi-
tion of a derivative,^ and then crystallises out, or that if it does
exist in the solutions it must be in a very small quantity, otherwise
the bands would overlap each other, and the result would be a total
obscuration, which I have only found to be the case in a chlorophyll
solution exposed to the action of direct sunlight.

* '• Boy. Soc. Proc.,' vol. 57, p. 321.
f ' Koy. Soc. Proc.,' vol. 44, p. 449.
% Hansen, ' Die Farbstoffe des Chlorophylls,' 1889, p. 58.

394 Mr. C. A. Schunck. A Photographic Investigation

Phylloxanthin, Phyllocyanin and its Compounds.

Phylloxanthin and phyllocyanin, the two leading chlorophyll
derivatives obtained by the action of hydrochloric acid (Schunck,
" Contributions to the Chemistry of Chlorophyll")* give in alcoholic
solutions in the violet region of the spectrum, in the former case two
bands, and in the latter one (Plate 5, figs. 3 and 4). As has already
been pointed out, the two phylloxanthin bands are identical in posi-
tion with the second and third of the chlorophyll ones in the violet,
the band in phyllocyanin being moved slightly towards the violet
end, this band being situated between the lines h and H2. In both
cases the solutions have to be exceedingly dilute before the bands
become visible on the photographic plate, the only band remaining
visible to the eye in the visible part of the spectrum being the first,
the characteristic one in the red, and that now only appears faint.
From the investigations of 8chunck,f phyllocyanin plays the part of
a weak base, and combines with strong acids, the compounds, how-
ever, being unstable and easily decomposed even by water, and, like
other bases, giving definite double compounds of great comparative
stability, into which metals and acids, especially organic acids, enter
as constituents.

I have examined the compounds formed by dissolving phyllocyanin
in anhydrous acetic acid, hydrochloric acid, and sulphuric acid, and
find a more pronounced band in each than even in the case of an
alcoholic solution of phyllocyanin, but in each compound the band
is shifted slightly towards the red end of the spectrum compared to
the band in phyllocyanin itself (Plate 4, figs. 1, 2, 3, and 4).

Of the compounds formed by phyllocyanin with metallic salts, the
one with zinc carbonate in alcohol, with zinc acetate in acetic acid,
and the one with cupric acetate in the same solvent were examined.
In each the characteristic absorption was noticeable in the same
region of the spectrum. In the zinc carbonate compound two very
distinct bands were found corresponding very nearly in position with
the two in phylloxanthin, the shifting being towards the violet end
(Plate 4, figs. 5 and 6), the zinc acetate compound, on the other hand,
gave only one band, corresponding in position with the band of the
anhydrous acetic acid compound of phyllocyanin (Plate 4, fig. 7),
whilst in the case of the cupric acetate compound two badly defined
dark bands were apparent, the division between the bands corre-
sponding about to the position of the phyllocyanin band (Plate 4,
fig. 8). In both these series of compounds, as in the case of phyll-
oxanthin and phyllocyanin, the solutions had to be very dilute before
the characteristic absorption became apparent on the photographic

* 'Boy. Soc. Proc.,' vol. 39, p. 348; TO!. 50, p. 306.
t * Roy. Soc. Proc.,' vol. 39, pp. 354 and 356.

Schunck. Roy. Soc. Proc., Vol. 63, Plate j.

Q P O N ML H2HiK£h GGi F

••

A.

D.

4.

5.

E,

Schunck.

A.

P o

Roy. Soc. Proc., Vol. 63, Plate 4.

N ML H2HiK«h GGi F

8.
D.

E.
9.

10

11.

Q P O N ML HaHiKflh

Schunck.
A,

B,
1.

2.

Q P O

Roy. Soc. Proc., Vol. 63, Plate 5.

N ML HaHiKflh GGi F

D.

6.
7.
8.

9.

10.
E,

Q P O N ML HaHiK^'h GGi

of the Absorption Spectra of Chlorophyll, fyc. 395

plate. Here the results of my experiments differ from those of
Tschirch, who found but one band in the zinc and copper compounds,
but the discrepancy may have arisen from the fact that he does
not state in his memoir what acid was in combination along with
the metal with phyllocyanin. That the zinc carbonate compound
of phyllocyanin should give two bands in the violet region corre-
sponding very nearly in position and relative intensity with the two
of phylloxanthin, and therefore, with the second and third violet
chlorophyll bands, is interesting from the fact that of all the
chlorophyll derivatives the spectrum of the phyllocyanin zinc car-
bonate in the visible region corresponds more closely than any of
the others with that of chlorophyll, and from the deductions arrived
at from this similarity by Schunck* as regards the functions of
chlorophyll as being a carrier of carbonic acid in the plant, just
as haemoglobin serves to convey oxygen in the animal economy.

Alkachlorophyll, Phyllotaonin, Ethyl-phyllotaonin, Phylloporphyrin.

In his " Contributions to the Chemistry of Chlorophyll " Schunck
has discovered that by the action of alkalis upon chlorophyll, the
above definite derivatives are produced in a crystalline forin.t
Alkachlorophyll, phyllotaonin, and ethyl-phyllotaonin all give the
single band in a pronounced and well- denned manner, corresponding
very nearly in position with the band in phyllocyanin, viz., at
about K/s, in phyllotaonin it being shifted slightly towards the
violet, and in the other two a trifle towards the red end of the
spectrum (Plate 5, figs. 6, 7, and 8). Alkachlorophyll also forms
a definite crystallised sodium salt. In an alcoholic solution the
band appears considerably shifted towards the red, but a watery
solution gives the band much obscured, in the same position as
the one in the alcoholic solution of alkachlorophyll itself (Plate 4,
figs. 9, 10, and 11).

Phylloporphyrin on the other hand gives a double band, intense and
fairly well defined, the less refrangible one having its centre situated,
at the K|3 line (Plate 5, fig. 9). Phylloporphyrin forms a compound
with acids, which has a spectrum in the visible region quite
distinct from the very characteristic one of phylloporphyrin itself,
which consists of seven bands, while the acid compounds only
show three bands. J On examining the hydrochloric acid compound
in the violet region, a corresponding change is also found in the
spectrum, and instead of the double band, a single very intense

* ' Annals of Botany,' vol. 3, pp. 65—120.

f 'Roy. Soc. Proc.,' vol. 39, p. 355; vol. 44, pp. 449—454; vol. 50, pp.
312—316 ; vol. 57, pp. 316—319.

J Schunck and Marchlewski, ' Koy. Soc. Proc./ vol. 57, p. 319.

396 Messrs. R. W. Foray th and R. J. Sowter.

one takes its place, situated between the other two (Plate 5,
fig. 10). This band is the most pronounced and the best defined
one in the whole series, and only becomes visible on the photo-
graphic plate in excessively dilute solutions, so dilute that one
might say the solution was colourless to the eye when viewed by
transmitted light.

Phylloporpfiyrin and Hcematoporphyrin.

On comparing the spectra of phylloporphyrin and haemato-
porphyrin in this region, and also those of their hydrochloric
acid compounds (Plate 3, figs. 6, 7, 8, and 9), it was found that
haematoporphyrin gave only a single band, but situated in the same
position as the double one of phylloporphyrin. On this point the
results of my experiments differ from those of Tschirch, who, as
stated above, found in both astw^Zeband occupying the same position.
In the hydrochloric compounds of hasmatoporphyrin, however, a
single band of the same pronounced character as that in phyllopor-
phyrin was found, the one in haBmatoporphyrin, as will be seen from
the figures, being slightly shifted towards the red end of the
spectrum, which is interesting from the fact that just in the same
way are the bands in the visible region of the spectrum of these
two compounds shifted, this constituting their only spectroscopic
difference.

In conclusion, my thanks are due to Dr. E. Schunck and Dr. L.
Marchlewski for the valuable assistance they have given me in
many details in connection with this investigation.

I hope in a further paper to investigate more particularly the
spectroscopic behaviour in the same region of the spectrum of the
yellow colouring matter accompanying chlorophyll in leaves and
allied colouring matters obtainable from other sources than the leaf,
for instance, carotin.

" On Photographic Evidence of the Objective Reality of Com-
bination Tones." By R. W. FORSYTE, A.R.C.S., and R. J.
SOWTER, A.R.C.S. Communicated by Professor RUCKER,
Sec.R.S. Received March 29,— Read May 5, 1898.

[PLATES 6, 7.]

In the following paper we propose to describe a series of photo-
graphs which prove the objective reality of difference and summation
tones. The work was suggested to us by Professor Riicker, and wehave
used the method of detecting these tones which has been described by
Riicker and Edser in the ' Philosophical Magazine ' for April, 1895.

The Objective Reality of Combination Tones. 397

The resonator they employed was a tuning fork. On to one prong
of the fork was fixed a mirror, which was made one of a system by
which Michelson's interference bands were produced. To the other
prong was attached a wooden square of larger area, but of the same
weight as the mirror. The fork was then compared with a Kouig
standard fork and its frequency adjusted to 64. The notes were
produced by a Helmholtz wind siren placed between a wooden
pyramidal tube and a large Konig resonator tuned to 64. The
narrow end of the pyramid was placed about half an inch from the
wooden square attached to the resonating fork.

Throughout the experiments we used blue light, obtained by
passing a beam from an electric lamp through a cell containing an
ammoniacal solution of copper sulphate. A slit about 2 inches
long and one-twentieth of an inch broad was cut out of a piece of tin-
foil pasted on glass, and was placed horizontally across the middle of
the bands, so that the bright and dark bands appeared as bright and
dark spots respectively.

In our earlier experiments, we took photographs upon flexible film
fastened by india-rubber bands to a rotating drum. A ball shutter,
such as is used in instantaneous photography, was employed. Working
at night, after the traffic had subsided, the bands in their normal
condition were perfectly steady. On taking a photograph, each
bright band produced a perfectly straight line upon the rotating film,
and the whole picture was made up of a series of parallel straight
lines.

On sounding a 64-fork in the vicinity of the apparatus, the
mirror is set in motion by resonance and thus the bands execute
harmonic motions, with a frequency of 64, about their mean positions.
The general appearance as then seen by the eye is a blue blur. When
this blur was photographed by means of the slit and rotating drum,
we obtained a series of sinuous lines. To prove that the frequency
of these curves corresponded to a note of 64 vibrations per second, we
made observations on the rate of turning of the drum. The following
are some of the actual figures obtained : —

Circum. of drum = 31*5 cm. 100 revs, in 19'5 sees.
Wave-length = 2'53 cm.

No. of vibns. per sec. = ^9.5 x 2-53 = ^3'9.

We thus obtained a series of photographs of what may be called
the difference arid summation curves, which were exhibited in a
preliminary communication read by Professor Riicker at the recent
meeting of the British Association held in Toronto.

The details of the method now employed are different, and we

398 Messrs. K. W. Forsyth and R. J. Sowter.

venture to think much better suited for obtaining good photographs,
though the drum enabled us to determine the frequency of the
oscillation more easily. When the drum was used, it was incon-
venient to take more than one photograph on the same film, and
moreover, it was impossible to use plates, which in some respects have
advantages over films.

Having satisfied ourselves by means of the drum, that the frequency
of the curves we obtained corresponded to 64, we had recourse to
a sliding plate arrangement fitted with an automatic shutter. The
sliding piece is capable of carrying 3 feet of plate 2 inches in width,
and the shutter is so arranged that any 6 inches of the plate can be
exposed at will. With one filling of the slide, it is therefore possible
to take six photographs.

Our first effort was to obtain photographs of the steady bands when
no sounds were produced. We have taken many of these, and
reproduce one of them in (Plate 6) fig. 1.

Fig. 2 shows a photograph taken when a 64 fork was sounding
rather loudly.

Fig. 3 shows an extraneous disturbance produced by the
slamming of a door. It is evident that the vibrations are compound
and, in part at all events, forced. We then proceeded to obtain
the difference-tone. The frequencies of the two notes used were 256
and 320, and these were produced as by Riicker and Edser with a
Helmholtz double wind siren. The 12 row of holes was tuned to a
256-fork, and then to produce the 320-note the 15 row of holes was
opened.

Fig. 4 shows a photograph taken when the 256-fork was sound-
ing, and when the siren was sounding in unison with it, the 12
row of holes being open. It will be seen that the bands are steady.
There is a slight vibration present, probably due to the disturbance
produced by the blowing of the bellows.

Fig. 5 shows a photograph taken immediately after the foregoing
one, upon the same plate, and under exactly the same conditions with
the single exception, that the 15 row of holes was opened and the
320-note therefore sounding in conjunction with the 256. The
objective reality of the difference-tone is clearly proved. This
experiment has been repeated on several occasions and with different
notes, and we have obtained many photographs demonstrating the
vibratory motion which is given to the bands by the difference-tone.
In all cases, we have proved that the separate notes sounding alone
produced no effect upon the bands.

Fig. 6 (Plate 7) is another photograph of the effects produced by
a difference-tone.

It will be observed in these two photographs, that although the
chief effect is that due to the sounding of a 64-note, there is super-

Roy. Soc. Proe., vol. 63, J'late (i.

Fig.

Fig.

>)(/ tfoirfer.

Jfni/. .Vor. jfVoc., /W. f>8, yj/«/f 7

F^g.

Fig.
9.

Fig.
9.

The Objective Reality of Combination lones. 399

imposed npon this some other disturbance which canses a slight
departure from the perfect regularity of the curves. This disturbing
effect is probably due to the fact, that, as it is difficult to keep the
pitch of the notes given by the siren absolutely constant, they had
departed somewhat from their proper values at the moment when the
photograph was taken, and thus forced vibrations of a pitch slightly
different from that of the tuning fork were added to those corresponding
to its natural period.

Having finished experiments on the difference-tone, we proceeded
to photograph effects produced by the summation tone. The two
notes used were obtained from the 9 and 12 rows of holes of the
upper box of the Helmholtz double wind siren. It is easily seen
that, to give a summation tone of 64, the disc must be revolving
64/(9-f 12) = 3'048 times per second. To obtain this rate of rotation
we used a stroboscopic method. On the upper surface of the lower
box of the siren, we affixed a star-like disc with 18 rays, and
viewed it through slits carried by a fork having a frequency of 27*4.

When the star appears stationary, the disc is revolving at the
desired rate, for 18 X 3'048 — 27'4 x 2 approximately.

We have taken photographs of the steady bands when the siren has
been going at the proper speed, and one set of holes open only. These
are exactly like the steady bands obtained in the former cases. On
sounding the two notes together the summation tone is produced, and
we have photographed it in the manner already described. Figs. 7,
8, and 9 show some of the photographs obtained.

In fig. 9, where the amplitude of the vibration of the bands is
large, the plates used were not sufficiently sensitive to photograph
them when moving through their mean positions. When the bands
are in their extreme position and therefore at rest, the exposure is
inversely proportional to the velocity of the plate. But when the
bands are passing, through their mean position, the exposure is
inversely proportional to the velocity found by compounding the
velocity of the plate with the velocity of the bands in a direction at
right angles. If the amplitude is large enough, this velocity may be
so great as to render the time of exposure too small to affect the plate.
This phenomenon is slightly noticeable in fig. 5, and is very well
marked in figs. 8 and 9.

In conclusion, we wish to thank Mr. Cameron for assisting us
in taking some of the later photographs, and Mr. Chapman for the
help he has given us in preparing the lantern slides and prints.

400 Cytological Features of Fertilisation, fyc., in Pinus silvestris.

" On the Cytological Features of Fertilisation and related
Phenomena in Pinus silvestris^ L." By VERNON H.
BLACKMAN, B.A., F.L.S., Hutchinson Student, St. John's
College, Cambridge, and Assistant, Department of Botany,
British Museum. Communicated by FRANCIS DARWIN,
F.R.S. Received May 3,— Read May 26, 1898.

(Abstract.)

This paper gives a fairly complete account of the minute Cytological
details of the act of fertilisation and of the processes surrounding it,
from the formation of the ventral canal cell up to the period of cell-
wall formation at the base of the egg.

As the oosphere nucleus, after separation of the nucleus of the
ventral canal cell, moves rapidly back towards the centre of the egg,
it increases greatly in size, as described by Strasburger. This
increase in size is shown to be due to the appearance in the nucleus
of a peculiar metaplasmic substance, which fills up the nucleus, and,
owing to its attraction for stains, ultimately obscures the chromatin.
The mature female nucleus, which is sometimes large enough to be
visible to the naked eye, exhibits merely an uniformly staining reticu-
lum composed chiefly of metaplasmic substance, with one or more
nucleoli.

By the rupture of the closing membrane of the well-marked pit
at the apex of the pollen tube, almost the whole of the contents of
the lower part of the tube pass over into the oosphere. At this
stage all the four nuclei, together with a considerable number of
starch grains from the pollen tube, are to be seen lying in the cyto-
plasm of the egg. Cytoplasm from the pollen tube must also
necessarily pass over, and with it the plastid-lik-e structures to be
seen earlier in the cytoplasm of the generative cells.

The behaviour of the four nuclei in the egg was carefully followed ;
the stalk cell nucleus, the pollen tube nucleus, and one generative
nucleus remain at the apex of the egg, near the point of entry, and
ultimately become disorganised. The other generative nucleus,
which possesses distinct nucleoli, as does also its sister nucleus,
advances very rapidly towards the female nucleus, increasing some-
what in size and in mass of staining material on its way. After
coming in contact with the much larger female nucleus it gradually
penetrates the substance of the latter until it is almost completely
enclosed within it, but breaking down of the nuclear walls, that is,
actual fusion, is for some time delayed. After fusion has taken
place, but while the outlines of the two nuclei are still distinct,
the chromosomes can be distinguished as two separate groups derived

Experiments on Aneroid Barometers and their Discussion. 401

from the male and female nuclei respectively. Indications of the
first segmentation spindle are also to be observed at this stage as
fine staining threads running throughout both nuclei. No definite
resting fertilised nucleus is formed.

The spindle, which lies obliquely in the centre of the egg, is at
first multipolar in form, and while it is in this condition the chromo-
somes begin to split longitudinally, but can still be distinguished
roughly into two groups.

Only after the formation of four segmentation nuclei do these
begin to wander down to the base of the egg. On its way down
each nucleus has a distinct sheath of cytoplasmic fibres, but when it
reaches the base these become replaced by fine cytoplasmic threads,
which run from the nucleus out into the general cytoplasm. These
later-formed cytoplasmic; threads seem to be connected with the for-
mation of cell walls around the nuclei.

The number of chromosomes in the egg nucleus was determined
by counting them in the division which cuts oif the ventral canal
cell, and was found to be twelve. The same number was also to be
found in the nuclei of the cells of the prothallial tissue and of the
pollen mother cells. The chromosomes of the first segmentation
spindle, on the one occasion on which they could be counted, were
exactly twenty-four in number. The chromosomes were also counted
in several types of sporophytic tissue ; at least twenty-one chromo-
somes could always be observed ; presumably twenty-four are always
present.

No centrospheres or centrosomes were to be seen in connection
either with fertilisation or with any of the related processes.

" Experiments on Aneroid Barometers at Kew Observatory
and their Discussion." By C. CHREE, Sc.D., L.L.D., F.R.S.,
Superintendent. Received May 5, — Read June 9, 1898.

(Communicated by the Author at the request of the Kew Observatory Committee.)

(Abstract.)

The paper deals with two species of data. The first consists of
particulars derived from the records at Kew Observatory as to
the errors observed in about 300 aneroid barometers. These had been
subjected to the ordinary Kew test, which consists in lowering the
pressure to which the aneroid is exposed inch by inch to the lowest
point at which verification is desired, and raising the pressure in a
corresponding way to its original value. Readings are taken at
each inch of pressure during both the fall and the recovery, and a
table of corrections is obtained by reference to the corresponding
readings of a mercury gauge.

402 Experiments on Aneroid Barometers and their Discussion.

The second group of data are the results of special experiments
made at Kew Observatory during the last three years. These were
intended to link together the phenomena exhibited in the Kew
verifications, and to further investigate various points bearing on the
usefulness of the certificate hitherto issued to aneroids.

The aneroid is an instrument exhibiting elastic after-effect, fre-
quently in a conspicuous way. When pressure is lowered and then
maintained constant, the aneroid's reading continues to fall, and when
pressure is restored to its original value, the aneroid reads at first
lower than it did originally, but exhibits a gradual tendency to recover.
These general facts have of course been long known. The most
characteristic features were in fact discussed 30 years ago by
Dr. Balfour Stewart, then superintendent of Kew Observatory, who
dealt with a considerable mass of experimental material. They have
also been the subject of a comparatively recent pamphlet by Mr.
Edward Wbymper, who gives the results of a number of interesting
long period experiments.

The present paper is partly experimental and partly theoretical.
It treats of how the differences between the readings with pressure
descending and ascending in a normal pressure cycle, such as the
Kew test, vary throughout the range, and how the sum of these
differences varies from one range to another. It investigates how
the error, as pressure is reduced, varies with the rate of fall of pressure
(when uniform), how the fall of reading at a low stationary pressure
increases with the time, depends on the pressure, and varies with the
rate of the previous fall of pressure, and how the recovery after a
pressure cycle progresses with the time, and is modified by the nature
of the previous pressure changes. The influence of subsidiary
stoppages during the fall or rise of pressure is investigated, and
experiments are discussed showing the influence of temperature on the
various phenomena.

Some of the aneroids employed for the special experiments having
been under observation for nearly three years, the opportunity is
taken of considering the secular change of zero, and also changes in
the elastic and the after-effect properties.

Algebraic and exponential formulae are obtained by trial for such
phenomena as the variation of the differences of the descending and
ascending readings throughout a pressure cycle, the dependence of
the sum of such differences on the range, the fall of reading at the
lowest pressure and the final recovery. A theory, to some extent
empirical, is built up, leading to mathematical results, depending on
only three arbitrary constants, for the behaviour of an aneroid in the
ordinary Kew test over any range. One of these constants varies
with the aneroid, but is determined by the observed value of such a
quantity as the sum of the differences of the descending and ascending

On the Heat dissipated by Platinum at High Temperatures. 403

readings over any convenient range. The other two constants depend
on the length of the stoppage at the lowest point of the range, and the
relation between the rates of the lowering and the recovery of pressure.
The results calculated in this way show a very satisfactory agreement
with the Kew verifications.

The investigation being principally intended to increase the useful-
ness of the existing Kew test, and to show where it is most in need
of amplification or amendment, attention is primarily given to the
defects of aneroids. It is hoped that the increased knowledge of these
defects will enable rules to be framed for the rejection of aneroids, and
that in this way it will be made worth while for makers to improve
the instrument. , The large differences brought to light between
different aneroids, show that the means of markedly raising the average
are already at the makers' disposal if they choose to utilise their
knowledge. The present enquiry also shows clearly how the effects
of tentative improvements may best be ascertained. The method of
utilising aneroids to the best advantage in determining mountain
heights is not formally considered, but a variety of the results should
nevertheless be found of immediate service by any traveller of intel-
ligence who has this object in view.

" On the Heat dissipated by a Platinum Surface at High Tem-
peratures." By J. E. PETAVEL, 1851 Exhibition Scholar.
Communicated by LORD RAYLEIGH, F.R.S. Received
May 19,— Read June 9, 1898.

(Abstract.)

The first part of the paper refers to the emissivity of a bright
platinum surface in air and in other gases.

The temperature measurements are based on the researches of
Callendar and Griffiths, confirmed by the recent determinations of
Heycock and Neville. To check the calibration of the thermometers
at higher temperatures, the melting point of palladium was used. A
number of the curves are extended to 1779° C. by a direct measure-
ment of the emissivity of platinum and palladium at their melting
points.

The platinum wire, which served at the same time as radiator and
thermometer, was Oil 2 cm. in diameter. It was placed in the axis
of a vertical glass cylinder, which formed the enclosure.

The effects produced by a change in the size, shape, material, and
temperature of the enclosure and in the position and diameter of the
wire are also studied.

The temperature is expressed in degrees centigrade, and the emis-
sivity in C.G.S. units.

404 On the Heat dissipated by Platinum at High Temperatures.

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On a new Constituent of Atmospheric Air. 405

An abstract of the values obtained is given in the table (p. 404).

Part II consists of a bolometric study of the radiation emitted by
platinum at temperatures ranging from 500° C. to the melting point
of the metal. It is shown that for theoretical reasons the true rate
of change of the total radiation with temperature lies between the
values obtained by measuring the heat lost by the radiating body
and those deduced from the readings of any form of bolometer or
thermopile.

By comparing the observations of Dr. J. T. Bottomley and
Schleiermacher, based on the first method, with those of F. Paschen
and of the author, made by the second method, a reliable criterion
is obtained by which to test any formula intended to express the law
of thermal radiation.

The formulae of Dulong and Petit, of Stefan, and of Bosetti fail
when tested in this manner ; whilst Weber's formula, from 400° to
800° C., gives results in close agreement with the true rate of
change of total radiation with regard to temperature.

The second part of the paper also contains a description of some
points of interest in the design of the bolometer which was used
during this work.

Part III refers to the variation of the intrinsic brilliancy of plati-
num surface with temperature.

The results may be expressed by the following formula :—

0-400) = 889-6 «yb,

where i is the temperature in degrees centigrade, and b the intrinsic
brilliancy in candle power per square centimetre. The constant 400
is taken as the temperature limit at which the visible radiation falls
to zero.

"On a new Constituent of Atmospheric Air." By WILLIAM
RAMSAY, F.R.S., and MORRIS W. TRAVERS. Received
June 3— Read June 9, 1898.

This preliminary note is intended to give a very brief account
of experiments which have been carried out during the past year
to ascertain whether, in addition to nitrogen, oxygen, and argon,
there are any gases in air which have escaped observation owing
to their being present in very minute quantity. In collaboration
with Miss Emily Aston we have found that the nitride of magne-
sium, resulting from the absorption of nitrogen from atmospheric
air, on treatment with water yields only a trace of gas ; that gas is
hydrogen, and arises from a small quantity of metallic magnesium
unconverted into nitride. That the ammonia produced on treatment

VOL. I.X11I. ^ H

406 Prof. W. Ramsay and Mr. M. W. Travers.

with water is pure lias already been proved by the fact that Lord
Rayleigh found that the nitrogen obtained from it had the normal
density. The magnesia, resulting from the nitride, yields only a trace
of soluble matter to water, and that consists wholly of hydroxide and
carbonate. So far, then, the results have been negative.

Recently, however, owing to the kindness of 'Dr. W. Hampson, we
have been furnished with about 750 cubic centimetres of liquid air,
and, on allowing all but 10 cubic centimetres to evaporate away
slowly, and collecting the gas from that small residue in a gas-
holder, we obtained, after removal of oxygen with metallic copper,
and nitrogen with a mixture of pure lime and magnesium dust, fol-
lowed by exposure to electric sparks in presence of oxygen and
caustic soda, 26*2 cubic centimetres of a gas, showing the argon
spectrum feebly, and, in addition, a spectrum which has, we believe,
not been seen before.

We have not yet succeeded in disentangling the new spectrum
completely from the argon spectrum, but it is characterised by two
veiy brilliant lines, one almost identical in position with D3, and
almost rivalling it in brilliancy. Measurements made by Mr. E. C.
C, Baly, with a grating of 14,438 lines to the inch, gave the following
numbers, all four lines being in the field at once : —

Di 5895-0

D2 5889-0

D3 5875-9

D4 5867-7

There is also a green line, comparable with the green helium line
in intensity, of wave-length 5568"8, and a somewhat weaker green,
the wave-length of which is 5560'6.

In order to determine as far as possible which lines belong to
the argon spectrum, and which to the new gas, both spectra were
examined at the same time with the grating, the first order being
employed. The lines which were absent, or very feeble, in argon,
have been ascribed to the new gas. Owing to their feeble intensity,
the measurements of the wave-lengths which follow must not be
credited with the same degree of accuracy as the three already given,
but the first three digits may be taken as substantially correct : —

Violet 4317 Blue 4834

, 4387 „ 4909

„ 4461 Green 5560*6

„ 4671 „ 5568-8

Blue 4736 Yellow 5829

„ 4807 „ 5867-7

„ 4830 Orange 6011

On a new Constituent of Atmospheric Air. 407

Mr. Baly has kindly undertaken to make a study of the spectrum,
which will be published when complete. The figures already given,
however, suffice to characterise the gas as a new one.

The approximate density of the gas was determined by weighing
it in a bulb of 32*321 cubic centimetres capacity, under a pressure of
521*85 millimetres, and at a temperature of 15*95°. The weight of
this quantity was 0*04213 gram. This implies a density of 22*47,
that of oxygen being taken as 16. A second determination, after
sparking for four hours with oxygen in presence of soda, was made in
the same bulb ; the pressure was 523' 7 millimetres, and the tempera-
ture was 16*45°. The weight was 0*04228 gram, which implies the
density 22*51.

The wave-length of sound was determined in the gas by the
method described in the " Argon " paper. The data are :—

i. ii. iii.

Wave length in air 34*17 34*30 34*57

,, „ gas 29*87 30*13

Calculating by the formula

X2air X densityair : \2gas X densitygas : : 7air : <ygas)
(34*33)2 x 14*479 : (30)3 x 22*47 : : 1*408 : 1*666,

it is seen that, like argon and helium, the new gas is monatomic and
therefore an element.

From what has preceded, it may be concluded that the atmo-
sphere contains a hitherto undiscovered gas with a characteristic
spectrum, heavier than argon, and less volatile than nitrogen, oxygen,
and argon ; the ratio of its specific heats would lead to the inference
that it is monatomic, and therefore an element. If this conclusion
turns out to be well substantiated, we propose to call it " krypton,"
or " hidden." Its symbol would then be Kr.

It is, of course, impossible to state positively what position in the
periodic table this new constituent of our atmosphere will occupy.
The number 22*51 must be taken as a minimum density. If we may
hazard a conjecture, it is that krypton will turn out to have the
density 40, with a corresponding atomic weight 80, and will be found
to belong to the helium series, as is, indeed, rendered probable by
its withstanding the action of red-hot magnesium and calcium on
the one hand, and on the other of oxygen in presence of caustic
soda, under the influence of electric sparks. We shall procure a
larger supply of the gas, and endeavour to separate it more com-
pletely from argon by fractional distillation.

It may be remarked in passing that Messrs. Kayser and Fried-
lander, who supposed that they had observed D3 in the argon of the

408 Sir W. Crookes. On the Position of Helium,

atmosphere, have probably been misled by the close proximity of the
brilliant yellow line of krypton to the helium line.

On the assumption of the truth of Dr. Johnstone Stoney's hypo-
thesis that gases of a higher density than ammonia will be found in
our atmosphere, it is by no means improbable that a gas lighter than
nitrogen will also be found in air. We have already spent several
months in preparation for a search for it, and will be able to state
ere long whether the supposition is well founded.

"On the Position of Helium, Argon, and Krypton in the
Scheme of Elements." By SIR WILLIAM CROOKES, F.R.S.
Eeceived and Read June 9, 1898.

It has been found difficult to give the elements argon and helium
(and I think the same difficulty will exist in respect to the gas
krypton) their proper place in the scheme of arrangement of the
elements which we owe to the ingenuity and scientific acumen
of JSTewlands, Mendeleef and others. Some years ago, carrying a
little further Professor Emerson Reynold's idea of representing the
scheme of elements by a zigzag line, I thought of projecting a scheme
in three dimensional space, and exhibited at one of the meetings of
the Chemical Society* a model illustrating my views. Since that
time, I have re-arranged the positions then assigned to some of the
less known elements in accordance with later atomic weight deter-
minations, and thereby made the curve more symmetrical.

Many of the elemental facts can be well explained by supposing the
space projection of the scheme of elements to be a spiral. This curve
is, however, inadmissible, inasmuch as the curve has to pass through
a point neutral as to electricity and chemical energy twice in each
cycle. We must therefore adopt some other figure. A figure-of-eight
will foreshorten into a zigzag as well as a spiral, and it fulfils every
condition of the problem. Such a figure will result from three very
simple simultaneous motions. First, an oscillation to and fro
(suppose east and west) ; secondly, an oscillation at right angles to
the former (suppose north and south), and thirdly, a motion at right
angles to these two (suppose downwards), which, in it simplest form,
would be with unvarying velocity.

I take any arbitrary and convenient figure-of-eight, without refer-
ence to its exact nature ; I divide each of the loops into eight equal
parts, and then drop from these points ordinates corresponding to the
atomic weights of the first cycle of elements. I have here a model
representing this figure projected in space; in it the elements are

* Presidential Address to the Chemical Society, March 28, 1888.

Argon, and Krypton in the Scheme of Elements. 409

supposed to follow one another at equal distances along the figure-
of-eight spiral, a gap of one division being left at the point of
crossing. The vertical height is divided into 240 equal parts on
which the atomic weights are plotted, from H = 1 to Ur = 239'59.
Each black disc represents an element, and is accurately on a level
with its atomic weight on the vertical scale.

The accompanying figure, photographed from the solid model,
illustrates the proposed arrangement. The elements falling one
under the other along each of the vertical ordinates, are

H

He

Li

Gl

B

C

N

O F Na

Mg

Al

Si

P 8

Cl

Ar

K

CcT,

8c

Ti

V

Cr Mn-Fe-ETi-Co Cu

Zii

Ga

Ge

As Se

Br

Kr

Kb

Sr

Yt

Zr

Nb

Mo Bh-BirPd Ag

CM

In

8n

Sb Te

I

—

Cs-

Ba

La

Ce

( )

( ) ( ) ( )

( )

( )

( )

( ) ( )

( )

—

( )

( )

( )

( )

Ta

W IrPt'Os An

Hg

Tl

Pb

Bi —

—

—

—

—

—

Th

—

Ur -

—

—

—

— —

The bracketed spaces between cerium and tantalum are probably
occupied by elements of the didymium and erbium groups. Their
chemical properties are not known with sufficient accuracy to enable
their positions to be well defined. They all give coloured absorption
spectra and have atomic weights between these limits. Positions
marked by a dash ( — ) are waiting for future discoverers to fill up.

Let me suppose that at the' birth of the elements, as we now know
them, the action of the vis generatrix might be diagrammatically
represented by a journey to and fro in cycles along a figure-of-eight

410 Position of Helium, Argon, and Krypton in the Elements.

patL, while simultaneously time is flowing on, and some circumstance
by which the element-forming cause is conditioned (e.g., temperature)
is declining; (variations which I have endeavoured to represent by
the downward slope.) The result of the first cycle may be represented
in the diagram by supposing that the unknown formative cause has
scattered along its journey the groupings now called hydrogen, lithium,
glucinum, boron, carbon, nitrogen, oxygen, fluorine, sodium, mag-
nesium, aluminium, silicon, phorphorus, snlphur, and chlorine. But
the swing of the pendulum is not arrested at the end of the first round.
It still proceeds on its journey, and had the conditions remained
constant, the next elementary grouping generated would again be
lithium, and the original cycle would eternally reappear, producing
again and again the same fourteen elements. But the conditions are
not quite the same. Those represented by the two mutually rectan-
gular horizontal components of the motion (say chemical and electrical
energy) are not materially modified ; that to which the vertical com-
ponent corresponds has lessened, and so, instead of lithium being
repeated by lithium, the groupings which form the commencement of
the second cycle, are not lithium, but its lineal descendant, potassium.

It is seen that each coil of the lemniscate track crosses the neutral
line at lower and lower points. This line is neutral as to electricity,
and neutral as to chemical action. Electro-positive elements are
generated on the northerly or retreating half of the swing, and
electro-negative elements on the southerly or approaching half.
Chemical atomicity is governed by distance from the central point of
neutrality ; monatomic elements being one remove from it, diatomic
elements two removes, and so on. Paramagnetic elements congregate
to the left of the neutral line, and diamagnetic elements to the right.
With few exceptions, all the most metallic elements lie on the north.

Till recently chemists knew no element which had not more or less
marked chemical properties, but now by the researches of Lord
Rayleigh and. Professor Ramsay, we are brought face to face with a
group of bodies with apparently no chemical properties, forming
an exception to the other chemical elements. I venture to suggest
that these elements, helium, argon, and krypton in this scheme
naturally fall into their places as they stand on the neutral line.
Helium, with an atomic weight of 4, fits into the neutral position
between hydrogen and lithium. Argon, with an atomic weight of
about 40, as naturally falls into the neutral position between chlorine
and potassium. While krypton with an atomic weight of about 80,
will find a place between bromine and rubidium.

See how well the analogous elements follow one another in order :
C, Ti, and Zr ; N and V ; Gl, Ca, Sr, and Ba ; Li, K, Bb, and Cs ; 01,
Br and I ; S, Se, and Te; Mg, Zn, Cd, and Hg; P, As, Sb, and Bi;
Al, Ga, In, and Tl. The symmetry of these series shows that we are

Position of Helium, Argon, and Krypton in the Elements. 411

on the right track. It also shows how many missing elements are
waiting for discovery, and it would not now be impossible to emulate
the brilliant feat of Mendeleef in the celebrated cases of Eka-silicon
and Eka-aluminium . Along the neutral line alone are places for many
more bodies, which will probably increase in density and atomic weight
until we come to inert bodies in the solid form.

Four groups are seen under one another, each consisting of closely
allied elements which Professor Mendeleef has relegated to his 8th
family. They congregate round the atomic weight 57, manganese,
iron, nickel and cobalt; round the atomic weight 103, ruthenium,
rhodium, and palladium ; while lower down round atomic weight 195
are congregated osmium, iridium and platinum. These groups are
interperiodic because their atomic weights exclude them from the
small periods into which the other elements fall ; and because their
•chemical relations with some members of the neighbouring groups
show that they are interperiodic in the sense of being formed in
transition stages.

[Note, June 22nd, 1898.

Since the above was written, Professor Ramsay and Mr. Travers
have discovered two other inert gases accompanying argon in the
atmosphere. These are called Neon and Metargon. From data sup-
plied me by Professor Ramsay, it is probable that neon has an atomic
weight of about 22, which would bring it into the neutral position
between fluorine and sodium. Metargon is said to have an atomic
weight of about 40 ; if so, it shares the third neutral position with
argon. 1 have marked the positions of these new elements on the
diagram.]

VOL. LXIII. 2 I

412 Meeting of June 16, 1898.

June 16, 1898.

SIB JOHN EVANS, K.C.B., D.C.L., Treasurer and Vice-President,

in the Chair.

Mr. H. F. Baker, Mr. S. F. Harmer, Mr. Arthur Lister, Lieut.-
General C. A. McMahon, the Hon. Charles A. Parsons, Professor T.
Preston, Professor E. Waymonth Reid, Dr. Alexander Scott, Mr. A,
C. Seward, Mr. W. A. Shenstone, Mr. H. M. Taylor, and Mr. James
Wimshurst were admitted into the Society.

The following Papers were read : —

" Observations on Stomata." By FRANCIS DARWIN, F.R.S.

II. " Note on the Attenuation and Exaltation of the Virulence of
the Organism of Texas Fever." By A. EDINGTON, M.B.
Communicated by Professor T. R. FRASER, F.R.S.

III. "Mathematical Contributions to the Theory of Evolution.

V. On the Reconstruction of the Stature of Prehistoric
Races." By Professor KARL PEARSON, F.R.S.

IV. " On some Expressions for the Radial and Axial Components

of the Magnetic Force in the Interior of Solenoids of
Circular Cross-section." By C. COLERIDGE FARR. Commu-
nicated by Professor H. LAMB, F.R.S.

V. " On the Source of the Rontgen Rays in Focus Tubes." By
A. A. C. SWINTON. Communicated by LORD KELVIN, F.R.S.

VI. " On the Companions of Argon." By Professor RAMSAY, F.R.S.y
and MORRIS W. TRAVERS.

VII. " Contributions to our Knowledge of the Fucaceae, their Life-
history and Cytology."* By Professor J. B. FARMER and
J. LI. WILLIAMS. Communicated by Dr. D. H. SCOTT,
F.R.S.

VIII. " On the Detection and Localisation of Phosphorus in Animal
and Vegetable Tissues." By Professor A. B. MACALLUM.
Communicated by Professor SHERRINGTON, F.R.S.

* This is the full paper of which the communication entitled " On Fertilisation,
and the Segmentation of the Spore, in Fucus" read June 18, 1896, and published
in the 'Proceedings/ vol. 60, p. 188, is to be regarded as the ' Abstract.'

Observations on Stomata. 413

IX. " Summary of the principal Results obtained in a Study of the
Development of the Tuatara (Sphenodon punctatum) ." By
Professor A. DENDY. Communicated by Professor HOWES,
F.R.S.

X. " Tables for the Solution of the Equation

By W. STEADMAN ALDIS, M.A. Communicated by J. J.
THOMSON, F.R.S.

XI. " The StomodaDum, Mesenterial Filaments, and Endoderm of
Xenia." By J. H. ASHWORTH, B.Sc. Communicated by
Professor HICKSON, F.R.S.

The Society adjourned over the Long Vacation to Thursday,
November 17fch, 1898.

" Observations on Stomata." By FRANCIS DARWIN, F.R.S.
Received May 31,— Read June 16, 1898.

(Abstract.)

The method described depends on the fact that in adult leaves
transpiration is stomatal rather than cuticular, so that, other things
being equal, the yield of watery vapour depends on the degree to
which the stomata are open, and may be used as an index of their
condition. In principle, it is the same as the methods of Merget* and
Stahl.f These observers used hygroscopic papers impregnated with
reagents which change colour according as they are dry or damp, and
Stahl, who employed paper soaked in cobalt chloride, has obtained
excellent results. In my laboratory I have used, for some years, a
hygroscope for demonstrating stomatal transpiration, in which evapo-
ration is indicated by the untwisting of the awn of Stipa pennata ; J
my present instrument is of the same general type, but the index is
made of " Chinese leaf," i.e., shavings of pressed and heated horn.§ If a
strip of horn is placed on a dry substance, e.g., the astomatal surface of
a leaf, it does not move, but on the stomatal surface, it instantly curves
strongly away from the transpiring surface. In the hygroscope the

* ' Comptes Rendus,' 1878.
f ' Bot. Zeitung,' 1894.

£ Darwin and Acton, ' Practical Physiology of Plants/ 1st edition, 1894.
§ I also use the epidermis of a Yucca — a material which I owe to the kindness
of Mr. Thiselton-Dyer.

2 i 2

414 Mr. F. Darwin.

degree of curvature is read off on a graduated quadrant, and in this
way a numerical indication of the condition of the stomata is obtained.

The instrument makes no claim to accuracy, but has proved
extremely useful when used comparatively to indicate and localise
small changes in the transpiration of leaves, and therefore by impli-
cation, changes in the condition of the stomata. By observing under
the microscope the uninjured leaf of Caltha palustris, and comparing
the variations in the size of the stomata with the variations in
the readings of the hygroscope, it is easy to convince one's self of the
value of the method. It must be especially noted that though a fall
in the hygroscope readings corresponds with a narrowing of the
stomatal opening, it does not follow that zero on the hygroscopic
scale means absolute closure of the stomata. This want of sensitive-
ness has one advantage, namely, that cuticular transpiration has no
effect on the horn index, so that any movement of the index must
depend on a stomatal transpiration. The hygroscope indicates well
the gradual " closure "* of the stomata that occurs as a plucked leaf
withers. It is generally stated that marsh and aquatic plants do not
close their stomata under these circumsbances. I find that, although
the phenomenon is much less marked than in terrestrial plants, yet
that, in many species, partial closure of the stomata undoubtedly
occurs in the aquatic class.

The most interesting fact observed in withering leaves is that in
many cases the " closure " of the stoma is preceded by temporary
opening, which may occur almost simultaneously with the severance
of the leaf from the plant. Thus the hygroscope readings rise at
first, and subsequently sink to zero. The interest of this fact is the
demonstration of the interaction between the guard cells and the
surrounding epidermis. The phenomenon is best seen in plants with
milky juice, but is not confined to this class. The preliminary
•opening of le stomata occurs in the early morning, but not in the
evening — a fact which is of importance in relation to the mechanism
of the nocturnal closure of the stomata.

A diminution of the stomatal transpiration can also be brought
:about by compressing the stem of the plant in a vice, a process which
is known to diminish the water supply. f The stomatal closure is here
probably an adaptive response to the lowering of the water-supply
of the leaf, but this is not quite certain.

A series of experiments were made on the comparative effect of
moist and dry air, from which it is clear that the stomata " close "
before any visible signs of flaccidity occur in the leaf. When leaves
are exposed to air dried by H2S04, " closure " is preceded by a remark-

* I use the word " closure " to mean such a narrowing of the stomatal aperture
as corresponds with zero on the hygroscope.

f F. Darwin and R. Phillips, ' Camb. Phil. Soc. Proc.,' 1886.

Observations on Stomata. 415

ably prolonged opening of the stomata — a phenomenon which requires
further investigation.

Baranetzky* showed that slight degrees of disturbance affect
transpiration. The hygroscope gives no evidence of increased tran-
spiration when the disturbance is slight. When the plant is violently
shaken the leaves become flaccid and the stomata " close," and in
some cases the closure is preceded by increased transpiration, 110
doubt due to temporary opening of the stomata, induced by the
guard cells being released from epidermal pressure before they have
lost their own turgor.

N. J. C. Miillerf showed that stomata may be closed by electric
stimulation ; my experiments show that while a strong shock narrows
the stomata, a weaker one opens them, no doubt owing to the tem-
porary loss of epidermal pressure.

Some experiments on poisonous gases and vapours were made.
Chloroform and ether slowly " close " the stomata, which finally
reopen in a normal atmosphere. Pure C02 also slowly closes the
stomata.

The hygroscope is well fitted to demonstrate the fundamental facts
in relation to light. The fact that the storaata are widely open in
sunshine is well known ; the difference between bright and less
bright diffused light is not so well known, nor the fact that in
dark stormy weather the stomata may be nearly closed by day, even
in summer. The effect of difference of illumination is well shown
in certain leaves having stomata in both surfaces, e.g., Iris, Narcissus,
and the phyllodes of Acacia cyclopis. In these the stomata on the
illuminated surfaces are much wider open than on the less brightly
illuminated sides ; and when the plant is reversed in position in
regard to light, the stomata rapidly accommodate themselves to the
change in illumination.

The most interesting fact in regard to the effect of artificial
darkness is that it is more effectual in producing closure in the after-
noon than in the morning ; and, conversely, illumination opens
closed stomata more readily in the morning than later in the day.
These, together with other observations, tend to show a certain
amount of inherent periodicity in the nocturnal closure of the
stomata. Another fact of interest is that in darkness prolonged for
several days the stomata gradually open. This last observation is
used in the section on the mechanism of the stoma as an argument
against the prevalent view that the stoma closes in darkness, because
in the abeyance of assimilation the osmotic material, on which the
turgor of the guard cells depends, ceases to be manufactured.

* c Bot. Zeitung,' 1872.

+ Pringsheim's ' Jahrbiicher,' vol. 8, 1872.

416 Observations on Stomata.

Schellenberger* lias striven to uphold this view by showing that
in the absence of C03 the stomata close as though they were in
darkness. My experiments on plants deprived of C02 lead to abso-
lutely contrary results, namely, that the stomata remain perfectly
open even during prolonged deprivation of CO2.

It is a vexed questionf whether or no the majority of plants
close their stomata at night. My conclusion is- that in terrestrial
plants (excluding nyctitropic plants) a great majority show some
closure at night ; the horn hygroscope stands at zero on the stomatal
surface of by far the greater number of ordinary plants. On the
other hand, the hygroscope shows widely open stomata on most
aquatic plants at night. StahlJ concludes that nyctitropic plants
are remarkable for not closing the stomata at night ; this fact I
somewhat doubtfully confirm ; but the question is not so simple as it
seems, owing to the varying behaviour of the stomata at night in
different temperatures.

Since the hygroscope gives numerical readings, it is possible to
represent graphically the daily opening and closing of the stomata.
The curve begins to leave the zero with the morning light ; it rises
rapidly at first, and afterwards more slowly. In some cases it runs
roughly horizontally until a rapid fall begins in the evening. In
other cases there is a slow rise up to the highest point, which occurs
between 11 A.M. and 3 P.M. The hygroscope generally sinks to zero
within an hour after sunset.

The effect of heat has not been fully studied, but enough has been
done to confirm previous observers who find that heat opens the
stomata. As regards the visible spectrum, I find that the red rays
are decidedly most efficient, but I am not able to find any evidence
of a secondary maximum in the blue, such as Kohl§ describes.

The biology of the nocturnal closure is a subject which can
hardly be discussed in a condensed manner. It is suggested that
the gaseous interchange of assimilation may require widely open
stomata, whereas respiration may be carried on with comparatively
closed apertures. If this is so, the stomata might be to a great extent
shut at night, and an economy in the use of water effected, without
detriment to metabolism. Observations are given to show that
quite another effect is brought about by nocturnal closure. As long
as the stomata are open, the transpiring leaf is considerably cooler
than the dry -bulb thermometer, but at night it has almost the tem-
perature of the air. In this way a saving of heat is undoubtedly
effected — but it is not easy to say whether it is sufficient to be of much

* * Bot. Zeitung,' 1896.

f Leitgeb, ' Mittheilungen aus dem Bot. Inst. zu Graz,' 1886.

j 'Bot. Zeitung,' 1897.

§ ' Beiblatt zur Leopoldina,' 1895.

Mathematical Contributions to the Theory of Evolution. 417

practical importance to the plant. I am inclined to believe, from
Sachs'* experiments on the depletion of leaves, that all saving of
heat must be valuable, by preventing the checking of translocation
which he observed on cold nights.

The mechanism of the stoma is another subject which does not
lend itself to condensed treatment. I have tried to point out that
the stoma has been neglected in the modern reorganisation of plant
physiology from the point of view of irritability. Some observers
insist on the preponderant influence of the guard cells, while Leitgeb
in the same way exaggerated the importance of epidermic pressure,
whereas the two factors should, as far as possible, be considered as
parts of a whole and as correlated rather than opposed in action. I
have also attempted to show how the stoma, like other parts of the
plant, may be supposed to react adaptively to those signals, which we
usually call stimuli. The attempt which I have made to rank the
problem among the phenomena of irritability, is very tentative in
character. I have ventured to put it forth because I am convinced
that it is in this direction that advances will be made.

•" Mathematical Contributions to the Theory of Evolution. Y.
On the Reconstruction of the Stature of Prehistoric Races."
• By KARL PEARSON, F.R.S,, University College, London.
Received June 6, — Read June 16, 1898.

(Abstract).

1. The object of this memoir is to illustrate the general theory by
which we may reconstruct from the knowledge of one organ in a fossil
or prehistoric race, the dimensions of other organs, when the correla-
tion between organs in existing races of the same species has been
ascertained. The particular illustration chosen is the reconstruction
of probable stature from a measurement of the long bones.

Up till quite recently this subject remained in great obscurity,
partly on account of absence of theory, and partly for want of trust-
worthy data.

2. The estimated statures as obtained by Orh'la, Topinard or Beddoe,
•or by use of their methods, differ widely, and those methods have
no satisfactory theoretical basis. It was usual to suppose that there
was some mean or average ratio of stature to long bone, and even
when it was recognised that this ratio varied with the length of the
long bone, it was thought sufficient to determine it for two or three
separate ranges of stature, and determine its mean value for these
ranges by a very limited number of cases.

* ' Arbeiten,' 1884.

418 Prof. Karl Pearson.

3. The first stage in advance was taken when Rollet published his
measurements made in the Anatomical Theatre at Lyons, of the
stature and long bones of 100 corpses. Rollet's attempt to establish
ratios on the basis of his measurements is not very satisfactory, but
to him belongs the credit of having first provided a respectable, if not
large amount of data. Rollet's work was followed by a very able
memoir on the reconstruction of stature by Manouvrier. Rejecting
about one half Rollet's data, he constructed tables giving the average
stature for certain ranges of each of the six long bones, and farther
what he terms coefficients moyens ultimes, for ascertaining the stature
corresponding to long bones lying outside the limits of his tableau
bareme. There are many traces in Manouvrier's paper of the old view
of a " coefficient " by which the long bone must be multiplied in order
to obtain the stature. Beyond this view, it cannot be said to contain
any theory, and it suffers from certain marked defects. In the
first place, proper allowance does not seem to be made for cartilage
and the disappearance of animal matter from the bones. The 2 mm.
allowed on each bone appear by no means sufficient. In the second
place, Manouvrier does not seem to. me to justify his extension of
results obtained from the French to very divergent races. He merely
remarks that individ ual variations are greater than ethnic. Even if this-
extension be made, it must be done with hesitation, and with a full
recognition of the assumptions made. Lastly, we may note that the
statures obtained from the different long bones by Manouvrier's table
for particular races, are often rather widely divergent among them-
selves, and no attempt is made to account for this divergence.

4. Manouvrier's memoir was rapidly followed by an excellent piece
of work from Rahon, who collected measurements of the long bones of
a very wide series of local races of man, and reconstructed their
stature by aid of Manouvrier's tables. This memoir will remain of
first-class importance even if better reconstruction formulae than those
of Manouvrier are adopted. Manouvrier's tables have been used in
recent German memoirs, as those of Kitsch e and Kollmann on the
skeletons of the Row Graves and of the Schweizersbild. They are
accepted at present as the standard tables for the reconstruction
of stature.

5. The present memoir starts with the theory of probability, which
the author has already applied to other problems in evolution,,
and deduces the most probable stature for any combination of the four
long bones. It is shown that for a population with normal correlation,,
the relation between stature and one or more long bones is always
linear. A general theorem is proved to show that no linear function
of the long bones can give the probable stature with so small
a probable error as the regression formula of the theory of probability.
From this result the following conclusions are obtained :

Mathematical Contributions to the Theory of Evolution. 419

(a) No constancy of the ratio stature to long bone is theoretically
to be expected, but the ratio of deviation from mean stature to
deviation from mean long bone, i.e., the regression coefficient is the
quantity, the constancy of which might be expected.

(6) No method of predicting individual stature from the indi-
vidual long bones, whether one or all are used, can give a result
with a less probable error than 2 cm.

(c) For the same length of femur, tibia, and humerus, the stature
is shorter the longer the radius. This result has considerable bear-
ing on the relationship of man to the anthropomorphous apes.

6. Formulae are then obtained for the reconstruction of probable
stature, as measured :

(a) On corpse, from the lengths of the long bones containing
animal matter, and with the cartilages attached. These will possibly
be of service for purposes of criminal investigation.

(6) In life, from the lengths of the long bones without cartilages,,
and free of all animal matter.

Corrections are given for cases in which the femur is measured in
the oblique position ; the tibia is measured with the spine ; and the
left, instead of the right, hand members are known.

7. While the formulae are tested on twenty cases, taken at random
from Reliefs data, with fairly satisfactory results, the step from
variation within the local race to racial variations is not made without
a consideration of the circumstances under which natural selection,
will modify a regression formula. It is pointed out that the diver-
gence between such regression formulae really enables us to predict
to some extent the nature of the differential selection which has
taken place between two local races. To test how far we may safely
apply our formulas to other than French measurements, the stature
of the Ainos <$ and ? is reconstructed by means of them from
Koganei's measurements of the long bones, and the result is found
to be very satisfactory. If French regression formulas give good
results for the Aino, they will give, in all probability, good results-
for prehistoric European races. At the same time it is most import-
ant that material should be obtained for an independent investiga-
tion of the regression formulas for another European race. With
a view of illustrating the change in the regression formulae owing to
selection, the anthropomorphous apes are considered, and it is shown
that the gorilla, in the regression formulas for femur and tibia
stands much closer to man than either the chimpanzee or orang.

8. The formulas are applied to reconstruct the stature of Palaeolithic
man, Neolithic man in France and Britain, of the Dolmen-builders
and Guanches, of Bound Barrow British, and Bow Grave Germans^
of Romano-British and Bomano-Gauls, of Anglo-Saxons, Franks,
mediaeval French, and of the Naqada race discovered by Professor

420 Drs. C. J. Martin and T. Cherry.

Petrie, and measured by Mr. Warren. The modern populations
occupying the same districts of Europe as Palaeolithic and Neolithic
man appear to be taller, but in the case of both south Germany and
France there appears to be a slight, but sensible, decrease of stature
since prehistoric times. Modern English do not seem to have
•decreased in stature since the ancient Anglo-Saxons. In the esti-
mates of stature for the above races, the author differs, in some
cases very considerably, from previous writers.

9. Beyond the range of normal population (say from 157 to
175 cm. for ^), the line of regression ceases to be linear. An
attempt is made, such as existing data will allow of, to express the
line of regression by the equation to a curve. The constants of this
curve are determined for measurements of the four chief long bones,
and the results exhibited in a diagram, from which it is possible to
deduce the probable stature corresponding to a given length of any
long bone by inspection. The prediction of the stature of dwarfs
from the curve obtained from the data of giants shows only 2'25 cm.
mean error, and must be considered satisfactory. Application is
then made of the results to reconstruct the stature of Bushmen,
Andamanese, and Akkas. These give sufficiently good results to
lead us to believe that a fair estimate can be made of the stature of
European neolithic dwarfs.

The memoir concludes with a table of reconstructed statures and
sexual ratios.

" The Nature of the Antagonism between Toxins and Anti-
toxins." By C. J. MARTIN, M.B., D.Sc. Lond., Acting
Professor of Physiology, and THOMAS CHERRY, M.D., M.S.
Melb., Demonstrator and Assistant Lecturer in Pathology
in the University of Melbourne. Communicated by W.
D. HALLIBURTON, F.R.S. Received May 7 — Read June 9,
1898.

In the * Deutsche Med. Wochenschrif t ' for 1894 appeared a contro-
versy on this subject between Bearing and Buchner. Behring
maintained that the antagonism was of a chemical nature, and that
the antitoxin neutralised the toxin much as an alkali neutralised an
acid. Buchner, on the other hand, adduced results opposed to this
view, pointing to the interpretation that the action was an indirect
one, due to the antitoxin operating in some indirect way through the
medium of the cells of the organism. Since this controversy many
investigations have been made with the object of deciding this funda-
mental point. At the present time, however, opinion is still divided ;

The Antagonism between Toxins and Antitoxins. 421

Behring. Ehrlich, and Kanthack being principal exponents of the
direct chemical view, whilst Buchner, E/oux, and Metchnikoff: still
maintain that the interaction takes place only through the interven-
tion of some cells in the body.

We will briefly review the more important observations which bear
directly upon the subject of our paper.

(1) Observations favouring the Interpretation that the Action of
Antitoxins is indirect.

Calmette* in 1895 made experiments with the toxin of cobra poison
and its antitoxin, which he had recently succeeded in producing.
Cobra poison is not apparently attenuated by heating its solutions to
68° C. for ten minutes. The antitoxin is, however, completely de-
stroyed by this treatment. Mixtures of cobra poison and antitoxin
which produced no symptoms when injected into a rabbit, killed
similar rabbits in a few hours if after the mixture had remained in
contact for ten minutes it were heated for another ten minutes to
68° 0. before injecting. From his experiments Calmette concluded
that the toxin of snake venom does not interact with its antitoxin in
vitro, but only in corpore, and therefore that its action cannot be
explained as a simple chemical operation between the two.

Wassermannf found that the toxin produced by the bacillus pyo-
cyaneus was not destroyed by boiling, whereas its antitoxin was.
The amount of toxin and antitoxin which neutralised each other was
first determined by experiment, then the same quantities and propor-
tions of these substances were allowed to remain in contact and
afterwards heated to boiling. The animals receiving an injection of
this heated mixture died, whereas the control animals which received
an equal dose unheated recovered. From these experiments Wasser-
mann concluded that the toxin of pyocyanens does not interact with
its antitoxin in vitro, but only in corpore, and therefore that it cannot
be explained as a simple chemical operation between the two.

Nikanorow { discovered that the precipitate formed by the addition
of a 1 per cent, solution of cupric acetate was possessed of antitoxic
properties and the filtrate not. A 1 per cent, solution of cupric
acetate does not, however, precipitate the toxin. Mixtures of the two
could thus be separated by the use of this reagent. Experiments
conducted along the lines mentioned in the experiments above led to
identical results.

Marenghi§ made some observations with the toxin and antitoxin

* « Ann. de 1'Inst. Pasteur,' 1895, p. 250.

f ' Zeits. f. Hyg.,' 1896, B. 22, p. 263.

t ' Wratsch,' 1896, vol. 31, abstracted ' J. Ph. Chem.,' 1896, p. 983.

§ < Centralbl. f. Bakt.,' 1897,' vol. 22, p. 521.

422 Drs. C. J. Martin and T. Cherry.

of diphtheria which were identical in principle with those of
Calmette and Wassermann. In this case, however, it is the toxin
which is destroyed at the lower temperature (60° C. Roux and
Yersin), whereas the antitoxic properties still remained after heating
the serum to 70° C. Mixtures of the two in such proportions as to
cause no symptoms when injected into a guinea-pig were made.
After heating such mixture to a temperature sufficient to destroy the
toxin, the mixture was discovered now to possess antitoxic properties
which could be titrated against a fresh amount of toxin.

2. Observations favouring the interpretation that the action of Antitoxins

is direct.

The view that the operation is a direct one has always received
support from the general truth of the " law of multiples," on which
indeed the antitoxin notation has been founded. It is further
strengthened by the observations of Kanthack and Ehrlich.

Kanthack,* in 1896, demonstrated that the influence of cobra
poison in preventing the coagulation of shed blood, observed by
Cunningham, was prevented by the previous admixture of some of
Calmette's an ti venomous serum to the solution of cobra poison.

Ehrlichf found that if a solution of ricin, be added to defibrinated
blood ( ? animal) the corpuscles are precipitated in a clump. A
ricin solution of the same strength, but containing a little serum
from an animal immunised against ricin, failed to produce this result.

Within the last few days we have received a short account of
some experiments by Stephens and Meyers, J bearing upon the same
point. Cobra poison exercises a haemolytic action upon blood in
vitro. After admixture of the poison with antivenomous serum
this heemolytic action was absent. The necessary precaution of
making the solution of the venom with saline solution approximately
iso tonic with blood serum was taken.

Before relating the results of our own experiments we may point
out one source of fallacy in the conclusions drawn by Wassermann,
Calmette, Nikanorow, and Marenghi, viz., that they take no account
of the factor, time, which may be a very important element in any
possible chemical interaction between toxins and antitoxins. Every
chemical reaction has a certain definite velocity coefficient, and the
rapidity of action under any circumstances where the reacting com-
pounds are in solution depends upon this coefficient, and also upon

* Demonstrated at meeting of Physiol. Soc., October 1896 (not published in
Proceedings) .

t ' Fortschr. d. Med.,' 1897, No. 2.

J " Eeport of Proceedings of Path. Soc. of London," ' Lancet,' March 5, 1898,
p. 644.

The Antagonism between Toxins and Antitoxins. 423

the product of the active masses of the reacting bodies present.
Temperature will also exercise an important influence.

As we shall later show, the experiments quoted by these observers
can easily be repeated and the same results obtained. Nevertheless
their conclusions are quite unjustified, and by modification of the
factors, time, temperature, and active masses, exactly opposite results
may also be obtained.

Experimental results obtained by the Authors.

Our experiments have been conducted with the toxin of diphtheria,
and one of the constituents of the poison of the Australian tiger
snake (SoplocepTialus curtus.)

The diphtheria toxin was prepared by cultivating the organisms
in broth made from well hung beef, after the method of Spronck.*
It was filtered through a sound Pasteur-Chamberland filter, and the
toxin strength of the filtrate determined by injection into a series
of guinea-pigs. That with which most of our experiments were
conducted, had a minimum lethal dose of 0'12 c.c. per kilogram in
48 hours.

The antitoxins used were Behring's No. 1 and serum from the
Pasteur Institute, Paris.

The constituent of the venom used was the one which is not
destroyed by heating a solution of venom to 90° C. This consti-
tuent resembles most closely, if indeed it be not identical with, the
principal constituent of cobra poison ; and, as shown by one of us,f
Calmette's antivenomous serum possesses a small but decided counter-
acting action upon it. This action, though unfortunately of little or
no practical importance, is sufficient for our present purpose, for in
our experiments we could mix comparatively large quantities of the
serum with small fatal doses of the venom in vitro. Under these
circumstances one could easily neutralise the poison.

The antitoxin was the antivenomous serum prepared by the Pasteur
Institute at Lille, and bore date November, 1896.

We endeavoured at the outset to determine whether the action of
antitoxins upon toxins were chemical or physiological, by a direct
physical method. In 1896 one of usj published an account of a
method of separating substances of large molecular size from those of
smaller, in solutions containing both. This method was simply by
filtering through a film of gelatin, supported in the wall of a
Pasteur-Chamberland filter. The filtration was accomplished by a
pressure of 50 atmospheres.

* ' Ann. de 1'Inst. Pasteur,' 1895.

f C. J. M., ' Intercolonial Med. Journ. of Australasia,' August, 1897.

J C. J. M., < Journal of Physiol.,' rol. 20, 1896.

424 Drs. C. J. Martin and T. Cherry

A standardised solution of diphtheria toxin was filtered through
such a filter. The filtrate was found to contain diphtheria toxin.
This filtrate was then tested to ascertain whether it were as toxic as
the original solution. As will be seen from the protocols it was
somewhat diminished in toxic power (Protocol I).

The antitoxin of diphtheria, as was shown by Brodie,* does not
pass through such a filter. When antitoxic serum is filtered through
gelatin, the whole of the proteids, and together with them all anti-
toxic virtue, are absent from the filtrate (Protocol II). As the toxin
is not held back by the filter, whereas the antitoxin is, one is provided
with a simple physical means of separating them, provided they have
not reacted upon one another.

We mixed a solution of toxin containing eight fatal doses per
kilogram of guinea-pig in each c.c., with sufficient Behring's anti-
toxin to more than completely neutralise all the toxin. This mixture
was allowed to remain in contact at 30° C. for two hours, and then
filtered through the gelatin filter. Varying quantities of the
filtrate were injected into guinea-pigs up to nearly 4 c.c. per kilo-
gram of body weight, that is a quantity originally containing 32
fatal doses. The filtrate was quite innocent. The guinea-pigs
suffered no inconvenience, and gained weight while under observa-
tion in small cages. The injections produced no local oedema.

If the toxin had remained unaffected beside the antitoxin there
was nothing to prevent it passing through the filter in virtue of its
relatively small molecular size. As, however, it did not do so, we
can only conclude that it had entered into some sort of chemical
relationship with the relatively large molecules of the anti-toxin
during their sojourn together prior to filtration.

Having obtained results so definite, and in apparent contradiction
to those of the authors quoted in the beginning of this paper, we
next experimented with snake venom in order to repeat Calmette'sf
observations.

We took a series of rabbits (Protocol V) and injected them with
mixtures containing one constituent of the venom of Eoplocsphalus
curtus and Calmette's antivenomous serum. On reference to the
protocols of this series of experiments it is seen that 2 c.c. of this
sample of serum was sufficient to counteract an amount of the poison
contained in '0002 gram of the dried venom. This amount killed
control rabbits in about eight hours (Protocol IV).

In some of the experiments this amount of venom and serum was
allowed to remain in contact for fifteen minutes at the laboratory
temperature (21° C.) and then heated to 68° C. for ten minutes to
destroy the antitoxin. In Calmette's experiments the rabbits

* « Journ. of Path.,' 1897, p. 460.
+ Cairn ette, loc. cif.

The Antagonism 'between Toxins and Antitoxins. 425

injected with this heated mixture died, whereas the controls injected
with the mixture which had not been heated lived. From this he
concluded that the serum and venom were merely existing side by
side, and had not re-acted upon one another. In our experiments, on
the contrary, the rabbits injected with the heated and unheated
mixtures of venom and sernm alike lived, nor did any of them suffer
from symptoms such as loss of appetite, loss of weight, or diminished
temperature. The only conclusion to be drawn from these experi-
ments is that during the time which elapsed between the mixture of
the venom and serum the latter had acted upon the former, so that
there was no longer a fatal dose of venom present. The protocols-
will show that heating for ten minutes to 68° C. has no influence upon
the venom. (P. VI, experiment 4.)

These results, while they lead to results in entire agreement with
those drawn from the filtration experiments with diphtheria toxin
and antitoxin, are diametrically opposed to the results obtained by
Calmette. As the experiments are so simple as not to leave any
possibility of experimental error, we turned our attention to any
existing difference in the conditions under which Calmette and our-
selves worked. As previously pointed out, Calmette absolutely
neglected the possible influence of time, temperature, and the relative
proportions of the active masses of the toxin and antitoxin present
in his mixture. Up to the present we have investigated the value of
the factors, time, and proportion of active masses, and have shown
that these are most important. Indeed, by altering either the one or
the other we can produce results which, if these factors be neglected,,
would lead to diametrically opposite conclusions.

The toxin and antitoxin of this venom are both of great molecular
size and complexity. The former is a deutero-albumose and the
latter probably a globulin,* or at any rate its molecular size is of the
same order. A priori one would expect the velocity coefficient of any
reaction between such complex molecules to be a high one, and in
addition, from their great molecular weight, the solution will contain
relatively few molecules : so that it is not surprising that any
chemical operation in which they are concerned should occupy a very
appreciable time.

The value of the factors time and influence of proportion of active
masses will be best seen in reference to the table below, which is
compiled from Protocols VII, VIII, IX, and represents the results
of twenty-one experiments. On reading along any horizontal line
will be seen the influence upon the result of the time during which
the toxin and antitoxin were allowed to operate upon each othery
with proportion of active masses constant. On reading any vertical
line the influence of varying proportions of active masses with time

* Brodie, loc. cit.

426

Drs. C. J. Martin and T. Cherry.

of operation constant is indicated. The thick line separates off the
fatal results from those in which the rabbits lived. All other
factors were kept constant. The solutions were mixed in the vary-
ing proportions and stood at laboratory temperature (20 — 23° C.).
At stated intervals, by a stop watch, portions were pipetted off, and
the reaction terminated by rapidly raising the temperature to 68° C.
in a water bath. They were kept at this temperature for 10 minutes,
cooled, and kept for injection.

Proportion of
toxin to antitoxin
per kilo.

Control
venom
only.

Time allowed for interaction of toxin and antitoxin,
temp. 20—23° C.

Anti-
toxin.

Toxin.

2 mins.

5 mins.

10 mius.

15 mins.

30 mins.

Injected
un heated
oo mins.

Ic.c.

2 fatal
doses.

Died
15 hours.

Lived
(very ill
for 2 days)

Lived
(ill 1 day).

Lived
(no symp-
toms).

Lived
no symp-
toms).

Lived
(no symp-
toms).

Lived
(no symp-
toms).

Ic.c.

3 fatal
doses.

Died
12 hours.

Died
20 hours.

Died

28 hours.

Lived
(ill
2 days).

Lived
(ill 1 day).

Lived
(no symp-
toms).

Lived
(no symp-
toms).

1 c.c.

4 fatal
doses.

Died
9 hours.

Died
13 hours.

Died
15 hours.

Died
23 hours.

Lived
(very ill
2 days).

Lived
(no symp-
toms).

Lived
(no symp-
toms).

In our experiments with diphtheria we allowed abundance of
time, 2 hours, for the reaction between the toxin and antitoxin to
take place. The surplus of antitoxin was also large, so that the
active masses were considerable and the temperature was favourable,
via 30° C. (Protocol III). We have not yet determined the in-
fluence of temperature upon the rapidity of the reaction, but our
results so far seem sufficiently conclusive to decide the question and
leave no room for doubt that the antagonism between the toxins of
diphtheria and snake venom and their relative antitoxin is due to
a direct chemical action which takes place between them. Further,
that the opposite conclusion come to by Calmette, and presumably
those of Wassermann, Nikanarow, and Marenghi were due to their
disregard of the value of time as a factor in such chemical action.

The Antagonism between Toxins and Antitoxins. 427

Protocols.

A. EXPERIMENTS WITH DIPHTHERIA TOXIN.

t

I. Experiments to ascertain whether the Toxin of Diphtheria passes
through a Gelatin Filter.

The toxins were prepared bj the method stated above and filtered
through a Pasteur-Chamberland filter to free them from bacilli.
The minimal fatal dose calculated for one kilogram weight of
guinea-pig was 0*12 c.c. of toxin No. 1, and 0*6 c.c. of toxin No. 2.
Portions of each of these toxins were filtered through gelatin and
afterwards injected into guinea-pigs. As seen below the filtrates in
each case contained toxin, but in less amount than the original
solutions.*

Toxin No. 1.

Amount
injected.

Weight of
animal
in grams.

Eesult.

Before filtering through,
gelatin • ....

0-25 cc.

562

Died under 36 liours

» »

5J J>

After filtering through

0-5 „

i-o „

0-12 „

540
655

187

» 5>

>> j>
, in 41 hours.

5> »

0-24 „

176

,, in 30 hours.

Toxin No. 2.

Amount
injected.

Weight of
animal
in grams.

Result.

Before filtering through

0'5 c.c.

377

Died in 56 hours.

After filtering through

0-5 „

275

„ 72 hours.

* This small diminution in toxic power by filtration may possibly be due to the
action of oxygen at high, tension (50 atmospheres of compressed air) or to the
size of the toxin molecule being of the order of the molecular size of albumoses.
Albumoses, as shown by one of us (' J. Physiol.,' 1896), pass through gelatin, but
le?s readily than water, and the filtrate is accordingly less concentrated than the
original solution.

VOL. LXIII. 2 K

428 Drs. C. J. Martin and T. Cherry.

II. Experiments to confirm Brodie's* statement that the Antitoxin of

Diphtheria does not pass through a Gelatin Filter.

0*5 c.c. of Pasteur Institute antitoxin was mixed with 1 o.e. of toxin
No. 1 (=8 fatal doses per kilo.), and injected into a guinea-pig
weighing 260 grams.

The animal remained well and gained 26 grams during the
four days it was kept under observation. The same sample of anti-
toxin was passed through the filter. Of the filtrate 0*6 c.c. was
mixed with 0'6 c.c. of the same toxin and injected into a guinea-pig
weighing 163 grams. The animal died in 22 hours.

III. Experiments to show that when Diphtheria Toxin is mixed with
Diphtheria Antitoxin in sufficient quantity, and allowed to remain in
contact for a sufficient time, the filtrate which has passed through
a Gelatin Filler is free from Toxin.

60 c.c. of toxin No. 1 (containing approximately 500 lethal doses
per kilogram) was mixed with 2'5 c.c. of Behring's antitoxin
<(= 600 units). The two were well mixed and allowed to stand at
30° C. for two hours before filtration.

The filtrate was injected subcutaneously into guinea-pigs as
under : —

Weight
in grams.

Amount
injected.

Amount per kilo, of
body weight.

'.Result.

400
340
318

1-0 c.c.
1-25 „
1-25 „

2 -5 c.c. = 20 fatal doses
3 -6 c.c. = 30 „
3 -9 c.c. = 32

No symptoms.

» 5>

5) »

The animals were absolutely unaffected. They never failed in
appetite, nor was there any local oedema.

B. EXPERIMENTS WITH SNAKE VENOM.

IY. Experiments to determine the Minimal Fatal Dose of the Poison

used.

The venom employed was that of Hoplocephalus curtus. This had
been procured free from admixture with saliva by making the reptiles
bite into a watch-glass covered with thin rubber sheeting. The
liquid poison was rapidly dried at ordinary temperatures (15 — 20° C.)
over calcium chloride, powdered, and stored in a stoppered bottle.

* Loc. cit.

The Antagonism between loxins and Antitoxins. 429

All weights of venom mentioned below refer to this dried venom.
About 2 — 3 milligrams were weighed out for each experiment and
dissolved in 0*9 per cent. NaCl solution, so that 1 c.c. contained
O'OOOl gram of dried venom.

The solution was then heated momentarily to 90° C. in order to
destroy one of the poisonous constituents of the venom of this snake,
a proteid which coagulates at 85° C.* This was done because
Calmette's serum possesses little or no immunising action against
this constituent.f

In all our experiments the same sample of venom was used, and it
was treated in the way described above. The injections were always
made subcutaneously into the flank.

Amount of

Animal.

Weight in
grams.

original venom per kilo,
of body weight in

Result.

grams.

Rabbit....

1360

0 -0004

Died in 5 hours.

j, ....

1020

0-0002

8 „

910

0 -0002

9 ,

....

1250

0 -00016

10 ,

. . • •

1705

0-00015

10

....

1250

0-0001

10

....

1240

0 -00008

12

....

1030

0 ;000075

10

1220

0 -00005

16

1370

0 -000036

24

....

1300

0-00003

„ 48

....

1380

0 -00003

Lived. Very ill 3 days.

....

1820

0 -0000275

Died in 24 hours.

....

1430

0 -000025

„ 3 days.

....

1140

0 -00002

Lived. Yery ill 3 days.

....

1300

0 '00002

j> >»

From the above series it appears that O000025 gram per kilo, of
body weight is about the lowest fatal dose. In the present paper, in
speaking of so many fatal doses, this has been taken as the unit.

V. Experiments to ascertain the value of Calmette's Serum in counter-
acting the Poison after it had been deprived by Heat of One Con-
stituent.

The solution of venom was prepared as in Series III. Calmette's
serum bore date November, 1896. The two were mixed together in
varying proportion, as stated below, and allowed to remain at)

* C. J. M , < Proc. Roy. Soc., N.S.W./ August, 1896.
f C. J. M., ' Intercol. Med. J.,' August, 1897.

430

Drs. C. J. Martin and T. Cherry.

laboratory temperature (23° C.) for fifteen minutes. They were
injected subcutaneously in amounts corresponding to the body weight
of the animal.

Animal.

Weight
in
grams.

Amount of
venom in grams
per kilo.

Amount of
serum in c.e.
per kilo.

Eesult.

= 16 fatal doses.

Babbit

1350

0-0004

None

Died 5 hours.

5>

1370

0-0004

0-25

,i 6 „

5)

1330

0 -0004

0-5

» 10 .,

»

1370

0-0004

1-0

i. 12 „

J>

1375

0-0004

1-5

„ 16 „

= 8 fatal doses.

» «...

1240

0 -0002

1-0

» 38 „

,, ....

1220

0-0002

1-5

Lived. Ill 2 days.

690

0-0002

2-0

,, No symptoms.

„

1380

0-0002

3-0

» » 5)

2 c.c. of the serum completely counteracts 0'0002 gram of the
venom deprived of one of its constituents.

VI. "Experiments to determine whether mixture of venom and serum
(in such proportions as to completely deprive the former of any toxic
properties), regained toxic properties after destroying the antitoxin
by heating to 68° C. per 10 minute*, subsequent to admixture.

The venom solution and sernm were mixed in the proportion of
1 c.c. of serum to every O'OOOl gram of venom. This proportion
was found by the previous series of experiments to be adequate.
The two solutions were mixed together, and allowed to remain 30
minutes at a temperature of 23° — 24° C., after which the mixture
was heated to 68° C. for 10 minutes to destroy the antitoxin. They
were then cooled and injected subcutaneously in varying quantities
per kilogram weight of the animal. The injections had no effect
upon the animals, although they contained originally eight fatal
closes of venom. This must therefore have been neutralised by the1
antitoxin during the time which elapsed before its destruction by
heat.

The Antagonism between Toxins and Antitoxins. 431

Animal.

Weight
in grams.

Amount of
venom per
kilo.

Amount of
serum per
kilo.

Eesult.

i. Babbit. . .
ii. „ ...
iii. „ ...

1140
710
1210

0-0002
0-0002
0 '0003

3 c.c.
2 „
3 „

1 Lived. No
symptoms.

*iv. „ ...

1020

0 -0002

None

Died in 9 hours.

v. „ ...

1160

0 -0002

None

,, 8* „

VII. Experiments to determine the influence of variations in the time
during which venom, and antivenomous serum, operated upon one
another.

In this series of experiments, the same samples of venom and
serum were employed as before. The relative proportions of the
two were kept constant. The venom solution and serum were
mixed together in the proportion of O'OOOl gram of venom to 1 c.c.
of the serum and well stirred. After they had remained in contact
at the temperature of the laboratory (21° C.) for times varying
from 2 to 30 minutes, portions were pipetted off, and rapidly
raised to 68° C., at which temperature they were kept for 10 minutes.
The portions were then rapidly cooled, and injected subcutaneously
in quantities proportionate to the body weights of the animals.
Amounts of venom and of serum equivalent to O'OOOl gram and 1 c.c.
respectively per kilogram of body weight were injected in each case,
except the control, when this quantity of venom was employed.

Time during which

Animal.

Weight
in grams.

venom and serum
were in contact

Besults.

before heating.

i. Babbit. .

1370

Venom only (control)

Died in 9 hours.

ii. . .

1320

2 minutes

» 13 „

in.

1340

5 „

» 15 „

IV.

1400

10 „

» 23 „

V.

1220

15 „

Lived. Very ill for 2 days.

VI.

vii. „ . .

1160
890

30 „
Not heated at all

„ No symptoms.

3> J3 J>

* In Experiment No. IV no serum was mixed with the venom, but the venom
solution was heated alone to 68° C. for 10 minutes to show that this treatment has
no influence upon it.

432

Mr. A. A. Campbell Swinton.

VIII. — Similar to VII, except that the preponderance of Antitoxin was
greater, viz., 0'000075 gram of venom and 1 c.c. of serum per kilo-
gram of body weight in each case.

Time during which

Animal.

Weight
in grams.

venom and serum
were left in contact

Results.

before heating.

i. Eabbit

1025

Yenorn only (control)

Died in 12 hours.

ii. „

1190

2 minutes

,, 20 „

iii.

1130

5 „

v 28 „

iv. „

1060

10 „

Lived. Very ill 2 days.

v. ,,

1250

15 „

Ill 1 day.

vi. „

12 10

30 „

,, No symptoms.

vii. „

1070

Not heated at all

» ?>

. — Similar to VII and VIII, but the preponderance of Serum is still
greater, viz., 0'00005 gram of venom and 1 c.c. of serum per kilo-
gram, of body weight in each case.

Time during which

Animal.

Weight
in grams.

venom and serum
were in contact

Eesult.

before heating.

i. Eabbit

1070

Venom only (control)

Died in 15 hours.

ii. „
iii. „

1200
1170

2 minutes
5 „

Lived. Very ill for 2 days.
Off feed 1 day.

IV. ,,

1130

10 „

No symptoms.

v. „

1030

15 „

»

vi. ,,

1420

30 „

vii. „

1050

Not heated at all

»

The expenses involved in the foregoing research were in part
defrayed from a grant made by the Government Grant Committee of
the Royal Society.

" On the Source of the Rontgen Rays in Focus Tubes." By
ALAN A. CAMPBELL SWINTON. Communicated by Lord
KELVIN, F.R.S. Received June 7,— Read June 16, 1898.

The writer has already described (" Some new Studies in Cathode
and Rontgen Radiations," a discourse given at the Royal Institution
on February 4, 1898) how he has found it possible to study by
means of pin-hole photography the active area on the anti-cathode of
a focus tube from which the Rontgen rays proceed.

On the Source of the Rontgen Rays in Focus Tubes. 433

By means of a special camera he has now been able to make further
investigations. The camera is illustrated in fig. 1, where A is the
pinhole in a removable lead disc secured by a brass cap to the brass
cone B, which is lined with thick lead so as to be opaque to the
Bontgen rays. D is a framework into which slides either the
fluorescent screen E, or a carrier containing a sensitive plate should
photographs be required. F is an observation tube for use with the
fluorescent screen. It is made of insulating material to avoid danger
of shocks.

FIG. 1.

IOI254S67891O

i-i-i— f— 4 i i — ;-— >— f— i I -H

cms.

With this apparatus directed at the anti-cathode of a focus tube,
it is easy with the fluorescent screen in place to take accurate note
of the image of the active anti-cathode area which appears on the
screen, and to observe the variations in form, dimensions, and
brilliancy that take place under varying conditions. Similarly by
replacing the fluorescent screen by a photographic plate in a black
paper envelope, the Rontgen ray image can be photographed.
Exposures, varying from one to thirty minutes, according to condi-
tions, are found sufficient to impress upon the plate any effect that
can be seen directly with the screen. It has not, however, been
found possible, even with very prolonged exposures, to photograph
anything not directly visible with the screen, and having regard to
the difficulties of maintaining the vacuum and other conditions con-
stant for any considerable length of time, the method of direct
observation seems generally to be best and most convenient. For
direct observation, rather a large pin-hole, say about 2 mm. in
diameter, gives the best results ; for photography about half this
diameter is preferable, as it gives sharper images.

The writer has made numerous observations and photographs with
this apparatus, both with focus tubes of the ordinary pattern, and
also with a special tube in which both the cathode and also the anti-
cathode (which in addition acted as anode) were independently
adjustable along the axis of the tube, so that the distance between
them could be varied from a minimum of 4 to a maximum of
14 cm. This special tube is illustrated in fig. 2, and during the

434 Mr. A. A. Campbell Swinton.

observations it was connected to a mercury pump, so that the degree
of exhaustion could be varied as desired.

FIG-. 2.

3 6 7 63 K) II 12

The following are the main effects observed.

(1) When the anti-cathode intersects the cathode stream at the
focus, the dimensions of the active area are independent of the
degree of exhaustion. For all other positions beyond the focus it is
larger the lower the exhaustion and vice versa. These observations
are of course only possible between the limits of exhaustion with
which K-ontgen rays are produced.

(2) When the anti-cathode intersects the cathode stream beyond
the focus, the active area is larger the greater the distance between
cathode and anti-cathode. For instance, with the tube illustrated in
fig. 2, exhausted to a good Rontgen ray vacuum, it was found
that the active -area gradually increased from about 0'15 cm.
diameter with 4 cm. distance between cathode and anti-cathode up
to about 2'3 cm. diameter as the distance was gradually increased
to 14 cm. The increase is less the higher the vacua, but is always
very considerable.

(3) When the anti-cathode intersects the cathode stream con-
siderably beyond the focus, the active area is found to consist of a
well defined and very intense central nucleus, surrounded by a much
fainter but quite appreciable halo. Both of these increase in size as
the distance between cathode and anti-cathode is increased.

In some cases the halo consists of a well marked hollow ring with
a dark space between it and the central nucleus. In other cases two
distinct concentric rings are visible surrounding the nucleus.
Moreover, the nucleus itself, when very large, shows distinct signs
of being made up of one or more concentric rings, sometimes with a
still smaller nucleus within them. These observations correspond
with and amplify what the writer has already noticed by direct
observation of the visible luminescence of a carbon screen arranged
to intersect the cathode stream.*

(4) With an anti-cathode inclined at an angle of 45° to the
axis of the conical cathode stream, it is found that those portions
of the stream which impinge most normally upon the anti-cathode

* ' Eoy. Soc. Proc.,' vol. 61, pp. 81—84.

On the Source of the Rontgen Rays in Focus Tubes. 435

surface are considerably the most efficient in producing Rontgen
rays. Similarly those portions of the stream that impinge on the
anti-cathode surface very much on the slant are correspondingly in-
effective in producing Rontgen rays.

(5) At the degrees of exhaustion most suitable for producing
Rontgen rays, and with concave cathodes of the usual dimensions,
the cathode stream proceeds almost entirely from a small central
portion of the cathode surface, the remaining portion of the
surface being apparently practically inoperative. That this is
so was very conclusively established by photographs taken with
the tube shown in fig. 2. In the manufacture or subsequent
exhaustion of this tube three very minute fragments of glass by some
means attached themselves on to the concave surface of the alu-
minium cathode, and remained fixed there during the experiments.
The cathode itself was 29 mm. diameter, and the radial distances of
the three glass fragments from the centre were respectively about
9 mm., 4 mm., and 2'5 mm. In all the pin-hole photographs of the
anti-cathode of this tube in which the enlargement of the active area
was sufficient, the shadows of the two glass fragments nearest to the
centre of the cathode are clearly visible, while in none of them is
there any appearance of the third and outer fragment. It, therefore,
is evident that the whole of the cathode stream that was effective in
producing Rontgen rays came from an area of the cathode surface
less than 18 mm. diameter, or less than two-thirds of the full
diameter of the cathode. Further, in each case the shadows of the
two inner glass fragments appeared outside of the central nucleus,
showing that the whole of the more intense portion of the cathode
stream proceeded from a portion of the cathode surface less than 5 rnm.
in diameter. These results confirm the writer's observations made
with carbon cathodes.*

(6) The different portions of the cathode stream proceeding from
different portions of the cathode, cross at the focus and diverge in
a cone that retains any special characteristics of the convergent cone.
The relative positions of the two inner glass fragments on the
cathode, and the positions and enlargement of their shadows
on the anti-cathode for different distances between the latter and the
cathode, were found to show this very clearly.

(7) Though by far the greater portion of. the Rontgen rays given
by a focus tube proceed from the active anti-cathode area, still, a
very appreciable quantity is also given off by all those portions of
the glass of the tube that show the green fluorescence.

Using a somewhat large pin-hole, this is easily observed by turning
the tube so that the more powerful rays from the anti-cathode cannot
reach the pin-hole, when a Rontgen ray image of the whole of the
* ' Eoy. Soc. Proc.,' vol. 61, pp. 92—93.

43 6 On the Source of the Rontgen Rays in Focus Tubes.

fluorescent portions of the glass of the tube can be distinctly seen.
Further, it is noticeable that that portion of the glass that shows the
brightest fluorescence, i.e., that part which lies in the path in which
cathode rays would be reflected from the anti-cathode surface were
they reflected according to the law of equal angles of incidence and
reflection — gives off the most Rontgen rays, while those portions of
the glass that show no fluoresence do not give off any Rontgen. rays.
The conclusion appears obvious that whatever produces the one also
produces the other, but as has been pointed out by Professor S. P.
Thompson* and others, the fluorescence is not due to the direct stream
of rays from the cathode, which cannot reach portions of the glass that
show fluorescence, but to some description of radiation that proceeds
from the surface of the anti-cathode that faces the cathode. In the
paper above referred to Professor Thompson calls these radiations
" para-cathodic rays," stating that they differ from the Rontgen rays
in respect of their power of penetration, and in their capacity of
being electrostatically and magnetically deflectable. In these re-
spects the writer's experiments confirm those of Professor Thompson,
but when the latter goes on to differentiate these rays from ordi-
nary cathode rays, on account of their not exciting Rontgen rays
where they impinge on a solid surface, the writer is unable to
agree, for, as above stated, these rays do excite Rontgen rays where
they impinge upon the glass walls of the tube ; as mentioned, however,
they do this only to an extent that is relatively very feeble, and so
far as the author knows only discernable by the pin-hole method of
observation, which no doubt explains Professor Thompson's failure
to observe the effect. The " para-cathodic " radiations in question do
not, however, appear to be ordinary cathode rays. In the first place
they do not proceed directly from the cathode, but only from the
surface of the anti- cathode that faces the latter. Secondly, they do
not appear to be negatively but positively charged, as can be ascer-
tained by means of an exploring pole connected with an electro-
scope. The writer suggests that, assuming the correctness of the
Crookes theory of the nature of the cathode rays, these "para-
cathodic " rays may very probably consist of cathode ray particles
which, having struck the anti-cathode, and having thus given up
their negative charges and acquired positive charges, rebound, both
by reason of their elasticity and also by repulsion from the anti-
cathode. Perhaps owing to the comparative roughness of the anti-
cathode surface, they fly off to some extent in all available directions,
but they do so especially in that direction which the law of equal angles
of incidence and reflection requires. It also appears very possible
that these " paracathodic " rays are identical with the positively
electrified streams proceeding from the anode, which the writer has
* See 'Phil. Trans.,' A., vol. 190, pp. 471—490.

On the Companions of Argon. 437

investigated by means of radiometer mill wheels, recently described
in a paper to the Physical Society.

In any case, it seems clear that in the tubes observed and photo-
graphed with the pin-hole camera, the Rontgen rays given off by
certain portions of the fluorescent glass are not originated by the
impact of an ordinary cathode stream, but apparently by the
impact of positively charged streams proceeding from the anti-
cathode.

The writer is greatly indebted to Mr. J. C. M. Stanton and Mr. EL
Tyson Wolff, for the construction of the apparatus described, as also
for valuable assistance in the carrying out of the experiments.

" On the Companions of Argon." By WILLIAM RAMSAY, F.R.S.,
and MORRIS W. TRAVERS. Received June 13,— Read June
16, 1898.

For many months pasb we have been engaged in preparing a large
quantity of argon from atmospheric air by absorbing the oxygen
with red-hot copper, and the nitrogen with magnesium. The amount
we have at our disposal is some 18 litres. It will be remembered
that one of us, in conjunction with Dr. Norman Collie, attempted to
separate argon into light and heavy portions by means of diffusion,
and, although there was a slight difference* in density between the
light and the heavy portions, yet we thought the difference too slight
to warrant the conclusion that argon is a mixture. But our
experience with helium taught us that it is a matter of the
greatest difficulty to separate a very small portion of a heavy gas
from a large admixture of a light gas ; and it therefore appeared
advisable to re-investigate argon, with the view of ascertaining
whether it is indeed complex.

In the meantime, Dr. Hampson had placed at our disposal his
resources for preparing large quantities of liquid air, and it was a
simple matter to liquify the argon which we had obtained by causing
the liquid air to boil under reduced pressure. By means of a two-
way stopcock the argon was allowed to enter a small bulb, cooled by
liquid air, after passing through purifying reagents. The two-way
stopcock was connected with mercury gas-holders, as well as with
a Topler pump, by means of which any part of the apparatus could
be thoroughly exhausted. The argon separated as a liquid, but at
the same time a considerable quantity of solid was observed to sepa-
rate partially round the sides of the tube, and partially below the

* Density of lighter portion, 19'93 ; of heavier portion, 20'01, ' Koy. Soc. Proc.r*
vol. 60, p. 206.

438 Prof, W. Ramsay and Mr. M. W. Travers.

surface of the liquid. After about 13 or 14 litres of the argon had
been condensed, the stopcock was closed, and the temperature was
kept low for some minutes in order to establish a condition of equi-
librium between the liquid and vapour. In the meantime, the con-
necting tubes were exhausted and two fractions of gas were taken
off by lowering the mercury reservoirs, each fraction consisting of
about 50 or 60 cubic cm. These fractions should contain
the light gas. In a previous experiment of the same kind, a small
fraction of the light gas had been separated, and was found to have
the density 17*2. The pressure of the air was now allowed to
rise, and the argon disbilled away into a separate gas-holder. The
white solid which had condensed in the upper portion of the bulb
did not appear to evaporate quickly, and that portion which had
separated in the liquid did not perceptibly diminish in amount.
Towards the end, when almost all the air had boiled away, the
last portions of the liquid evaporated slowly, and when the remaining
liquid was only sufficient to cover the solid, the bulb was placed in
connection with the Topler pump, and the exhaustion continued
until the liquid had entirely disappeared. Only the solid now
remained, and the pressure of the gas in the apparatus was only a
few millimetres. The bulb was now placed in connection with mer-
cury gas-holders, and the reservoirs were lowered. The solid vola-
tilised very slowly, and was collected in two fractions, each of about
70 or 80 cubic cm. Before the second fraction had been taken
off, the air had entirely boiled away, and the jacketing tube had
been removed. After about a minute, on wiping off the coating of
snow with the finger, the solid was seen to melt, and volatilise into
the gas-holder.

The first fraction of gas was mixed with oxygen, and sparked over
soda. After removal of the oxygen with phosphorus it was intro-
duced into a vacuum-tube, and the spectrum examined. It was
characterised by a number of bright red lines, among which one was
particularly brilliant, and a brilliant yellow line, while the green and
the blue lines were numerous, but comparatively inconspicuous. The
wave-length of the yellow line, measured by Mr. Baly, was 5849*6, with
a second-order grating spectrum. It is, therefore, not identical
with sodium, helium, or krypton, all of which equal it in intensity.
The wave-lengths of these lines are as follows : —

Na (DO 5895-0

Na(D2) 5889-0

He (D3) 5875-9

Kr(D4) 5866-5

Ne (Ds) 5849-6

The density of this gas, which we propose to name " neon

On the Companions of Argon. 439

(new), was next determined. A bulb of 32'35 cubic cm. capacity
was filled with this sample of neon at 612*4 mm. pressure, and at a
temperature of 19'92° it weighed 0'03184 gram.

Density of neon 14'67.

This number approaches to what we had hoped to obtain. In
order to bring neon into its position in the periodic table, a density
of 10 or 11 is required. Assuming the density of argon to be 20,
and that of pure neon 10, the sample contains 53*3 per cent, of the
new gas. If the density of neon be taken as 11, there is 59'2 per
cent, present in the sample. The fact that the density has decreased
from 17*2 to 14* 7 shows that there is a considerable likelihood that
the gas can be farther purified by fraction ation.*

That this gas is a new one is sufficiently proved, not merely by the
novelty of its spectrum and by its low density, but also by its beha-
viour in a vacuum-tube. Unlike helium, argon, and krypton, it is
rapidly absorbed by the red-hot aluminium electrodes of a vacuum-
tube, and the appearance of the tube changes, as pressure falls, from
fiery red to a most brilliant orange, which is seen in no other gas.

We now come to the gas obtained by the volatilisation of the white
solid which remained after the liquid argon had boiled away.

When introduced into a vacuum-tube it showed a very complex
spectrum, totally differing from that of argon, while resembling it in
general character. With low dispersion it appeared to be a banded
spectrum, but with a grating, single bright lines appear, about equi-
distant throughout the spectrum, the intermediate space being filled
with many dim, yet well-defined lines. Mr. Baly has measured the
bright lines, with the following results. The nearest argon lines, a&
measured by Mr. Crookes, are placed in brackets : —

Reds very feeble, not measured.

First green band, first bright line 5632 '5 (5651 : 5619)

second „ 5583 '0 (5619 : 5567)

third „ 5537-0 (5557:5320)

Second green band, first bright line . . . 5163 '0 (5165)

second „ .... 5126 '5 (5165 : 5065) brilliant.

First blue band, first bright line 4733 '5 (4879)

second „ 4711 '5 (4701)

Second blue band, first bright line 4604 -5 (4629 : 4594)

Third blue band (first order) 4314 -0 (4333 : 4300)

Fourth blue band (second order) 4213 "5 (4251 : 4201)

Fifth blue band (first order), about .... 3878 (3904 : 3835)

The red pair of argon lines were faintly visible in the spectrum.
The density of this gas was determined with the following

* June 16th. After fractionation of the neon, the density of the lightest sample
had decreased to 137.

440 Prof. A. Dendy.

results : — A globe of 32'35 c.c. capacity,1 filled at a pressure of
765'G mm., and at the temperature 17'43°, weighed 0'05442 gram.
The density is therefore 19'87. A second determination, made after
sparking, gave 110 different result. This density does not sensibly
differ from that of argon.

Thinking that the gas might possibly prove to be diatomic, we
proceeded to determine the ratio of specific heats : —

Wave-length of sound in air 34 '18

gas 31-68

Ratio for air 1-408

„ gas. 1-660

The gas is therefore monatomic.

Inasmuch as this gas differs very markedly from argon in its
spectrum, and in its behaviour at low temperatures, it must be
regarded as a distinct elementary substance, and we therefore pro-
pose for it the name " metargon." It would appear to hold the
position towards argon that nickel does to cobalt, having approxi-
mately the same atomic weight, yet different properties.

It must have been observed that krypton does not appear during
the investigation of the higher-boiling fraction of argon. This is
probably due to two causes. In the first place, in order to prepare it,
the manipulation of a volume of air of no less than 60,000 times the
volume of the impure sample which we obtained was required ; and in
the second place, while metargon is a solid at the temperature of boiling
air, krypton is probably a liquid, and more volatile at that temperature.
It may also be noted that the air from which krypton has been
obtained had been filtered, and so freed from metargon. A full
account of the spectra of those gases will be published in due course
by Mr. E. C. C. Baly.

" Summary of the principal Results obtained in a Study of the
Development of the Tuatara (Sphenodon punctatum)" By
ARTHUR DENDY, D.Sc., Professor of Biology in the Canter-
bury College, University of New Zealand. Communicated
by Professor G. B. HOWES, F.R.S. Received June !£,—
Read June 16, 1898.

Thanks to the most generous and freely rendered services of Mr.
P. Henaghan, Principal Keeper of the Lighthouse on Stephen's
Island in Cook Straits, I have lately obtained a very perfect series of
Tuatara embryos, ranging in age from just before the appearance of
the blastopore to about the time of hatching. I have classified these
embryos in sixteen stages, and propose shortly to publish a general

Development of the Tuatara (Sphenodon punctatum). 441

account of the development with numerous illustrations. As, how-
ever, it will still take some time to complete the drawings and manu-
script, it appears desirable to publish at once a short summary of the
most interesting results obtained. The general development, as
already stated by Thomas, conforms closely to that of other reptiles,
but the following features seem to deserve special mention : —

(1) The development occupies about thirteen months, the eggs
being laid (on Stephen's Island) in November and hatched about
midsummer of the year following. The last stages in the develop-
ment, after about the first four months, occupy a much longer period
than the earlier ones, so that, having reached an already very
advanced stage, the development seems to be almost if not quite
suspended during the winter months.

(2) The blastoderm spreads around the yolk at a very early date,
and the embryo first appears as a cap-shaped mass of cells, the front
end of which is elevated above the surrounding blastoderm as the
head-fold, while the hinder and narrower end is formed by an undif-
ferentiated mass of cells representing the primitive streak. The
front part of the embryo is formed of epiblast and lower layer cells,
and from the lowest of the latter the hypoblast is subsequently
differentiated.

(3) In the primitive streak a distinct blastopore makes its appear-
ance, which presently opens into the enteron below, forming a very
distinct neurenteric canal which persists for some time.

(4) The notochord appears to be formed by a forward growth from
the primitive streak in front of the blastopore, rather than by dif-
ferentiation of hypoblast cells in the mid-dorsal line of the enteron.

(5) At a very early date the front end of the embryo sinks into the
yolk, pushing the subjacent blastoderm before it in such a manner
that the latter forms a kind of amnion closely investing the head and
the thoracic portion of the body. This "amnion," though very
thin, becomes differentiated into inner somatopleuric and outer
splanchnopleuric portions, but, at any rate for a long time, without
any mesoblast.

(6) At a comparatively late stage in development the anterior
end of the embryo, together with the somatopleuric layer of the
" amnion," is withdrawn from the splanchnopleuric layer (which
belongs really to the yolk sac), and thus the embryo comes to lie
entirely above the yolk sac.

(7) In the hinder part of the embryo the amnion is formed by
uprising folds of somatopleure meeting and fusing above the embryo,
probably accompanied by a down sinking of the embryo. This
process is continued backwards for some distance behind the embryo,
forming a narrow canal which communicates in part with the cavity
of the true amnion, and opens behind on the surface of the blasto-

442 Development of the Tuatara (Sphenodon punctatum).

derm close to the sinus terminalis. The " posterior amniotic canal "
thus formed is lined by epiblast, but it lies embedded in the meso-
blast of the serous envelope which gradually splits off from the
underlying yolk-sac around the embryo. The posterior amniotic
canal arises at a very early date, and does not persist very long-.

(8) The connection between the true amnion and serous envelope
(false amnion) in the mid-dorsal line persists in part to a very late
stage, but there is free communication between the two halves of the
pleuroperitoneal space above the embryo.

(9) In connection with the vitelline circulation, very numerous
absorbing vessels are developed which dip down far into the yolk,
and large transparent globules of yolk, each surrounded by a layer of
yolk " crystalloids," become arranged around these vessels like onions
on strings. The yolk thus gradually assumes a very characteristic
radially columnar structure.

(10) The parietal eye commences its development shortly after
the appearance of the optic lobes. It arises by evagination of the
roof of the brain in front of the prominence of the mid -brain, and
is at first situated slightly to one side of the median line (the left
side, so far as yet ascertained). It very soon becomes completely dis-
connected from its stalk as a closed, hollow vesicle, the wall of which
is composed at first of a single layer of columnar cells. The outer
(upper) part of the wall of the vesicle is thickened to form the lens
and the inner (lower) part presently divides into two very distinct
layers, and acquires a secondary, fibrous connection with the brain
immediately in front of the stalk. It is a curious fact that while
the parietal eye, after separating from its stalk, at first lies on the
left side — the stalk itself is median.

(11) The posterior commissure arises just in front of the place
where the stalk of the parietal eye connects with the brain and the
stalk passes forwards above it. This fact seems to exclude the
possibility of the stalk of the parietal eye representing the pineal
gland, for, according to Balfour, the posterior commissure arises
behind the pineal gland which is directed backwards.

(12) The pineal gland in Sphenodon appears to be represented by
a mass of convoluted tubules lying in front of the stalk of the
parietal eye.

(13) At a late stage of development (in embryos estimated at
from four to eight months) the body and part of the head are .
marked with very distinct longitudinal stripes of white on a grey
ground. This striping almost entirely disappears before hatching,
being last retained on the under surface of the head. This observa-
tion is in close agreement with those of Eimer on the markings of
mammals, &c.

(14) In embryos of the same age a patch of cornified epidermis

Ilie Stomodceum, Mesenterial Filaments, $c., of Xenia. 443

on the snout forms a very distinct "shell-breaker," which seems to
be represented in the adult by the large median scale in front of
the premaxillse.

(15) At about the time of hatching there are on each of the
premaxillsD three distinct, sharp, conical teeth, of which the outer-
most is the largest. These probably unite later on to form the
large upper cutting teeth of the adult. There are also three similar
teeth on each side in the front of the mandible, which probably
unite to form the lower cutting teeth of the adult. (I have not
found any vomerine teeth.)

Of the above results those regarding the amnion and the parietal
eye seem to be the most interesting. I had discovered and drawn
the posterior amniotic fcanal long before I was aware of Mitsukuri's
similar and previous discovery in Chelonians, and it appears to me
that the observation is of especial interest in view of the supposed
relationship between Sphenodon and the latter group, the probability
of which is greatly strengthened by the striking similarity in the
development of the fostal membranes.

The development of the parietal eye in Sphenodon certainly sup-
ports Beraneck's important conclusion that this organ (in Lacerta and
Anguis) arises independently of the epiphysis, a conclusion which
was also unknown to me until after I had come to suspect the same
thing from observing the peculiar relation of the stalk of the parietal
eye to the posterior commissure.

I may add that owing to the scarcity of biological literature in
Christchurch the works of Mitsukuri and Beraneck above referred
to are only known to me from the short abstracts in the ' Journal of
the Royal Microscopical Society.'

" The Stomodseum, Mesenterial Filaments, and Endoderm of
Xenia" By J. H. ASHWORTH, B.Sc., Demonstrator in
Zoology, Owens College, Manchester. Communicated by
Professor HiCKSON, F.R.S. Received February 23,— Read
June 16, 1898.

The specimen referred to in this note is a colony of the Alcyona-
ceous coral Xenia sp. ? from Celebes. The Xeniidae are distinguished
from all other Alcyonaria by their soft fleshy consistency and
non-retractile polyps. The former character is due to the fact that
their spicules are very minute rounded or oval discs (average measure-
ments 0*015 mm. long, O'Ol mm. broad, 0'004 mm. thick), which have
a horny basis impregnated with only a small quantity of calcium
carbonate. The polyps have the usual Alcyonaceous structure, and

VOL. LXIII. 2 L

444

Mr. J. H. Ashworth. The Stomodceum,

for the greater part of their length are bound together in bundles of
about forty to sixty, each bundle forming one stem of the colony.

The polyp, or, more correctly, the free portion of the polyp, is
5 mm. to 7'5 mm. long, and bears eight tentacles, each 4 mm. to
5'4 min. long.

Fig.i

FIG. 1. — Semidiagrammatic view of one-half of a polyp which lias been cut along
the dorso-ventral line. Only the bases of the tentacles are shown, x 20.

FIG. 2. — Transverse section through the lower third of the stomodseum (about the
level of reference line F in fig. 1). x 80. DF, dorsal meseuterial filament
on the edge of the dorsal mesentery ; F, flagella of siphonoglyphe ; Q-, gland
cells of stomodzeum ; LM, lateral mesentery (mesenterial filament absent) ;
M, mouth ; Sp, siphonoglyphe ; St, stomodseum ; T, tentacle ; VM, edge of
ventral mesentery (mesenterial filament absent) .

The stomodseum of each polyp is 1'8 mm. to 2'2 mm. in length.
It has a well marked ventral groove or siphonoglyphe, the cells of the
lower third of which bear long flagella. Many of the cells of the

Mesenterial Filaments, and Endoderm of Xenia, 445

remainder of the stomodaeum bear short cilia on their free surface,
but among these are numerous "goblet cells" (G, figs. 1 and 2),
which have not hitherto been noticed in the stomodeeum of the
Alcyonaria. These cells are swollen by some secretion to which they
give rise; they generally appear to be empty, having discharged
their secretion, which, in some cases, can be seen issuing from the cell
into the cavity of the stomodaeum. These secreting cells occur chiefly
in the middle and lower portions of the stomodoeum, and are most
abundant on the lateral walls near the siphonoglyphe (see fig. 2).
They do not occur among the cells which form the siphonoglyphe.

These " goblet cells " of the stomodaeum are the only secreting cells
connected with the digestive cavity which 1 have been able to find,
as the six thick short ventral and lateral mesenterial filaments,
which bear the gland cells in other Alcyonaria, are absent in all
polyps of this Xenia. Only the dorsal mesenteries possess thickened
edges forming the two mesenterial filaments which have a similar
course and structure to those of Alcyonium. The free edge of the
ventral and lateral mesenteries is only very slightly thickened, and
the cells which cover this edge differ in no way from those which
cover the remaining portions of the mesentery.

The two new points in the anatomy of this species of Xenia are the
presence of gland cells in the stomodaeum and the absence of the six
ventral and lateral mesenterial filaments usually present in the polyps
of the Alcyonacea. Wilson* (in Kophobelemnon) and Hicksonf (in
Alcyonium) have shown that these mesenterial filaments bear the cells
which produce the digestive secretion. I would suggest that the
absence of these filaments in this Xenia is correlated with the pre-
sence of gland cells in the stomodseum, and that these cells, judging
from their appearance and position, probably perform some digestive
function.

The siphonozooids which occur in Pennatulids and some other
Alcyonaria are the only recorded examples of polyps in which the
ventral and lateral mesenterial filaments are absent. According to
Wilson these siphonozooids derive their food-supply from the auto-
zooids or feeding-polyps, and, therefore, do not require cells to pro-
duce a digestive secretion.

In this species of Xenia, then, the secretion in connection with the
digestive cavity is formed, not by endoderm cells, but by cells which
are derived from the ectoderm, as, from a study of the buds, I have
found that the stomodaeum is ectodermic in origin in this as in other
Alcyonaria.

The endoderm cells which line the ccelentera and the cavities of the
tentacles have a similar structure throughout the colony. They are

* ' Mitt. Zool. Stat. Neapel,' vol. 5, 1884.

f ' Quart. Journ. Micr. Science,' vol. 37, 1895.

2 L 2

446 The Stomodceum^ Mesenterial Filaments. $•?,., o/Xeuia.

FIG. 3. — Endoderm cells from coelentera of poljps, showing the ordinary endc~
derm cells (E) and the cells bearing pseudopodia (P). x 400. E, endoderm
cell with racuolated protoplasm ; ME, muscle process of endoderm cell cut
transversely ; N, nucleus ; P, pseudopodia of endoderm cells.

cubical or columnar, and contain many small vacuoles which give the
protoplasm a reticulate appearance (E, fig. 3). Among the ordinary
endoderm cells there are numerous cells, the inner or free end of which
is produced into a long pseudopodium (P) which is from four to eight
times as long as the basal portion of the cell. This pseudopodium
may be slender or moderately stout, and may attain a length of over
0*12 mm. The basal part of the cell from which the pseudopodium
arises has the reticulate protoplasm of an ordinary endoderm cell, and
the nucleus of the cell is situated in this portion. The pseudopodium
is not vacuolated ; its protoplasm exhibits a homogeneous or very
finely granular structure. The pseudopodia usually taper towards
their free end, but in a few instances this end is slightly broadened
and flattened. In one case the pseudopodium, which is a very large
one, bears a short branch near the middle of its length. The pseudo-
podia appear to be flexible, as in several cases they are curved so that
their tips approach the basal portion of the cells. These curious
pseudopodia-bearing cells are very numerous, and are found in all
parts of the endoderm lining the coelentera and the cavities of the
tentacles.

On Surfusion in Metals and A Hoys. 447

" On Surfusion in Metals and Alloys." By W. C. ROBERTS-AUSTEN,
C.B., D.C.L., F.R.S. Received May 20,— Read May 26,

1898.

(PLATES 8, 9.)

Introduction.

The fact that metals and alloys may be maintained in a fluid state
at temperatures which are many degrees below their true freezing
points, has been but little studied. As regards salts the question of
surfusion has recently received much attention. Ostwald* has
shown, as the result of an investigation of great interest, that a very
minute quantity of a solid will cause a mass of the same substance to
pass from the surfused to the solid state. His work, moreover, has
led him to distinguish between the meta-stable, or ordinary condi-
tion in which surfusion takes place, and the labile condition which
occurs at temperatures much below the melting point. Ostwald's
paper, and one by M. Brillouin,f on the theory of complete and pasty
fusion lead me to offer the Royal Society the results of some experi-
ments of my own on the surfusion of metals.

Historical.

Metals do not appear to have been studied from the point of view
of surfusion until the year 1880, when some excellent experiments
on the surfusion of gold were made by the late Dr. A. D. van
Riemsdijk,]; by whose early death, which occurred last year, Holland
has lost a skilful physicist. He pointed out that : —

" Faraday, in his memoir on regelation, published in 1858, stated
that acetic acid, sulphur, phosphorus, many metals and many solu-
tions, may be cooled below the congealing temperature prior to solidifi-
cation of the first portions."§ On the other hand, in their treatises
on physics, Danguin|| and Jamin^f mention tin as the only metal
which is capable of remaining liquid at a temperature 2'5° below
the true melting point of the metal, which is 228° C.

Van Riemsdijk's contribution to the subject of surf usion of metals
consisted in showing that the well-known phenomenon of eclair, the
brilliant flash of light which often attends the solidification of the
metal in the ordinary assay of gold, is really due to surfusion. He

* ' Zeit. fur Physikal. Chem.,' 1897, vol. 22, p. 3.

t 'Ann. de Chim. et de Phys.,' 1898, vol. 13, p. 264.

£ 'Ann. de Chim. et de Phys.,' 1880, vol. 20, p. 66.

§ ' Experimental Researches in Chemistry and Physics/ p. 379.

|| Vol. 1, 1855, p. 892.

1" Vol. 1, 1859, p. 105.

448 Dr. W. C. Roberts-Austen.

also pointed out that surf usion could be either stimulated or hindered
by suitably modifying the conditions, but he made no attempt at
thermal measurements. It was not until ten years after the publica-
tion of van Riemsdijk's work that the recording pyrometer, which I
devised and submitted to the Royal Society in 1891,* enabled such
measurements to be readily effected.

It consists of a camera, enclosing a dead-beat galvanometer, to
which the free ends of a thermo- junction are attached. The thermo-
junction is suitably protected, and, as it only consists of two wires,
twisted together and covered with a fine clay tube, it can be placed
in the cooling mass of molten metal or alloy, and the cooling curve
of the mass may be traced by a spot of light from the galvanometer
which falls on a moving sensitised plate. A ready method for
studying all the phenomena of the solidification of metals and alloys
is thus afforded.

The freezing point of a metal, or the initial freezing point of an
alloy, for a fluid mass of two metals may possess many points of
solidification, is represented by one or other of three typical curves.
These are shown in the accompanying figures which indicate the

FIG. l.

nature of the curves, traced by the recording pyrometer. Fig. 1
shows the freezing point curve of a pure metal, the horizontal
portion, ob, indicating the actual solidification of the mass, the
sharpness of the angles at a and b attesting the purity of the metal.
The initial freezing point of most alloys would resemble fig. 1 in
having the corner a sharp, while the point b is generally rounded
off. If the alloyed metals form an isomorphous mixture, neither
angle is sharp, and in many cases there is no true freezing point, the
curve being of the form shown in fig. 2. This represents the
freezing of the gold-silver alloy containing 28 per cent, of gold in
which the fluid mass, as a whole, passes through a long pasty range

* '.Proc. Boy. Soc.,' 1891, vol. 49, p. 347.

On Sur fusion in Metals and Alloys. 449

FIG. 2.

before solidifying. The third type of curve, which may be a modi-
fication of the other two types, indicates the occurrence of surfusion,
and, as a case in point, pure gold has been taken, the bend at a,
fig. 3, showing the amount of surfusion which was observed. I
have detected pronounced cases of surfusion not only in gold but in
copper, bismuth, antimony, lead, and tin. Surfusion, moreover, is
not confined to pure metals, and I showed in 1893* that the eutectic
alloy in the bismuth-copper series presents a marked case of sur-
fusion.

FIG. 3.

In order to study surfusion, it is necessary to make the galvano-
meter, to which the thermo- junction is attached, very sensitive, and,
by suitable adjustment, it is easy to catch on the sensitised plate any
desired portion of the range of the spot of light. It is, however,
preferable to balance by a potentiometer the current which results
from the heating of the thermo-junction, and in this way to prevent
the mirror from swinging through a long range. The sensitiveness
of the instrument is but slightly diminished by the introduction
of the potentiometer. As the thernaya- junction cools down, the spot
of light from the galvanometer is simply made to traverse a short
distance many times, instead of a long range once. The sensitised

* "Second Report, Alloys Research Committee," 'Mech. Eng.,' 1893, Plate 32.

450 Dr. W. C. Roberts-Austen.

plate need only be exposed to the action of the spot of light at the
critical moment, when solidification or surfusion is known to be
imminent. A paper by my assistant, Mr. Stansfield, illustrating
the use of this method, will shortly be published by the Physical
Society.

A curve, traced by the aid of either of the sensitive methods
which have just been described, if it represents the surfusion of a
metal or alloy does not merely show a slight depression as in the
case of pure gold shown at a, fig. 3 : the slight depression becomes a
deep dip, (Plate 8, fig. 1, which represents the surfusion of gold).
In this case three curves were taken on one plate, the line ab
represents the heating and melting of gold, the horizontal portion
marking the actual melting of the metal. The lines cde and fgh,
on the other hand, represent successive coolings and solidifications
of the metal, surfusion occurring in both cases, the horizontal por-
tions at e and h representing the beginning of solidification of the
gold in each case. It is noteworthy that these successive points
of solidification differ by less than half a degree, the melting point of
the metal (the line ab) occupying a median position between them.
During the surfusion, the temperature of the metal fell about 2°
below its true freezing point. Pigs. 2 and 3, Plate 8, both represent
the surfusion of gold ; fig. 4, Plate 8, that of copper,* while fig. 5,
Plate 8, represents the surfusion of an alloy of antimony with 25 per
cent, of copper which freezes at 520°. It was selected as represent-
ing the highest temperature of surfusion which I have as yet
examined in the case of an alloy. Such a surfusion curve, in the
case of an alloy, may do much more than reveal the sudden release
of the latent heat of the fluid mass. The curve may present a com-
plicated record of modifications in molecular grouping occurring in
the brief space of time actually occupied by surfusion. This is
shown by the points d, e, in fig. 6, Plate 9, which represents the sur-
fusion of tin alloyed with 36'5 per cent, of lead. All the curves on
Plate 9 serve as bonds connecting the behaviour of alloys with that
of freezing solutions of salts.

The explanation of the existence of these points, d, e, is simple.
The freezing point curve of the lead-tin series is a very ordinary
type, and is shown in the accompanying diagram (fig. 4), and, as
regards the portion where the lines meet, full details are given on a
larger scale in fig. 5. It consists of two branches united at the point
where they join a horizontal line which represents the freezing of the

* Figs. 2, 3, 4 on Plate 8 were taken with an insensitive galvanometer and have
been enlarged by photography from the original plates. Fig. 5, Plate 8, and all the
curves on Plate 9 are given exactly as they were taken on the plate of the
recording instrument. The co-ordinates, as in the case of the figures 1 to 4, are
time and temperature.

On Surfusion in Metals and Alloys. 451

Fm. 4.

eutectic alloy of the lead-tin series. This alloy freezes at a constant
temperature (183°). The eutectic constitutes a fluid residual " liquor "
which is left after the excess of either lead or tin has fallen out as
the mass cools down. When, however, the tin is present in slight
excess of the amount required to constitute the entectic, the whole
mass of the alloy may remain fluid at temperatures below that at
which the eutectic would naturally freeze. It may even cool to a
temperature at which it can no longer maintain all its lead in solu-
tion, and some lead will, therefore, fall oat while surfusion is actually
taking place. This explains the existence of the point d, which marks
an arrest in the fall of temperature, in Plate 9, fig. 6 (on the line ab,
representing the fall of temperature during surfusion). Conversely,
when the surfusion is ended, the latent heat is released, and the
line bee represents the rise of temperature due to the release of latent
heat. There should also be on this line an indication of a retarda-
tion or arrest in the rise of temperature, because the lead which fell
out of solution (at the point d) has to be re-melted. This point of
arrest will be found at e.

In the same way, in fig. 7. Plate 9, which represents a fine case of
surfusion in the lead-tin alloy containing 64 per cent, of tin, there is
also a point at /, on the line gh, at which point the lead fell out of
solution during the surfusion. Fig. 8, Plate 9, represents the sur-
fusion of a lead-tin alloy containing 68 per cent, of tin. In this case
the tin is in large excess, and freezes first. In becoming solid, the
tin would have been represented by a horizontal line somewhere
about the point s, on the line ij, had not surfusion occurred, and
been terminated by the solidification of tin at &. This is followed
by the solidification of the eutectic mother liquor represented by
the line Im. This eutectic does not surfuse because the tin (the
metal in this alloy which is prone to surfuse) is already present in
the crystalline form.

In fig. 9, Plate 9, a similar case is represented, but a small, though
distinct, surfusion at the point n has been recorded. This surfusion

452

Dr. W. C. Roberts-Austen.

at n probably indicates that the lead in the entectic may surfuse
slightly even though the crystallisation of tin has begun.

By taking a series of lead-tin alloys which do not contain more than
2 or 3 per cent, of tin, in addition to the amount required to constitute
the eutectic (62 per cent, of tin), the temperatures at which the
lead begins to crystallise below 183°, can be measured. The results
are shown in the diagram, fig. 5. In it the co-ordinates are tem-

FIG. 5. — Freezing-point curves of lead-tin alloys.

185°-
X

Le&d

EutecC

c.

Percentage of\ Tin.

59

60

62

66

67

68

peratures and percentages of tin. Each alloy examined has, it will
be seen, 'at least two freezing points, and some appear to have three,
but in all the alloys one of the freezing points (the eutectic) is at
the constant temperature 183°. In the eutectic alloy (62 per cent, of
tin), theoretically these points, d, e, should coincide. In fig. 5 they
are not quite coincident, and this is due to the fact that the
lines AB, CD, drawn through the observed freezing points, are of
necessity somewhat lower than the ideal solubility curves. The
freezing points which lie below the horizontal or eutectic line were
recorded while surfusion occurred. For instance, take the alloy
containing 64 per cent, of tin, its initial freezing point would be at
a (185°), that of its eutectic at 6 (183°), while the third freezing
point, c (176°), is due, as has already been explained, to the falling
out of lead while the fluid mass was in the surf used condition. In
order to observe the uppermost of the three points (185% it is
necessary to stir the mass to prevent the possibility of snrfusion.
On the other hand, a record of the lowest freezing point can only be
obtained in a fluid mass which is perfectly tranquil. When lines
are drawn through all the points recorded it will be seen that the
line AB, representing the solidification of lead, extends far below the
horizontal line XX. It should be remembered that if the fluid mass

Roy.Soc.Proc. Vol.63, IVate 8

SURFUSION.

Fig. I. Gold

3°

Fig. 2. Gold

Fig. 3. Gold

10

Fig. 4. Copper.

o°

Fig. 5. Antimony
svith 25/' Copper.

Roberts-Austen^.

183

Roy. Soc. Proc. Vol. 63, Plate 9.

SUR FUSION.

180

175°

Fig. 6. 64 Tin, 36 Lead. Fig. 7. 63-5 Tin,36-5 Lead.

190'

185

190°

185°

Fig. 8. 68 Tin, 32 Lead. Fig. 9. 68-5 Tin, 31 5 Lead

On Surfusion in Metals and Alloys. 453

is stirred, the first point to be recorded will be the upper or tin point
(185°), followed by the eutectic point (183°). If the "alloy surfuses,
the first point recorded will be the lowest point (176°), followed in
turn by the eutectic. In general, therefore, only two freezing points
can be obtained in a single record.

In the case of salts the crossing of the curves of solubility has
already been observed by H. le Chatelier and by Dahms, but in the
case of alloys, experimental evidence has hitherto been wanting.
The silver-copper series presents many analogies to the lead-tin
series. Heycock and Neville*, in their excellent work on the com-
plete freezing point curves of many series of alloys, have calculated
what the ideal freezing point curve of the silver-copper series would
be, but the present paper affords, I believe, the first experimental
evidence as to the identity of the behaviour of saline solutions and
metallic alloys as regards selective surfusion.

Prolonged experience in these methods of manipulation may prove
that it is possible to effect the separation of a particular metal or
definite groups of metals by dropping in (during the surf usion of the
fluid mass) a fragment of the same metal or of the particular group
of the associated metals it is intended to separate. It is well known
that the introduction of a fragment of the same metal or of an iso-
morphous metal or alloy will determine its solidification. Such a
method may readily be employed in studying the surfusion of salts.
In the case of metals, so far as my own experiments go, the sur-
fused state is singularly unstable, for it may be disturbed even by
very slight tremors. It remains to be seen whether it is possible to
arrange the experiments in such a way as to maintain metals and
alloys for an indefinite time in Ostwald's meta-stable condition
which would need the presence of a particle of solid matter to
induce the solidification of the mass.

Ostwald applies to the change from liquid to solid the equation
which represents the gas-liquid change. In the former case there
are, however, the three phases, solid, liquid and gas, present, and a
complete expression of the change must take account of all three.
Thus during eurfusion the gas phase is in equilibrium with the liquid
phase, but when solidification has begun the gas phase must also be
in equilibrium with the solid phase. It is possible that the solidi-
fication of the mass may be started by crystals deposited directly
from its vapour so that solidification of a surfused metal may be
started by crystals from its own metallic atmosphere. The amount
of gas evolved by a solid metal is, of course, very small. Evidence
of the vaporization of metals at very moderate temperatures is not
wanting. Dema^yf showed in 1882 that in vacuo metals evaporate

* 'Phil. Trans.,' A, vol. 189 (1897), p. 25.
t ' Comptes Rendus,' 1882, vol. 95, p. 183.

454

Prof. D. Mendeleeff. Experimental

FIG. 6.

at much lower temperatures than they do at ordinary atmospheric
pressure. Pellat* pointed out that the proximity of the surface
of a metal to that of another metal in air, changes its electrical con-
dition, and he attributed this to vaporization of metals, showing
that even iron exerted an influence at a distance. Colsonf showed
that a photographic plate was affected by the vapour of certain
metals, notably by zinc, cadmium, and magnesium even through
porous septa. Dr. RussellJ in some recent and very interesting
experiments, was led to the conclusion that even so
infusible a metal as cobalt will by vaporization, affect
a photographic plate. In January, 1897, before hearing
of Dr. Russell's experiments, I began some experi-
ments with a view to ascertain whether metals, vapor-
ized in vacuo near the ordinary temperature, will
actually unite to form alloys. The arrangement is
shown in fig. 6. A and B are two discs of metal
with polished surfaces separated by a ring of glass, the
whole being enclosed in a vacuous tube which could be
heated in a water bath. I found that when cadmium
and silver were opposed for eight days at a tempera-
ture of 50° an appreciable deposit of a tinted cadmium-
silver alloy formed on the surface of the silver.
Cadmium must, therefore, have passed across the
interval between the discs A and B.

The results given in the present paper, reveal addi-
tional points of similarity between the behaviour of
alloys and that of ordinary saline solutions. I trust, therefore, that
it may be useful as a continuation of ray investigation on the
" Diffusion of Metals," which formed the subject of the Bakerian
Lecture of 1896.

" Experimental Investigations on the Oscillations of Balances."
By D. MENDELEEFF, For. Mem. U.S. Received June 9, —
Read June 9, 1898.

In the year 1893 the Central Chamber of Weights and Measures
(Glavnaya Palata Mer y Vesov) was created in St. Petersburg to act
as a Central Institution of the Empire for the verification of all
kinds of standard measures. Having been appointed Director of
the above-mentioned Institution, I was first of all occupied in

* 'Comptes Eendus,' 1882, vcl. 94-, p. 124.7; 1896, vol. 123, p. 104; and 1898,
vol. 126, p. 1338.

t Ibid., 1896, vol. 123, p. 49.

J 'Roy. Soc. Proc.,' 1897, vol. 61, p. 424, and ibid., vol. 63, p. 102, Bakerian
Lecture, 1898.

Investigations on the Oscillations of Balances. 455

making arrangements for accurate weighings, whereby some improve-
ments have been introduced in the usual methods ; a detailed
description will be found in the official report on the renewal of
Russian standards of measure and weight.

The results of the work show that with the balances of oar
Institution we are able to find the difference between two platinum-
iridium kilogram weights by one single weighing with an accuracy
of ± 0'02 milligram, and by a system of weighings to ± 0'002
milligram with a probable error of a few ten-thousandths of a
milligram.

We have a number of such balances, but those mostly used were
constructed by the well-known balance makers of Vienna, Rnprecht
and Nemetz; some important improvements have been made upon
these balances, especially in the direction of minimising the in-
fluence of the observer.

Having obtained such results in accurate weighings, I have used
them, not only in the comparison of standards of weight, but also in
an experimental research on the oscillations of a balance, hoping ta
collect some material, not only for an investigation of balances of
different systems and constructions in general, and of the friction of
the knife-edges, but especially to find the action of gravity and
moment of inertia on such a pendulum as is represented by an
accurate balance.

If we consider the time of one oscillation (from 30 to 60 seconds),
we find that our balances correspond to synchronous mathematical
pendulums of a length equal to 1000 — 3000 metres. The investiga-
tions in this direction are not yet completed, but one part of the
results obtained is now in print, and I would like to communicate an
abstract to the Fellows of the Royal Society.

Before going into the matter, I must explain that the many
hundreds of observations of the times of oscillation and the changes
in the scale-reading have been made by my friends and assistants,,
especially F. P. Zavadsky, Y. D. Sapogenikoff, and also by Messrs.
Dobrokhotoff, K. Egoroff, Miller, and Misses Ozarovskaya and
Endymionova. Their active co-operation has greatly contributed
to the success of the experiments, and I am much indebted to them
for verifying the numerous calculations which this research involves.

In the investigations mentioned, the following data were ob-
served : —

1. The readings of the scale, ZM, were observed through a tele-
scope after reflection from a mirror attached to the beam of the
balance, li is the first reading. One division of the scale corresponds
in the different balances to an angle of from 0'5 to 4 minutes. The
readings were taken by estimation to 0'05 division, which agrees
nearly with the probable error in Z.

456

Prof. D. MendeleefL Experimental

From every set of four to five readings the position of equilibrium
Ltt was deduced, and the amplitudes rn, by taking the differences
between ln and Lw. The difference between rn and ra+i is called in
what follows the decrement DM.

2. The time of the passage through the position of equilibrium,
Tn, was determined partly by the use of a chronographic watch,
partly by Marey's cylindrical chronograph, reductions having been
made to true astronomical mean time by comparisons with our
standard clock (Hohwii 31) controlled by signals from the Pulkova
Astronomical Observatory.

From the observed T» was deduced the mean duration (in seconds
of mean time) of one oscillation, i.e., from ltl to /„+,.

3. k, the number of milligrams corresponding to one division of
the scale.

4. e, the weight in milligrams of a litre of air inside the balance
case, according to readings of the thermometer (±0'003°), barometer
and Assman's psychrometer.

5. p, the weight of the load on each pan expressed in grams.

6. P, the weight of the whole moving mass of the balance and the
load in grams.

7. r, the volume of the load in millilitres. The same has an
influence on tn and DM, and we have examined the change of DM
and tn.

I. The Variation o/D and t depending on the value of one oscillation,
B« = lfi—lu+i, or amplitude, rn = (L« — Z«)( — l)*.*

The duration of one oscillation, all other conditions being constant
in all six examined balances without exception decreases with decreasing
oscillations or amplitudes. These variations are not only many times
greater than the errors of the readings, but many hundred times
surpass the corrections of the time of one oscillation, as deduced
from the usual formula for the reduction of the oscillations of a
pendulum to infinitely small amplitudes. The decrease of the time
of one oscillation in the most simple manner can be expressed in first
approximation by the formula

tn =

Therefore

where
and

log. nat.

Q = TO-TJ.

* r,t is very nearly equal to iR, but I prefer to give D and t in relation to r,,
because by this method the small errors in Ln disappear.

Investigations on the Oscillations of Balances. 457

More clearly visible is the decrease of D with decreasing amplitude
rn, and it is sufficient to observe four readings. The experimental
law of the decrease of D by first approximation can be represented
by the formula

Dre =

where d is the limit of the decrement in the case of infinitely small
amplitudes, and « a constant coefficient, which in all examined
balances varied between O0010 and O0002. Observations relating
to tn and Dn have been made in a very great number, and all of them
confirm the above given result.*

Therefore rn = - 12 - ,

or

where N = = — - ,

a — 1

and K = ]srH-— .

r0

Similar facts about t and D have been shortly mentioned before,f
but little notice of them has been taken. But in our very numerous
observations these facts stand out so clearly and beyond doubt, that
also in the ordinary simple pendulums we must suppose the existence
of similar deviations which only by their smallness have escaped the
attention of the observers. I have commenced the investigation of
a simple pendulum in this direction.

As D and t are varying with the amplitude r«, in what follows
D and t will be given for the case when r = 15 divisions, using the
signs D15 and £15.

II. Variation of Di6 and f15 icith varying load.

The time tu in all balances decreases with decreasing load and k.
(a) For one kind of balances very quickly, as, for instance,
Ruprecht's balance : —

1. 2. 3. 4.

p ...... 0 grms. 105 grms. 430 grins. 563 grms.

P ...... 1234 „ 1440 „ 2099 „ 3358 „

D15 ..... 1-0136 1-0180 1-0217 1-0244

tl5 ...... 27-3 sees. 28'5 sees. 38'3 sees. 48'2 sees.

* For details see the above mentioned Official Eeport.

t Cf. O. E. Meyer, 1871, Mercadier, 1876, T. Thiessec, 1886, and others.

458 Prof. D. Mendeleeff. Experimental

(6) For other balances considerably slower, as for the balance of
Nemetz : —

P 1147 grms. 1359 grms. 2213 grms. 3442 grms.

k 0-0192 ings. 0-0234 ings. 0'0481 mgs. 0'0670 mgs.

D15 1/0321 1-0392 1-0337 1-0313

tL5 30-5 sees. 32-8 sees. 33'3 sees. 33'7 sees.

The decrement D15 in some balances with increasing load (a)
increases as with the above-mentioned balance of Ruprecht, or (6)
decreases as with a balance of Collot designed to carry a load of
40 kilograms on each pan : —

P grm. _ 0

-. •_ . — v« -L. ^J. 4. O.

409'o grm.

P . . 29,879 grm. 38,069 grm. 46,259 grm. 62,640 grm. 95'402 grm.
D15.. 1-0459 1-0316 1-0259 1-0172 1-0103

tl5 . . 55-9 sees. 53'0 sees. 49'3 sees. 43'5 sees. 35'9 sees.

In this case the variation of D in relation to p corresponds in first
approximation to a hyperbola with an asymptote — 1 or (c), a combi-
nation of the preceding (a) and (6).

III. Variation of D15 and /15 with the Variation of the Sensibility of a

Balance I/A;.

If k increases, all other conditions being the same, then Di5 and £15
decrease as with the balance of Nemetz. (P = 2213 grams.)

k 0'034 mgrms. 0'055 mgrms.

tl5 37-3 sees. 30'6 sees.

D15 1-0363 1-0286

TV. Variation of the Time of one Oscillation depending upon the
Friction of the Knife-edges (Prisms) against the three Planes.

When the pans and the movable parts used for suspending them
are removed and the balance beam alone is oscillating, there is
friction only at the middle knife-edge, and the time of one oscillation
is shortened, as with the above mentioned balances of Collot and
Ruprecht ; for the latter we have found —

With pans but without

any load. Beam only.

P 1231 grms. 678 grms.

k 0-0310 mgrms. 0'0290 mgrms.

ti5 27-3 sees. 15'0 sees.

D15 1-013 1-007

If in the balance of Nemetz the pans are suspended from the beam,

Investigations on the Oscillations of Balances. 459

and we put in the place of the middle agate plane (the knife-edges
being of flint) planes of the same size but of different material, we
find a change in the time of the oscillation ; from thirty-two oscil-
lations in each case we have obtained the following mean results
(P = 2178 grams) :—

Material of the Time of one

middle plane. oscillation, £15. D15. Jc.

Hard steel 33'3 sees. 1'034 O043

Agate 327 „ 1*031 0'044

Copper 25-4 „ 1-065 0-071

Horn 18-2 „ 1-115 0'093

That is to say, the time of one oscillation in the last case is one-half
of that when an agate plane is used, although the load and the
position of the centre of gravity were the same in both cases.

Therefore the experiment shows a great dependence of the time of
one oscillation decrement and of the sensibility from the friction of
the knife-edges, although usually it is assumed that t and k do not
directly depend upon the friction. Further experiments are going
on, especially as regards the changes found in the value of the
decrement.*

Y. Variation of t and D depending upon the Dimensions of the
Horizontal Section of the Load.

If we put on the pans of the Ruprecht's balance two platinum-
iridium pounds (Russian) (cylinders of which the height and diameter
are equal and the weight 409*5 grams), we find k = 0'033 milligram,
t about 44'4 sees., and D about T0175 ; replacing these weights by
two plates of 914 square cm. section (of the same weight 409'5 grams),
we find t about 397 sees., and D about T0240.

VI. Variation of t and D with the Variation of the Volume of the

Load.
VII. Influence of the Variation of the Density of the Air e, and

VII I. The Inner Friction of the Gas in which the Oscillations are

going on.

The experiments will be continued and extended, and I hope to
obtain results which will throw more light on the little explored
regions of the oscillation of a balance considered as a physical
pendulum of peculiar properties.

Some results will probably be applicable to the ordinary physical
pendulum.

But, for the moment, I would not like to make any theoretical
generalisations.

* Vide Bessel and F. Baily, 1832, " Pendulum. Experiments."
VOL. LXllF. 2 M

460 Prof. A. W. Riicker and Mr. W. H. White.

" On the Determination of the Magnetic Susceptibility of Rocks."
By A. W. RUCKER, Sec. R.S., and W. H. WHITE, A.R.C.S.
Received July 6, 1898, and published during the vacation.

In the Report of the Magnetic Survey of the United Kingdom*
the question as to how far the local and regional magnetic dis-
turbances of the earth's field may he ascribed to the influence of
masses of magnetic rocks was discussed by Professors Riicker and
Thorpe.f

In a previous paperj a method for the determination of the
magnetic susceptibilities of rocks was given, together with values
for the specimens then examined. It was considered desirable to add
to this relatively small number of results so as to obtain a broader
basis for the development of the theory. Accordingly Sir Archibald
Geikie, F.R.S., Director- General of the Geological Survey, has been
good enough to supply us with a typical series of specimens of the
basic rocks of the country, and, after a complete overhauling of the
method originally adopted, we have measured the susceptibility of
sixty-eight of these new specimens of forty-five different rocks. The
earlier stages of the work were carried out by Mr. F. Fisher. A.R.C.S.,
who would, no doubt, have taken part in the whole had he not left
the college for an appointment elsewhere.

The principle of this method of determining the susceptibility of
small pieces of feebly magnetic materials is to compare the suscepti-
bility of the fragment with that of the displaced volume of liquids
of known susceptibility in which it is immersed.

In more detail, the method is as follows : —

(a) To measure the susceptibility of the magnetic liquids a tube
containing the liquid is introduced into one of two equal solenoids,
the effects of which on a small magnetometer destroy each other. In
these experiments a field of seven absolute units WAS employed. The
ratio of the deflection caused by the tube of liquid to that produced
by a measuring solenoid traversed by a small current, multiplied by
the computed constant of the instrument, gives the absolute sus-
ceptibility of the liquid.

The apparatus was figured and described on pp. 506 — 509, ' Roy.
Soc. Proc.,' vol. 48, 1890.

(6) The differences of susceptibility of rocks and liquids are
measured on the calibrated sonometer scale of a Hughes' induction
balance. Two tubes, filled with a liquid to the sufficient depth of
6 cm., are balanced, and the distance through which the compensator

* ' Phil. Trans.,' vol. 188, 1896-

f Vide pp. 637 — 647 and map 14.

T ' Boy. Soc. Proc.,' vol. 48, 1890, p. 505.

Determination of the Magnetic Susceptibility of Rocks. 461

lias to be moved to produce silence after the introduction of a small
piece of a rock into one of the tubes is noted. This is repeated with
liquids of different strengths. Then if a, b are the differences
observed between the rock of susceptibility x and two liquids of
susceptibility Jcl9 /^ respectively, we have

a : — x _

b K2 — x b — a

due regard being given to the signs of the differences.

The liquid employed was pure glycerine in which finely divided
magnetic oxide of iron was suspended, for no solutions of metallic
salts possess a susceptibility sufficiently high for our purpose. These
liquids were very carefully prepared, and in the light of the expe-
rience now gained it is desirable to add to the statements made in
the earlier paper on this point. Natural magnetite cannot be ground
'fine enough to remain long in suspension, though experiments in
which a coarsely powdered mixture of magnetite and manganese di-
oxide (minerals of about the same specific gravity) was shaken in
water and allowed to settle rapidly into a solid mass were fairly
successful.

Finally, the magnetic oxide was prepared artificially by adding
ammonia to a boiling solution of sulphate of iron of which one-half
had been oxidised by nitric acid. The black precipitate, dehydrated
by alcohol and dried at 100°, gives a friable dark brown mass about
one and a half times as magnetic as a good specimen of the powdered
mineral.

By grinding with glycerine between glass plates the oxide is
reduced to minute yellow scales. Glycerine mixtures made with this
substance give no indications of settling for forty-eight hours.

Numerous experiments with various suspensions of natural magne-
tite called attention to the fact that in a magnetic field the particles
rotated slowly to set their axes along the lines of force, thus giving a
fictitious susceptibility largely dependent on the permanent magneti-
sation of the grains of magnetite. With the artificial oxide this effect
is extremely small, but, to avoid it altogether, we prepared gelatinised
glycerine mixtures which at ordinary temperatures become solid.
In this state we repeatedly determined, firstly, their absolute sus-
ceptibility with the magnetometer apparatus, and, secondly, the
value in sonometer scale divisions of each balance tube filled with
the jelly. With these particular tubes one division = susceptibility
O0001075. The balance tubes being thus standardised, the absolute
magnetic value of a liquid is determined by the induction balance
under exactly the same conditions that hold during the tests of
rocks.

2 M 2

462 Prof. A. W. Riicker and Mr. W. H. White.

Sensitiveness and Accuracy.

The errors arising from various sources have been carefully con-
sidered. They naturally fall into two groups —

First. Errors in the determination of the primary standard of sus-
ceptibility, and affecting all results equally.

Second. Errors affecting individual specimens.

1. Under the first heading come the probable errors in the mag-
netometer constant and readings.

In the value of the constant there is an estimated probable error
of i 1 per cent. Combining with this several smaller errors due to-
temperature, variation of resistances, imperfect adjustment, external
magnetic disturbances, &c., we conclude that the susceptibility of
each standard jelly is subject to a probable error + 2 per cent. The
two jellies actually gave factors O000109 and O000106 (the error of
constant being the same in each case). Presumably the mean factor
0-0001075 is within ± 2 per cent, of the truth.

2. Errors in the values of individual rocks arise from the limited
sensitiveness of induction balance, telephone, and ear. The values
of the magnetic liquids are not appreciably affected by this, but it
becomes important in the case of rock specimens of small size and
feeble susceptibility.

In the earlier paper already referred to it was stated 0*00013 was
the lower limit to the range of measurement by the methods adopted
and experiments made since with magnetic and non- magnetic sub-
stances indicate about the same degree of accuracy. For moderate
susceptibilities, however, the accuracy now attained has been greater
than in the earlier work, and the errors cannot in most cases be much
greater than 1 per cent. The difference between two specimens taken
from the same rock is of course greater than this, as the composition
of the rocks is not uniform.

It is not necessary to give a detailed example of an experiment.
Suffice it to say that in a particular case the susceptibility of the
rock (No. 2) was determined by comparison (1) with liquids H and
D of susceptibilities 0-00074 and 0*00357, and (2) with liquids
H and C of susceptibilities 0*00074 and 0*00250. The results
obtained were 0'00164 and 0*00179, the mean being 0*00172.

The agreement of these two values is not particularly good, though
not exceeding the probable error given above.

For some unrecorded reason this specimen was tested again, and
gave—

From D and H', x = 0'00174

„ C and H', x = 0*00170

Mean value = 0*00172

The susceptibility was not in this case computed from mixtures D

Determination of the Magnetic Susceptibility of Rocks. 463

and C taken together, for that would introduce extrapolation, which
we avoid as much as possible.

In the case of the three specimens of susceptibilities greater than
O'Ol we are compelled to extrapolate beyond our strongest mixture,
and with the eighteen specimens below O'OOl we make our weakest
mixture a factor in the extrapolations.

In some instances (e.g., No. 45) there is a very distinct difference in
the strength of two pieces broken off the same hand specimen.

A few of the specimens used in the earlier investigations were
re-examined, and gave considerably larger susceptibilities than those
previously measured. This is probably due to an error in the deter-
minations of the absolute value of the susceptibilities of the liquids
employed, but in the case of any individual rock this error would not
exceed the difference often observed between two different fragments
of the same specimen. The fact also that the mean value now obtained
is almost exactly the same as that formerly given (viz., 0*00255 as
against 0*00245) justifies the conclusions based upon the use of this
or the smaller number (0*00160) which was used in many of the
calculations on the magnetic effects of basaltic rocks. The accuracy
of the absolute values now given has been tested by experiments on
ferric chloride. Although the susceptibility of this substance is
much smaller than that of most of the rocks, the result of our
measurements was in close accord with the means of values deduced
from the experiments of Quincke and Townsend.

464

Prof. A. W. Riicker and Mr. W. H. White.

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Detection and Localisation of Phosphorus in Tissues. 467

" On the Detection and Localisation of Phosphorus in Animal
and Vegetable Tissues." By A. B. MACALLUM, Associate-
Professor of Physiology, University of Toronto. Com-
municated by Professor S HERRING TON, F.R.S. Received
June 15,— Read June 16, 1898.

The distribution of phosphorus, like that of organic iron, in tissues,
is a question of considerable importance to the cytologist and it is
therefore necessary that the method of detection for this element,
should be a satisfactory one. There are difficulties, however, which
make the micro- chemical detection of phosphorus less easy than in
the case of iron, for there is no precipitate hoi ding phosphorus which,
under the microscope, gives as striking a demonstration of its
presence as ferrous sulphide does of iron. Ammonium phospho-
molybdate is, in the test-tube, a markedly coloured precipitate, but
when its constituent crystals are examined under the microscope the
colour observed counts for little. When also, as in tissues, the pre-
cipitate may be in a much more finely divided form, the canary -
yellow colour may be so faint that it is indistinguishable from the
yellow produced in the tissue by the action of the nitric acid in the
precipitating reagent, although Jolly* holds that the yellow colour of
the phospho-molybdate compound in the tissue cannot be simulated
by dilute nitric acid.

To get over these difficulties Lilienfeld and Montif used pyrogallol
to reduce the molybdic portion of the compound to the condition of a
lower oxide after they had, by washing the preparations in water,
removed the uncombined molybdate of ammonia from the tissues.
" Pyrogallol gives, in the test-tube with phospho-molybdic acid, an
intense colour varying from brown to black, whereby lower oxides of
molybdenum arise." J In speaking in another place of the action
of pyrogallol on the phospho-molybdate, they state that it gives, in
the parts of the preparations rich in phosphorus and according to
the quantity of the latter, " a yellow, brown, or black colour."

Ra9iborski§ points out that the reaction of pyrogallol with
ammonium phospho-molybdate in the test-tube is a green one, while
that produced with ammonium molybdate is a brown one. This
author further states that the green reaction is obtained in the
tissues of Euphorbia wherever crystals of ammonium phospho-

* "Contribution a 1'liistoire biologique des phosphates." 'Comptes Eendus,'
vol. 325, p. 538, 1897.

tJ" Ueber die mikro-cheniischen Localisation des Phosphors -in den Geweben,"
' Zeit. fur Physiol. Chemie,' vol. 17, p. 410, 1893.

£ Loc. cit., p. '411.

§ Vide a criticism of Lilienfeld and Monti's observations,^ Bot. Zeit.,' vol. 51,
p. 245, 1893.

468 Prof. A. B. Macallum. Detection and Localisation

molybdate occur, but a brown colour in other parts of an intensity
which varies according to the length of time during which the pre-
paration is washed, but if it is long and continuously treated with
water no brown colour appears. The brown, therefore, would be due
to molybdate of ammonium, and is no indication of the presence of
the phosphorus compound.

Heine* was unable to confirm Raciborski's observations regarding
the reaction produced by pyrogallol, but he found, using stannous
chloride as a reducing agent, that almost invariably a blue reaction
appeared, which may pass eventually into a dirty green colour. In
the test-tube also the reaction with the reducing agent is, according*
to the amount of the molybdate present, as well as to the strength
of acidity in the fluid, a green, brown, or blue one, whether phosphates
are present or not.

Pollacci,t using zinc chloride as a reducing reagent, found the
resulting colour range from dark blue to grey.

It is evident from the foregoing that there is error somewhere in
the observations which have been made on the action of pyrogallol
on ammonium phospho-molybdate, and it is obvious that, if Ra9i-
borski is right in his contention, then the results of the investigations
of Lilienfeld and Monti, relying as they did upon the "yellow, brown,
or black " reaction to indicate the presence of phosphorus, must be
wrong. As a number of observers, including Sherrington,* Gourlay,§
and Held, || have used the same method and the same criteria on
special tissue elements, it is therefore important to know the truth
concerning the results so obtained.

My observations confirm Raciborski's on the action of pyrogallol
on ammonium phospho-molybdate. When the former, in solution,
aqueous or ethereal, is allowed to act on the thoroughly washed
phospho-molybdate precipitate, the canary yellow of the latter is inva-
riably turned to green, even in the presence of nitric acid, and this
colour is maintained for a couple of hours, after which the precipi-
tate takes up slowly a darker shade, until at the end of twenty-four
hours it has a black colour with a faint shade of green in thin layers.
The form of the crystals, which are black, is maintained. When the

* " TJeber die Molybdansaure als mikroskopischer Eeagens," ' Zeit. fur Physiol.
Chemie,' vol. 22, p. 132, 1896-97.

f "Sulla distribuzione del fosforo nei tessuti vegetal!," 'Malpighia,' vol. 8, 1894;
Abstract in ' Zeit. fur Wiss. Mikrosk.,' vol. 11, p. 539.

J " Koto on some Changes in tbe Blood of tbe general Circulation consequent
upon certain Inflammations of acute and local character," ' Roy. Soc. Proc.,' vol. 55,
p. 161, 1894.

§ "Proteids of the Thyroid and Spleen," 'Journ. of Physiol.,' vol. 16, p. 23,
1894.

|j " Beitrage zur ^tructur der Nervenzellen und ihrer Fortsatze," ' Arch, fur Anat.
und Phys.,' Auat. Abthg., 1895, p. 396.

of Phosphorus in Animal and Vegetable Tissues. 4691

reducing reagent is allowed to act on a nitric acid solution of ammo-
nium molybdate, a brownish-black or black colour is produced, and an
amorphous precipitate may be formed, which, under the microscope
has a grey blue-black appearance, the fluid itself remaining brown,,
the colour being due to the oxidised pyrogallol. At the end of
twenty-four hours the amorphous elements are black, with or with-
out a brown shade. When, on the other hand, pyrogallol acts on
ammonium molybdate in solution the resulting colour is deep brown,,
very much like that of a saturated solution of Bismarck brown,
which is maintained at the end of twenty-four hours, but in no case
is a precipitate formed. It must be noted in this case that the colour
formed results immediately on the addition of the pyrogallol.

That what happens in the test-tube is what also obtains in tissues
may be shown readily. If one impregnates sections of tissue with
ammonium molybdate for an hour or more, these, thoroughly washed
and then treated with a pyrogallol solution, give a brown colour,,
which is most marked in the parts of the cells which have an affinity
for colouring matters. It is obvious that in the absence of nitric acid
there is no phospho-molybdate compound present, and yet the reducing
reagent shows that though repeated washings were resorted to, the
ammonium molybdate has not been removed. On the other hand,
when the tissues are placed in a nitric acid solution of ammonium
molybdate the results obtained are strikingly different. One may
conveniently demonstrate these by placing fresh Spirogyra threads in
the solution for from five to ten hours at a temperature of 35 — 40° C.>
then washing them quickly in distilled water and putting them in a
freshly prepared strong aqueous solution of pyrogallol. In ten
minutes the threads may be again washed, dehydrated, cleared in oil
of cedar, and mounted in balsam. Wherever in such preparations
one expects to find phosphorus, e.g., in the nuclei, it is demonstrated
by the green reaction. If the pyrogallol is allowed to acfc longer
than ten minutes it begins to stain the cells and to mark the green
more or less with a brown coloration, which distributes itself in them
as colouring matters generally do.

Perhaps the most striking way of demonstrating that the phospho-
molybdate is turned green and the molybdate brown by the action of
pyrogallol, is by impregnating portions of thin strips of writing paper
with a solution of sodic phosphate, drying them, and then submitting
them to the action of the nitric-molybdate solution, which gives them
a yellow colour. On now washing them in distilled water, and sub-
mitting them to the pyrogallol solution, the areas which are impreg-
nated with the phospho-molybdate become green in a few seconds,
while the parts which contain the molybdate solutioft alone become-
brown or yellowish -brown, and the contrast between the two reac-
tions thus appears marked.

470 Prof. A. B. Macallum. Detection and Localisation

The error at the base of the process adopted by Lilienfeld and
Monti has been the assumption that it is possible to wash out of
tissues all traces of the ammonium molybdate not combined with
phosphoric acid. I have found that when the stamens of Erythro-
nitim americanum, treated for twenty-four hours with the nitric-
molybdate solution, were washed with distilled water many times for
five months, they gave, at the end of that time, marked evidence of
the presence in them of ammonium molybdate. The addition of
stannous chloride brought out everywhere in such preparations the
appearance of the blue molybdic oxide, whereas, when such prepara-
tions were treated with pyrogallol solution, the phospho-molybdate
compound was found to be limited in its distribution. From animal
tissues also, I have found it impossible to remove by washing the
molybdate reagent. Indeed, one may succeed thus in removing the
phospho-molybdate compound rather than the other.

Heine* also has specially insisted on the strong affinity that cell
substances, those which contain phosphorus as well as those which
do not, have for ammonium molybdate, forming with the latter,
compounds insoluble in water or in dilute nitric acid solutions. He
prepared a quantity of histon, free from phosphorus compounds,
which, after treatment with the nitric-molybdate reagent and after
frequent washings, gave with stannous chloride abundant evidence of
the presence of ammonium molybdate.

One is consequently justified in concluding that the results of
Lilienfeld and Monti's observations, based as they are on the
*' yellow, brown, or black " reaction of the pyrogallol, are incorrect,
and that while the reaction may appear in phosphorus-holding
elements, it is simply a coincidence, and not an indication of the
presence of phosphorus.

The property of pyrogallol to form, in the reduction of the
molybdate and the phospho-molybdate compounds, a coloured sub-
stance which can be taken by cellular elements just in the same way
and to about the same extent that they take up other colouring
matters in solution, constitutes an objection to the use of this
reducing reagent. It is not possible to be certain in all cases in regard
to the length of time during which it is to be allowed to act, and,
consequently, a very faint green may be obscured by a light brown
reaction, resulting either from the oxidised pyrogallol or from the
reduced molybdate in the presence of traces of nitric acid.

In consequence of this objection, I endeavoured to find a reducing
reagent which would leave the molybdate compound, in the presence
of nitric acid, unaffected, while it would markedly react with the
phospho-molybdate, not only in the test-tube, but in tissues. Zinc

* "Ueber die Molybdansaure als mikroskopisches Eeagens," ' Zeit. fur Physiol.
Chetnie,' vol. 22, p. 132, 3896-97.

of Phosphorus in Animal and Vegetable Tissues. 471

chloride does this, but in an unsatisfactory way. It is very slow in
its action, and feeble in its reducing power. It gives a green reac-
tion with the phospho-molybdate compound, but none with the
molybdate in the presence of nitric acid. Stannous chloride reduces
both the compounds at once, forming the blue oxide of molybdenum,
and therefore it is, for the point in view, valueless. Ferrous sulphate
is also very slow in its action, and it has the disadvantage of giving*
a faint green colour to the tissue, independent of that which may be
produced in the phospho-molybdate compound.

The reagent which I found the most valuable from every point of
view is phenylhydraziii hydrochloride. This, in an aqueous solu-
tion of 1 — 4 per cent, strength, is certain in its action if it is freshly
prepared or not more more than two or three days old. It, in the
absence of alcohol or of a caustic alkali, makes a very marked dis-
tinction between the molybdate and the phospho-molybdate com-
pounds. It gives with the former, in powder, the brown oxide at
once, in solution, a brownish precipitate which may or may not
appear immediately, depending on the strength of the solution, but
in a solution of the molybdate containing nitric acid, e.g., that used
as the reagent for phosphoric acid, it has no apparent effect on the
molybdenum compound, although, in a few minutes, a soluble, red-
dish, aromatic compound may be formed in the solution. On the
other hand, with phospho-molybdates, either in the presence or in
the absence of ammonium molybdate, or nitric acid, or of both, it
gives at once the dark-green oxide of molybdenum. Examined
under the microscope, the crystals of the phospho-molybdate alone
are found to have the green colour, which, after an hour's action of
the phenylhydrazin, is so dark as to suggest, at first sight, black.
That this reaction depends upon the presence of phosphoric acid,
may be clearly shown by adding to a mixture of the reducing
reagent and of the nitric molybdate solution a quantity of phos-
phoric acid solution. Although the mixture will stand for several
minutes without any change other than the formation of a slightly
reddish solution, yet on the addition of the acid solution the dark-
green reaction appears immediately and markedly, sometimes accom-
panied by the formation of a blue-violet soluble compound. No
other acid exercises a like effect. Solutions of potassium hydrate
and sodic hydrate and alcohol, in a certain proportion, will call forth
in the mixture a greenish- blue or blue colour, which, in the case of
the alcohol preparation, fades out in twenty-four hours. In this
latter, the colour would appear to be due to the formation of an
aromatic compound, and not directly to an alteration in the molyb-
date. Nitric acid alone will produce, in a solution of phenylhydr-
azin, a reddish colour, and rarely also, when ammonium molybdate is
present, a blue-violet colour, which appears to be due to a phenylic

472 Prof. A. B. Macallum. Detection and Localisation

compound. What the conditions are, under which this coloured
compound is produced, have not been determined, but this reaction
cannot interfere with or confuse the results of the action of the
reducing reagent on the phospho-molybdate compound.

On the molybdate and phospho-molybdate compounds distributed
in animal and vegetable tissues, the phenylhydrazin hydrochloride
:acts as it does on these in the test-tube. It is not necessary to free
the tissue preparations from ammonium molybdate. They may be
placed for a minute or two in a dilute solution of nitric acid, after
which they are transferred to the reducing solution, which, in less
than two minutes, brings out the green colour where the phospho-
molybdate compound occurs, bat a faint yellow reaction where
ammonium molybdate alone is present. Instead of dilute nitric acid,
one may use distilled water, but it is not necessary to do even this,
for if the preparations are transferred directly to the reducing fluid
with but what may adhere to them of the nitric-molybdate solution,
the result is the same.

When the reducing fluid has been allowed to act for the proper
length of time the preparations are washed in distilled water, then
•dehydrated, cleared in oil of cedar, and mounted in balsam. Pre-
parations made in this way four months ago are now quite as satis-
factory as they were at first.

Reference to the other reagents and methods which have been
used is also necessary. The nitric-molybdate reagent was made by
dissolving one part of pure molybdic acid (Mo03) in four parts of
strong ammonia, and adding thereto, slowly, fifteen parts of nitric
acid, sp. gr. 1*2. The proportions indicate weights. The resulting
solution had a faint yellow tinge, and, after decantation from the
very slight sediment, remained free from a precipitate as long as
any of it was unused.

Fresh tissue material was used as well as that which had been
hardened in alcohol. The alcohol material is the best, for the nitric
acid, before it converts the phosphorus compounds in fresh tissue
elements into orthophosphoric acid, must dissolve a portion at least
of the phosphorus-holding proteids, and thus the phosphorus when
converted may not be distributed as intra vitam. I have, however,
used fresh material, wherever possible, to compare with that hard-
ened in alcohol. The latter offers advantages in the fixed form of
the elements, and in the preparation of thin sections which readily
permit the uniform action of the reagent as well as the extraction of
lecithin and inorganic phosphates.

The time during which the reagent was allowed to act on the pre-
parations varied from, ten minutes to twenty- four, and even, in some
cases, forty-eight hours. It was found that a temperature of 35° C.
favoured considerably the formation of the phospho-molybdate. The

of Phosphorus in Animal and Vegetable Tissues. 473

formation is a progressive one, the extent of the reaction appearing
to have some relation to the time employed. The inorganic phos-
phates are first affected, then lecithin, the organic phosphorus being
much more slowly converted into the orthophosphate.

According to Liebermann,* the phosphorus found in such com-
pounds as nuclein and nucleic acid is in the form of monometa-
phosphate, but Kosself has thrown doubt on the results on which
this view is based, and he claims that the facts point rather to the
•occurrence of other anhydrous forms of phosphoric acid in these
compounds. Jolly J has inferred from his experiments that in
organic compounds of phosphorus the latter does not occur in the
unoxidised metalloid (" metallo'idique non oxyde integre ") form.
Milroy§ has found that in the digestion of nuclein compounds with
trypsin, some of the phosphorus is set free as orthophosphoric acid,
but the greater part (89'08— 91/63 percent.), occurring in an organic
form, does not possess the characters of metaphosphoric acid, for its
solutions may be boiled a long time without producing an increase
in the amount of the ortho compound present.

As the nitric- molybdic reagent reacts only with the ortho form of
phosphoric acid, it is obvious that the organic phosphorus in the
tissues must be put in the condition of orthophoshoric acid. Lilienf eld
and Monti treated the fresh tissues with baryta water or sodic car-
bonate, in order to set the phosphorus free as phosphate, which was
then demonstrated as the phospho-molybdate ; but, as Liebermann ||
points out in the case of yeast nuclein, the baryta compound is only
after long boiling, or, after heating with acids, converted into the
orthophosphate. The action of the baryta must, in part at least, be
to change the structure of the elements, and it is not certain, there-
fore, that in all cases the ortho compound formed should be in the
structures where the phosphorus originally existed. This, and the
fact that the sodium compound first formed by sodic carbonate, being
soluble, may diffuse from its original situation, render this method
of doubtful value in localising phosphorus in tissue elements. These
observers, however, claim that the nitric acid in the molybdic
reagent has the property of gradually converting the phosphorus
compounds into the orthophosphate, and they allowed fresh prepara-

* "Nacbweis der Metapbospborsaure im Nuclein der Hefe," 'Arch, fiir die
gesam. Pbysiol.,' vol. 47, p. 155, 1890.

t " Ueber die Nucleinsaure," ' Verb. Pliysiol. Gresell. zu. Berlin,' ' Arch, fiir
Anat. und Physiol.,' Phys. Abth., 1893, p. 157.

£ " Kecherches sur le phospliore organique," ' Comptes Kendus,' vol. 126, p. 531,
1898.

§ " Ueber die Eiweiss-Verbindungen der Nucleinsaure und Tbymlnsaure und
ihre Beziebung zu den Nucle'inen und Paranucleinen," ' Zeit. fiir Pliysiol. Cbemie,'
vol. 22, p. 307, 1896-97.

II Loc. cit.

474 Prof. A. B. Macallum. Detection and Localisation

tions to remain a long time in this fluid for this purpose. I have, as
already stated, found that the long continued action of the reagent
has this result, and that the conversion is more marked if the reagent
is allowed to act at a slightly increased temperature. One cannot be
absolutely certain that the anhydrous forms of phosphoric acid when
liberated, and before being converted into orthophosphoric acid, da
not diffuse through the tissue elements, but in a number of experi-
ments made to decide this point, I ascertained that if such diffusion
did occur, it was in such minute amounts as to be unobservable. A
risk of diffusion is incurred when a tissue, very rich in orthophos-
phates, is acted on by the reagent. A part of the phosphoric acid
in this case, except in very thin sections, diffuses and forms a slight
deposit of phospho-molybdate crystals on the preparation. Prepara-
tions of renal tubules and the cat's placenta illustrate this well.

Owing to the abundance and general distribution of lecithin in
animal and vegetable tissues, it is necessary to extract this com-
pound from them in order to ascertain the distribution of the other
phosphorus compounds. Bitto* has shown that the extraction can
be regarded as complete only when the material, first treated with
ether, has been acted on by boiling ethyl alcohol thirty times, each
period of extraction lasting about ten minutes. Adopting this pro-
cess, I subjected samples from all the material used to extraction in
a Soxhlet apparatus for five hours, the condensed but still hot alcohol
being siphoned off every 6 — 10 minutes. This treatment is specially
necessary in the case of nerve tissues in which it makes a marked
difference in the phospho-molybdate reaction.

A much more difficult problem is that of the removal of the in-
organic phosphates from tissues. Jollyf used acetic acid of 20 per
cent, strength for this purpose, claiming that this fluid removes all
the phosphates except that of iron. It does indeed remove a large
part of them, but not those which may be in the nuclear elements.
In order, therefore, not to confuse the inorganic phosphorus with
that of organic combinations, I have always endeavoured to de-
termine in any given material what extent of molybdo-phosphate
reaction may be obtained in the first ten minutes after the nitric-
molybdate reagent is added. This reaction indicates whether the
tissues are rich or poor in inorganic phosphates, and it may be com-
pared with what may be obtained after a longer stay in the reagent,
any enhancement in the reaction thus demonstrating the phosphorus
of organic compounds.

* " Ueber die Bestimmung des Lecithingehaltes der Pflanzenbestandtheile,'
' Zeit. fur Physiol. Chemie,' vol. 19, p. 488, 1894.
f ' Comptes Keudus,' vol. 125, p. 538, 1897.

of Phosphorus in Animal and Vegetable Tissues. 475

Results of the Method.

I. General. — The chromatin of all nuclei gives, after eighteen
hours' treatment with the nitric-molybdate reagent a strong
phospho-molybdate reaction. This is so marked that the nuclei
appear under ordinary microscopic magnification as if they were
stained with a dark-green dye for the express purpose of showing
the chromatin structures. Even the finer fibrils constituting the
so-called reticulum are prominently brought out. This is well
illustrated in the nuclei of the epithelial cells of the skin, alimentary
tract, renal tubules, and olfactory region, and of the muscle fibres,
liver cells, testicular and ovarian cells, nerve cells (spinal cord),
pancreatic cells, connective tissue cells, and leucocytes of Meno-
branchus (Necturus) later alis and Amblystoma punctatum. In veget-
able cells, as shown in Erythronium americanum, the same result
was found. In brief, wherever true chromatin was found, there the
reaction for phosphorus was obtained. In the chromatin of the
mitotic loops in dividing animal and vegetable cells, no reaction
more marked than in the chromatin of the resting nuclei was in any
case obtained. This fact definitely contradicts the 'view of Lilien-
feld* that the chromosomes in mitosis are composed of nucleic acid
only, a view which Heine,t as a result of experiments in staining
with mixtures of dyes, also rejected. The phosphorus in nucleic
acid amounts to 9 — 10 per cent., but in nuclein it is 3 — 4 per cent.
If Lilienfeld's view is correct, then the reaction for phosphorus
in the chromosomes should be at least twice as marked as in resting
chromatin elements, taking volume for volume. The results
obtained by Lilienfeld in his staining experiments must be explained
on some other hypothesis than that which he adopted.

The eosinophilous nucleoli in animal and vegetable nuclei give a
strong reaction for phosphorus, but less marked than in the case of
the chromatin. On the other hand, the nucleolar elements in the
nucleus of the ovary of Erythronium which, as I have pointed out,J
are rich in " masked " iron, give a deep reaction for phosphorus.
A similar result was obtained in the nucleoli of the nuclei of the
embryo-sac of the same form, in the peripheral nucleoli of the
maturing ovarian ova of Menobranchus, in the nucleoli of Corallorhzza
multiftora and of tipirogyra, all rich also in " masked " iron. The

* " Ueber die Wahlverwandtschaft der Zellelmente zu gewissen Farbstoffen,"
'Verb. Berl. Physiol. Gesell.,' ' Arcb. fur Anat. und Phys.,' Phys. Abth. 1893,
p. 391.

f "Die Mikrocbemie der Mitose, zugleich eine Kritik mikrocbemischer Me-
thoden," ' Zeit. fur Physiol. Chemie,' vol. 21, p. 494, 1895-96.

J " On the Distribution of Assimilated Compounds of Iron, other than Haemo-
globin and Hsernatins, in Animal and Vegetable Cells," ' Quart. Journ. Micr. Sci.,'
vol. 38, p. 175, 1895.

VOL. LX1II. 2 N

476 Prof. A. B. Macallum. Detection and Localisation

nucleoli of the nerve cells in the spinal cord of Menobranchus and of
the ox and dog, give a deep reaction, but it is not uniform through-
out the nucleolus, portions of a granular form, giving a deeper
colour than the surrounding material.

In the cytoplasm of various cells the organic phosphorus present
is usually small in amount, and, unless inorganic phosphates are
present, the lecithin being extracted, the reaction is a very faint one.
In the cells of the nucellus and in the bast cells of Erythronium a
deeper reaction is obtainable in the cytoplasm ; and this appears to
be due to the presence of chromatin — at least in the case of the
nucellar cells. The cytoplasm of the latter is also, as I have pointed
out elsewhere, iron-holding. Other exceptions are found in the
pancreatic cells, liver cells, nerve cells, striated muscle fibres, in
maturing and mature ovarian ova of Amphibia, and in the spermato-
zoids of Ascaris. These exceptions are referred to at greater length
below.

In dividing cells the achromatic spindle gives no reaction for
phosphorus. This result is quite the opposite of that which Heine
obtained when he used stannous chloride as a reducing reagent after
the employment of the nitric-molybdate 'reagent. Heine advanced
the view that his result showed that the molybdic reagent could not
be depended on to indicate the presence of phosphorus in tissues. It
is rather to be interpreted as indicating that stannous chloride does
not distinguish between the molybdate and the phospho-molybdate
compounds.

In no case has the centrosome or centrosphere in animal and
vegetable cells given a reaction for phosphorus.

II. Special. — The zymogen granules in the pancreas of Diemyctylus,
from which the lecithin was thoroughly extracted, gave a deep reac-
tion for phosphorus after eighteen hours' treatment with the nitric-
molybdic reagent. The phosphorus apparently is less firmly bound
than is the case in the nuclear chromatin in the same cells, for the
reaction in the latter is slower in appearing. A very distinct but
less deep reaction was obtained also in the protoplasm in which the
granules lie, more especially in the part adjacent to the lumen, and a
marked reaction also was produced in the antecedent substance of
the zymogen, found usually in the outer or protoplasmic zone of the
cells. This substance, which I have named prozymogen,* contains
iron in a " masked " form, and it stains in every way like chromatin.
The presence of phosphorus, as well as of " masked " iron, seems to
indicate very clearly that it is a nucleo-proteid.

The demonstration that zymogen and prozymogen are pbosphorus-

* Loc. cit., p. 224 ; also " Contributions to the Morphology and Physiology of
the Cell," ' Trans. Can. Inst.,' vol. 1, p. 247, 1891.

of Phosphorus in Animal and Vegetable Tissues. 477

holding confirms the view which I advanced seven years ago,* that
both are primarily derived from the nuclear chromatin.

The deeper reaction for phosphorus which is obtained in that part
of the pancreatic cell immediately adjacent to the lumen, may be
due to ferments dissolved in the cytoplasm at this point or to a
phosphorus-holding substance derived from the zymogen at the same
time the ferments are formed.

A diffuse reaction for phosphorus, slow in appearing, was obtained
in the cytoplasm of liver cells of dog and man. These cells also
frequently contain abundance of inorganic phosphates whose presence
may render the demonstration of the organic compound difficult.

I have been unable to determine whether organic phosphorus com-
pounds are present in the cytoplasm of the renal cells, for in the dog
and human subject these cells are rich in inorganic phosphates which
are difficult to extract, and, consequently, obscure the reaction for
the other compounds if these occur here.

Mr. F. H. Scott, who is at present working on the micro-chemistry
of nerve cells, has found that Nissl's granules also give a distinct
reaction for phosphorus. He has also found that the substance
forming the granules does not digest in artificial gastric juice.
Mackenzief had previously found that these granules contain
" masked " iron. They stain like chromatin. These facts lead one
to conclude that the substance of the granules is a nucleo-proteid.

A feeble reaction for phosphorus has been obtained in the axis
cylinders of medullated nerves from which the lecithin was extracted.

In the muscle fibres from the chelae of the crayfish a deep phos-
phorus reaction was obtained in the dim bands and in the beadlets
which constitute Dobie's line, while no reaction occurred in the
lateral discs of Engelmann. The phosphorus-holding substance is
coterminous with the anisotropous element. The phosphorus demon-
strated is not due to presence of lecithin, for this was wholly ex-
tracted from the preparation before it was treated with the nitric-
molybdic reagent, and it was not due to inorganic phosphates, for the
reaction did not come out, except very feebly, during the first twenty
minutes.

In the striated muscle fibres of Amphibian larvae the iron-holding
substance appears to be also limited in its distribution, as it was
found only in the dim bands, £ Dobie's line giving no evidence of its
presence, perhaps because this structure in Amphibia is too minute
to permit a proper determination of this point. In my experiments
on crayfish muscle both the dim band and Dobie's line appear to give

* ' Trans. Can. Inst.,' vol. 1, p. 247, 1891.

f " Investigation in the Micro-chemistry of Nerve Cells," ' Brit. Assoc. Report,'
1897, p. 822.

I ' Quart. Journ. Micr. Sci.,' vol. 38, p. 220.

2 N 2

478 Prof. A. B. Macallum. Detection and Localisation

a reaction for " masked " iron, and thus in muscle this element and
phosphorus would seem to have the same distribution.

The matrix of cartilage in Menobranchus and the frog gives a
marked reaction for phosphorus, which seems in large part to be due
to inorganic phosphates, for it appears soon after the addition of the
nitric- molybdate reagent. The reaction in some specimens appears
in areas or zones about cartilage cells or groups of them, the areas
being separated by narrow zones in which no reaction was observed.

In the maturing and mature ovarian ova of Amphibia the cyto-
plasm is very rich in organic phosphorus, though not so much so as
the nucleus. As the yolk spherules form, the amount of phosphorus-
holding substance seems to lessen, possibly through its being taken
up by the spherules which, even when freed from traces of lecithin,
give a marked phospho-molybdate reaction in about six hours. It is
to be noted that these spherules are also iron-holding.

In the spermatozoids of Ascaris the organic phosphorus is, on
the whole, distributed as I have found the " masked " iron to be in
these structures.* The " nucleus " gave a deep phospho-molybdate
reaction, and a less marked reaction was obtained in the surround-
ing cytoplasm.

A diffuse but distinct reaction for phosphorus was obtained in
human chorionic villi of the seventeenth (?) day, and in the pla-
cental villi of the sixth week and third and sixth months. A
part of this reaction is due to inorganic phosphates, for it is
obtained to a certain extent in about ten minutes after the nitric-
molybdic reagent is added. The cat's placenta is very rich in
inorganic phosphates distributed throughout the tissue, but more
abundant in the deeper portions of the organ.

The colloid bodies of the thyroid are phosphorus-holding accord-
ing to Gourlay,t who relied in his experiments on Lilienfeld and
Monti's interpretation of the action of pyrogallol on the phospho-
molybdate compound. Through the kindness of Dr. J. H. Elliott,
I obtained an abundance of free colloid bodies of the ox, fixed in
alcohol, which, after extracting the lecithin, I fused in a platinum
cup with crystals of pure potassic nitrate. The mass, treated with
a quantity of the nitric-mo lybdate solution, became yellowish,
owing to the formation of the phospho-molybdate, the character-
istic crystals of which could be found under the microscope. The
reaction was not due to inorganic phosphates, for when thin sec-
tions of the ox's thyroid, freed from lecithin, were placed in the
reagent, the phospho-molybdate compound formed very slowly, and
the maximum reaction appeared only after eight hours. The pre-
sence of organic phosphorus in these elements does not, as Gourlay
* ' Quart. Journ. Micr. Sci.,' vol. 38, p. 229.
f Op. cit.

of Phosphorus in Animal and Vegetable Tissues. 479

believes, necessarily indicate the existence of a nucleo-proteid in
them, for Dr. Elliott has found that they digest in artificial gas-
tric juice, leaving no residue, which would not be the case were a
iiucleo- compound present.

The outer portions of the rods and cones in MenobrancJius and
Diemyctylus are rich in organic compounds of phosphorus. It is
more abundant in the rods than in the cones, and it is not due to
lecithin, for the retinae used were freed from the latter, nor is it
owing to the presence of inorganic compounds of phosphorus, for
the reaction is not obtainable during the first twenty minutes after
placing the organs in the nitric-molybdate solution, while it is a pro-
gressive one up to the sixth hour. The chromatin of the nuclei of
all the layers of the organ also gives the reaction.

The chromatophore in Spirogyra gives a weak phospho-molybdate
reaction, and it appears to be due to the presence of an organic com-
pound of phosphorus. A more marked reaction, however, is usually
found in the pyrenoids in the same genus, and also in those of (Edogo-
mum, Cladophora, and Conferva. In fresh specimens of Spirogyra,
taken during daylight and put into the nitric-molybdate reagent, the
pyrenoids appeared to give a stronger reaction than those of
specimens taken at ten o'clock at night. The reaction develops
slowly.

A diffuse reaction for phosphorus, slow in developing, was obtained
in the cytoplasm of Saccharomyces Ludwigii. In apparently normal
cells this may be the only reaction which will be obtained, but in
cells cultivated in the sap of the iron-wood tree a spherical body
occurs, at first sight like a nucleus, but frequently homogeneous, which
after about ten hours' treatment with the nitric-molybdate reagent
gives a reaction for phosphorus which may be very marked. This
body is in no sense a nucleus,* nor does the phospho-molybdate reac-
tion reveal any structure that corresponds to the latter. The fact
that the " masked " iron in these cells has a distribution parallel to
that of the organic phosphorus, also points distinctly to the absence
of a nucleus.

In Cyanophycese the " central body " always gives evidence of the
presence of organic phosphorus compounds. A stronger reaction
for phosphorus was obtained in the iron-holding, chromatin-like
granules which are to be found in the central body, or on its peri-
phery, in Tolypothrix and Oscillaria. The " cyanophycin " granules,
on the other hand, have not given any evidence of the presence of
organic phosphorus except in some few filaments of a preparation
of Oscillaria tennis, in which case a marked reaction was developed
in about an hour.

* I hare discussed the nature of this body, ' Quart. Joum. Micr. Sci.,' voL
38, p. 246.

FALMOUTH MAGNETIC OBSERVATORY.

IMPORTANT NOTE.

The observations made at this Observatory during 1897 have not
been printed at their usual place in the ' Proceedings,' as the Dip
observations for the period between October 8, 1895, and June 5,
1897, inclusive, have been found to be affected with certain errors.

OBITUARY NOTICES OF FELLOWS DECEASED.

Dr. HUBERT A. NEWTON, Professor of Mathematics in Yale Uni-
versity, whose death occurred on the 12th of August, 1896, was born
in 1830, on the 19th of March, at Sherburne, in the State of New
York. Both his parents were descended from ancestors who were
among the first British settlers in Connecticut. His father built the
Buffalo section of the Erie Canal, and it is recorded of his mother,
whose maiden name was Butler, that she was remarkable for her
mathematical attainments. He was one of ten children — seven sons
and three daughters.

At school the lad showed the aptitude for mathematics, and especi-
ally for geometry, which distinguished him throughout his life. He
entered Yale University at the age of 16, and graduated with the
highest mathematical honours in 1850. After his graduation he
continued for two and a half years more to devote himself to the
study of advanced mathematics, at the expiration of which time he
was, in 1853, appointed mathematical tutor in his university. Two
years later, at the unusually early age of 25, he was elected to the
full professorship, which he held through the rest of his life. In
1859 he married a daughter of the Rev. Joseph C. Stiles, who
survived her husband only three months, leaving two daughters.

Professor Newton's life was one of great industry. He was Associate
Editor of the ' American Journal of Science ' for twenty-seven years,
was a member and afterwards President of the Publishing Committee
of the Connecticut Academy of Arts and Sciences, and, in addition to
a long list of original memoirs, wrote articles for various cyclopaedias,
among others for the ' Encyclopaedia Britannica.' He took an active
parfc in promoting the introduction of metric measures into America,
and on the Board of Management of the Yale Observatory, which
owed its existence largely to the efforts and personal sacrifices of
Professor Newton, and of which he was for a long time Secretary
and for two years Director. He even took a part in municipal
affairs, and it is characteristic of the esteem in which he was held,
that it is recorded of him that he was elected alderman in a ward in
which the prevailing politics were in opposition to his own. In 1875
he presided over the Mathematical Section of the American Associa-
tion for the Advancement of Science, and in 1885 was President of
the Association. At an early period he received the honorary
degree of LL.D. from Michigan University, and in 1888 was

VOL. LXTII. b

11

awarded the Smith Gold Medal of the American National Academy
of Sciences, in recognition of his original work. In this country
he was elected a Foreign Member of the Royal Society, of the
Royal Astronomical Society, and of the Royal Society of Edinburgh.

The first of his papers seems to have been published in 1857, and
the last, " On the Relation of the Plane of Jupiter's Orbit to the
Mean Plane of 401 Minor Planets," in 1895. Between these dates
he published a long series of papers — usually from two to four each
year — covering a variety of subjects in mathematics, insurances, and
especially in that branch of astronomy which relates to meteors and
comets. These intimately connected phenomena early fixed his
attention. His first paper in reference to them was published in
1860, and a continuous succession, nearly fifty in all, have been the
result of his studies in this department of astronomy, and have con-
tributed largely to the immense advance which the astronomy of
meteors has made within the last forty years.

Two memoirs may be selected to illustrate how much modern
science owes to Professor Newton's industry and clear insight. The
first of these is his great memoir entitled " The Original Accounts of
the Displays in former times of the November Star-shower : together
with a Determination of the length of its Cycle, its Annual Period,
and the probable Orbit of the Group of Bodies round the Sun."
This memoir is published in the 'American Journal of Science ' (' Sil-
liman's Journal'), vols. 37 and 38 (1864). In it Professor Newton
makes use of the collections of ancient records of . star-showers
which had been brought together chiefly by the great industry of
French antiquarians and French astronomers. From these records
Professor Newton traces out all which refer to former visits to the
earth of that great swarm -of small bodies which are now known as
Leonids, but which, when first observed, radiated from the constella-
tion Cancer. In each case he cites the actual words of the original
records, of which there are usually several referring to each shower ;
and by a careful scrutiny of these he is able to fix, in many
instances with certainty, in others with more or less probability,
the actual date on which each shower occurred, and even in some
cases the hours during which it lasted. He thus discovered that we
possess records of thirteen showers of these meteors, of which
the earliest was in A.D. 902, and the last (at the time when he
wrote this memoir) was in 1833. To these we have now to add
the two great displays witnessed from Europe in 1866, and from
America in 1867.

By this careful scrutiny Professor Newton discovered several im-
portant facts — that the main swarm returns to the earth at intervals
of 33'25 years ; that on each return the earth encounters the dense
part of the swarm in two consecutive years ; that the date of the

Ill

principal showers has advanced at a nearly uniform rate from October
12, old style, which was the date in A.D. 902, to November 12, new
style, which was the date in 1833; and finally that the meteoric
orbit, whatever it is, is but little inclined to the ecliptic, and that the
motion of the meteors where they enter the earth's atmosphere is
nearly perpendicular to the direction of the sun.

Such being the facts, he proceeds to determine what inferences
may be drawn from them. From the dates of the showers he
ascertained that the node of the meteoric orbit — the point of its
intersection with the earth's orbit — has been since A.D. 902 advancing
in longitude nearly uniformly and at the average rate of 1 711'
annually. Allowing for the precession of the equinox, this is
equivalent to an advance of 29' in 33J years, measured from a fixed
point. This motion is accordingly direct, and Professor Newton
infers from this and from dynamical considerations that the motion
of the meteors in their orbit must be retrograde. He next considers
whether the meteoric orbit is wholly or only partly occupied by the
dense swarm of meteors. He first examines the hypothesis of an
elliptic orbit along which the meteors are distributed uniformly, and
which suffers such perturbations that it shifts about so as periodi-
cally to intersect the earth's orbit three times in a century. He
finds that this hypothesis must be rejected, because it involves an
apsidal motion so rapid as would require perturbing forces of an
intensity which we can satisfy ourselves do not exist. Accordingly
the meteors, leaving out of account the sporadic meteors which have
got separated from the main swarm, occupy only a portion of their
orbit. He next inquires what further can be learned about an orbit
of which the main swarm of meteors occupies only a portion ; and he
made the important discovery that only five orbits are compatible
with the observed return of the swarm to the earth at intervals of
33£ years. One of these five, accordingly, must be the true orbit.
Professor Newton determined the periodic times in these orbits, and
thus ascertained the axis major of each. All that was then wanting
to fix the precise form and position of each of the five orbits was a
sufficiently accurate determination of the "radiant point," i.e., of that
direction from which the meteors are seen to enter our atmosphere.
On account of Professor Newton's representations, efforts were made
by astronomers to make this observation with the utmost care during
the great meteoric showers of 1866 and 1867. This direction, when
corrected for the deflection of the meteors by the earth's attraction,
furnishes the position in space of one tangent to the orbit. Knowing
then the focus, the axis major, and the position and point of contact
of one tangent of each of the five orbits, its exact form and situation
in space can be ascertained. Thus the five orbits become fully
known; and the next step was to determine which of them is the

IV

actual orbit of the meteors. Professor Newton pointed out a line of
investigation by which it was possible that this discrimination might
be made. Bodies revolving round the sun in these several orbits
would be differently acted upon by the surrounding planets. The
perturbations in these five orbits would accordingly be different, and
would probably lead to a different rate of shift of the node of the
orbit along the plane of the ecliptic. If then, the perturbations in all
the five orbits can be so fully investigated that the rate of the shift
of the node in each can be computed, it will then be seen which of
the five computed amounts accords with that which Professor Newton
deduced from the observations, viz., an advance of 29' in 33| years, or
50*2" annually.

This was an invaluable suggestion, and the key to the complete solu-
tion of the problem, although there was at the time little hope that any
mathematician could be found competent to grapple with the difficulties
of the problem, which involved the investigation of a kind of per-
turbation which had never been attempted, viz., the perturbation by
a planet of a body revolving in the reverse direction in an orbit round
the sun, which is nearly coincident with the orbit of the planet.
Fortunately our own Professor J. Couch Adams was able to cope
with all the difficulties of the problem, and after five months' labour
found himself in a position to make known which of the five orbits
is the real orbit of the meteors. This marvellous achievement, how-
ever, would not have been possible without the discoveries that had
been made by Professor Newton : 1st, of the amount of the average
shift of the node ; 2nd, of the fact that the choice lay between five
orbits which he defined ; and 3rd, that a discrimination between
these was theoretically possible by the method afterwards success-
fully employed by Adams. Thus one of the most marvellous dis-
coveries of the century in dynamical astronomy is due to the
associated efforts of these two great men. Professor Newton in-
dicated the problem and pointed out how it was to be attacked, and
Professor Adams successfully grappled with its immense difficulty.

One other example of Professor Newton's contribution to our
knowledge of astronomy must here suffice. It may be treated briefly.
Most comets come into that portion of space which is occupied by
the solar system from great distances outside. Such comets move
either in parabolas, or in ellipses or hyperbolas which approximate to
parabolas. By an examination of the orbits of 247 comets, Professor
Newton establishes the fact that the planes of the orbits of these
non-periodic comets lie in all positions indifferently, and that such
comets exhibit no preponderance of direct over retrograde motion ;
whereas all the known periodic comets, which are about fifteen
in number, move in planes which are but moderately inclined to the
planes in which the principal planets move, and show such a marked

preponderance of direct over retrograde motion that only two have
their motion retrograde, viz., Halley's comet and the comet associated
with the great Leonid swarm of meteors.

Professor Newton succeeded in explaining this remarkable differ-
ence in behaviour of the two classes of comets. He shows that the
preponderance of small inclinations and the preponderance of direct
over retrograde motions would inevitably establish themselves amongst
comets of short period, on the supposition that each of these is a
comet of the other class which has at some time passed so close to a
planet that it was drawn aside from its original orbit.

Laplace had shown that if a comet passes close to a planet the
influence of the planet upon it may be found to a first approximation
by drawing a sphere of a certain size round the planet, and suppos-
ing that the comet has moved in a parabola round the sun, undis-
turbed by the planet, until it passes inside the sphere ; and that
while inside the sphere it moves in a hyperbola relatively to the
planet, attracted by the planet alone and unperturbed by the sun.
This is equivalent to supposing that as a first approximation we may
neglect the small difference between the direction and amount of
the sun's attraction upon the comet and planet while the former is
traversing the sphere from the point of its entrance into the sphere
to its point of exit.

Professor Newton points out that if the comet passes in front of
the planet as the planet advances along its orbit, then it will neces-
sarily accelerate the planet and thereby increase the planet's kinetic
energy. An equal amount of energy must be lost by the comet, of
which therefore the speed relatively to the sun decreases ; and there-
fore, if the orbit round the sun was a parabola before it entered the
sphere of the planet's influence, it will start along an ellipse after
emerging from that sphere. It thus becomes a member of the solar
system. On the other hand, if the comet pass behind the planet the
opposite effect is produced. The planet loses kinetic energy which
the comet gains, so that the comet when it extricates itself from the
sphere of the planet's influence, proceeds to move in a hyperbolic
orbit round the sun, past which it can make but one sweep, and will
then finally quit the solar system unless it encounter some other
planet.

Professor Newton deals specially with the planet Jupiter. It is
manifest that the only parabolic orbits which approach that planet
are to be found amongst those of which the perihelion lies as near
to the sun or nearer than the orbit of Jupiter. Professor Newton
shows that out of 1,000,000,000 comets traversing the solar system
in such orbits, about 839* -will have their orbits changed by that

* From this number a small deduction, perhaps of some dozen or so, has
to be made, to allow for those comets which actually collide with the planet.

VI

planet into elliptic orbits with a periodic time less than that of
Jupiter ; and by a further scrutiny of the dynamical conditions he
finds that moderate inclinations to the orbit of Jupiter will largely
preponderate among the comets so affected, and that direct motions
will preponderate over retrograde — thus explaining both these
observed facts of nature. This remarkable investigation will be
found in three papers, one in the ' American Journal of Science and
Arts,' 3rd Series, vol. 16 (1878), and the other two in the Reports
of the British Association for 1879 and 1891.

It is recorded of Professor Newton that he was noted in his own
university for the special pleasure which he took in all mathematical
investigations upon which geometrical insight could be made to
bear; and it must strike every student of Professor Newton's
published work that science in large measure owes the discoveries
which he made to the clearness of his geometrical and dynamical
conceptions, and to his facility in dealing with them.

This record ought not to close without referring to the circum-
stance that Professor Newton's original researches were the offspring
of his leisure. He regarded the duties of his professorship as those
of primary obligation upon him ; to these he at all times first gave
his full attention, and he seems to have possessed in a conspicuous
degree the powers of imparting to the students who had the good
fortune to be brought into contact with him a share of his own
enthusiastic love of mathematics. The motives which impelled
him to devote in addition the time which he felt to be at his own
disposal to a search into the secrets of nature, are illustrated by
words that he once used and which will find an echo in many
minds : — " To discover some new truth in nature, even though it
concerns the small things in the world, gives one of the purest
pleasures in human experience, and it gives joy to tell others of the
treasure found."

G. J. S.

RICHARD QUAIN, who died on March 13, 1898, at the age of 81, was
born on October 30, 1816, at Mallow-on-the-Blackwater, co. Cork, in
which county his family was one of the best known and most
respected. His father, John Quain, was a younger brother of
Richard Quain, of Ratheahy, whose sons, Jones and Richard, were
distinguished for their knowledge of anatomy and surgery, and John
Richard as a lawyer and judge in the Court of Queen's Bench. The
father of the subject of this notice married, in 1815, Mary, daughter
of Michael Burke, of Mallow, a member of an ancient and honoured
Irish family.

After early education at Cloyne, Richard Quain was apprenticed to
a medical practitioner in Limerick, where he acquired a knowledge of

Vll

many of the essentials of medical practice. In 1837 he entered the
University College of London, where his two consins were, the one
Demonstrator, the other Professor of Descriptive and Practical
Anatomy, from whom he seems to have received much sympathy and
valuable instruction. In this School of Medicine he studied with
much diligence, and his perseverance and keen powers of observation
obtained for him many distinctions.

In 1840 he graduated as M.B. of the University of London, obtain-
ing high honours in physiology, surger}', and midwifery. He con-
tinued to gain much experience in the appointments of "Resident
Surgeon or Physician at the hospital, and in 1842 he obtained the
degree of M.D. at the London University, receiving a gold medal and
certificate of special proficiency. He was soon afterwards elected a
Fellow of University College.

In 1848 he became Assistant Physician to the Hospital for Diseases
of the Chest, at Brompton, where he was associated with Drs. "Walsh,
Theophilus Thompson, and Cotton. In 1855 he was elected
Physician to this hospital, and his connection with it as a Consulting
Physician continued till the time of his death. He was also Con-
sulting Physician to the Seamen's Hospital at Greenwich, and to the
Consumption Hospital at Ventnor.

In 1851 Quain was elected a Fellow of the Royal College of
Physicians, and was identified with it till the time of his death ; for
he was a member of the Council, Censor, Lumleian Lecturer, Senior
Censor in 1877, Harveian Orator in 1885, and Vice- President in
1889. In 1888, on Sir William Jenner's retirement, he contested
the Presidency with Sir Andrew Clark, who, however, was elected,
though only by eight votes, in a large meeting.

In 1863 Quain was elected as Crown nominee of the Medical
Council, and continued in that post till his death. He was a moving
spirit in all the work of that body ; he was a member of many com-
mittees, serving with great distinction on the Pharmacopoeia Com-
mittee, which he seemed to make his special care, though most active
on several others. The services he rendered to this Council in the
various offices he held were most valuable, and the result was his
appointment, on the death of Mr. John Marshall in 1891, to the post
of President, to which he was unanimously re-elected on the expiry
of his first term of office in 1896, when he gave a valuable address,
clearly setting forth the questions in which the Council were in-
terested and his own practical and statesman- like view of the
methods of dealing with them. His predecessors in this important
office were Sir Benjamin Brodie, Joseph Henry Green, Sir George
Burrows, Sir George Edward Paget, Sir Henry Acland, and John
Marshall, none of them more devoted to the duties or more efficient
as President of the Council than himself.

Vlll

Sir Richard Quain's literary work and his researches into various
departments of medical science were, if not numerous, very important.
As a member of the Royal Commission appointed in 1865 to con-
sider the question of rinderpest or cattle plague, in which he was
associated with Lord Spencer, Lord Cranborne (now Marquess of
Salisbury), Lord Sherbrook, Dr. Lyon (now Lord) Playfair, Dr.
Edmund Parkes, and Dr. Bence Jones, he took a prominent part,
and was an earnest advocate of the stamping- out measures recom-
mended by the Commission, which, though strongly opposed at the
time, subsequent events have proved to have had the result of saving
large sums of money to the nation. He was a frequent contributor
to tlie * Saturday Review,' to the ' Lancet,' and other medical
journals ; whilst his treatise on " Fatty Degeneration of the Heart "
in the ' Transactions of the Medical and Chirurgical Society ' for
1850, expanded into a more elaborate article in his ' Dictionary of
Medicine ' some years later. His reports, in conjunction with the
staff of the Brompton Hospital, compiled for several years, of the
cases treated there ; some valuable contributions to the * Lancet ' of
1845 on Bright's disease, and to the ' Edinburgh Monthly Journal of
Medicine' on " Injuries of the Valves of the Heart," together with
his Lumleian Lectures given before the College of Physicians in 1872
on " Diseases of the Muscular Walls of the Heart " were, and are
still, regarded as authoritative writings.

But the great work with which Quain's name will ever be asso-
ciated is that of the 'Dictionary of Medicine,' on which the years
between 1875 and 1882 were spent, and which reappeared in a second
edition in 1894, enlarged and brought up to the knowledge of the
present time. For this cyclopedia of medical science he had care-
fully selected the contributors from the most eminent members of
the medical profession, whose communications were all revised and,
in some cases, modified by himself. His own contributions, espe-
cially those on " Fatty Degeneration of the Heart," " Angina
Pectoris," " Aneurism of the Heart," " Diseases of the Bronchial
Glands and General Remarks on Disease " are not the least valuable.
The work, in short, having filled a want long felt by the profession,
gained their entire confidence. To his able coadjutors, Dr. Frederick
Roberts, Dr. Mitchell Bruce, and Mr. John Harold he gave due
credit, and to their untiring devotion to the work its success is in
great part — as he himself would have acknowledged — to be attri-
buted.

Not the least interesting of Quain's contributions to medical litera-
ture was his Harveian Oration, delivered before the Royal College of
Physicians in 1885, in which he dealt eloquently with the healing art
in its historic and prophetic aspects.

In 1871 Dr. Quain was, for his eminence as a physician and for

Proc. Roy. Soc. LXIII. Front.

IX

scientific research into subjects connected with medicine, elected a
Fellow of the Royal Society. He was also a member of the Senate
of London University elected by the Queen, LL.D. of Edinburgh,
M.D. (Hon.) of Dublin and of the Royal University of Ireland, and
also a Fellow (Hon.) of the Royal College of Physicians of Ireland.
He was Fellow and President of both the Medical and Chirurgical
and the Pathological Societies, to the ' Transactions ' of which he
made several valuable contributions, and member and President of
the Harveian Society of London.

In 1890 he was appointed Physician Extraordinary to the Queen ;
-arid on New Year's Day, 1891, received the well-merited honour of a
baronetcy of the United Kingdom. This becomes extinct with his
-death, as Sir Richard Quain leaves no son. Isabella Agnes, Lady
*Quain, to whom he was married in 1854, was the only daughter of
Mr. George Wray, of Cleasby, Yorkshire she died, to his profound
•grief, a few months after the baronetcy had been conferred upon
him. Four daughters survive him.

Sir Richard Quain was much and justly esteemed by his profession
^aiid by the public. The kind-heartedness and geniality of his nature,
his amusing and epigrammatic conversation, his wide knowledge of
anen, and his unwearying sympathy and kindness, made him popular
not only with the younger as well as the older members of his pro-
fession, but with society generally, and in the Athenaeum and Garrick
Clubs, of which he was a well known member, whilst the bright and
•cheering effect of his presence in the sick room was always beneficial.
Few men have been more endowed with the faculty of endearing
themselves to their acquaintances, friends, and patients ; and few
*will be more regretted than the warm-hearted, genial Irishman and
.physician who has been taken from us, though not until advanced
.age had afforded the world full opportunity of appreciating his merits.

J. F.

JAMES JOSEPH SYLVESTER was born in London on September 3,
1814. He was the youngest son of Abraham Joseph, and had
five brothers and two sisters. His eldest brother early in life
established himself in America, and assumed the name of Sylvester
an example followed by all his brothers.

James went to Neumegen's well-known Jewish boarding school at
Highgate from the age of six until he was twelve. Mr. Neumegen, a
good mathematician, was strongly impressed by the boy's mathe-
matical talent, sedulously fostered it, and sent him at the age of
eleven to be tested by Dr. Olirithus Gregory at the Royal Military
Academy at Woolwich. Dr. Gregory, after examining in algebra,
jjronounced him to be possessed of great talents, and recommended
his mathematical tutor to pay great attention to his instruction. He

VOL. LXIII. C

subsequently went to Mr. Daniell's school at Islington for a year and
a half, where he came under Mr. Uownes. Thence to London Uni-
versity for five months, and in 1829, being then fifteen years of age,
he was sent to Liverpool. During this time Dr. Gregory kept up
his interest in the boy, for, in March, 1827, he wrote to his father
" Pray have the goodness to drop me a line so soon as your son
returns home that I may endeavour to fix a day in which I may
have the pleasure of seeing him here, and tracing his progress since
I saw him before."

At about this period he was for a short time a pupil of De Morgan.
At Liverpool he went to the Royal Institution,* which had itself
been founded in 1814, and its school in 1819. He lived with his
aunts, who had a school in Duke Street almost opposite Colquill
Street at the corner of Cornwallis Street, the house then commonly
known as " Morrell's Folly." One of his aunts was married to Elias
Moxley, one of three brothers who represented Barnard's Bank in
Lord Street. It appears from the school records that at a meeting
of proprietors on the 12th February, 1830, Thomas Langton, Esq.,
president, Sylvester was awarded the prize in the second class as the
result of the examination after the winter vacation. Other prize
winners were William Robertson. Sandbach, George Hancox, and
Murray Gladstone. In regard to the mathematical prize secured by
Sylvester, it is stated " In the Mathematical School one of the-
students, who had previous to entering it attained considerable pro-
ficiency, was so far advanced before the other scholars that he could
not be included in any class ; the first prize has without competition
been awarded to him." At the presentation of prizes, Mr. Langton
addressed him in the following words : — " In presenting to you,
James Sylvester, the youngest of the successful students, the first
prize for mathematical progress, let me caution you not to look upon
it as an occasion of triumph ; in receiving it you are giving a pledge
of your future diligence in the improvement of those natural abilities
with which a kind Providence has blessed you." The pupils of the
school numbered but thirty. The Rev. T. W. Peile, B.A., Fellow
of Trinity College, Cambridge (afterwards head master of Repton),
was head master; William Moore, B.A., of Trinity College, Dublin,,
second master ; and Mr. Marratt, mathematical master.

Few now remain who were with him at this school. Of these Sir
William Leece Drinkwater, until quite recently first deemster, Isle of
Man, perhaps knew him best, and I am indebted for many particulars
to a letter which he has been good enough to write me. It does not

* Mr. John Forslmw, who went to the school shortly after Sylvester left, writes-
that the Mechanics' Institution, originally founded in 1825, has since been trans-
formed into the Liverpool Institute, which must not be confused with the Liver-
pool Royal Institution standing about a quarter of a mile away in Colquill Street.

XI

appear that Sylvester was in all cases kindly treated by his school-
fellows. He was kind-hearted and brave, but rendered extraordinarily
irritable by the constant references, in a spirit of opposition, to his
Jewish extraction. He fought many battles in defence of his religion
with, it is said, greater courage than skill. On at least one occa-
sion he wished to fight a duel, being aware that with fists he was
no match for his opponent. At one time, considering that he was
treated with oppression by one of the under-masters, and being
directed, with the rest of the class, to write a theme on " Des-
potism," he composed an excellent essay, giving various instances,
both high and low, of the abuse of power, but reflecting unmistakably
upon the case of the under-master and himself. He concluded: —
" Thus we see that power begets tyranny, whether in the case of the
mightiest monarch or of the petty usher of a school or institution."
The severe punishment that followed, it is related, was endured with
great courage.

Soon after, Sylvester ran away from the school. He sailed from
Liverpool, and shortly found himself in the streets of Dublin with
but a few shillings in his pocket. This led to a singular incident.
As the boy was walking down Sackville Street he was observed
by an elderly gentleman who, his curiosity aroused, stopped and
inquired into his circumstances. A few moments' conversation
sufficed to reveal the fact that the boy was related to his wife, being,
in fact, her first cousin ! Thereupon he invited him to his house,,
entertained him, and finally sent him back to Liverpool. The gentle-
man was the Eight Hon. R. Keatinge, Judge in the Prerogative
Court of Ireland.

Being fully aware of his great knowledge of mathematics, he was
in the habit of proposing questions beyond the capacity of the
mathematical master. Before leaving he gained a prize of five
hundred dollars offered from the United States for the solution of a
certain question. It seems that a problem in combinations of great
difficulty had come under the notice of a certain D. V. Gregory, a
friend of Sylvester's elder brother in New York. On the advice
of the latter it was sent to the younger brother in Liverpool,
who almost immediately solved it. Its nature may be gathered
from the subjoined extracts from a letter addressed to him
a few years afterwards by D. V. Gregory : — " You solved my
problems, which I submitted without their knowledge, to the great
satisfaction of the Contractors of Lotteries in this country, and they
expressed, frequently, an exalted opinion of your mathematical attain-
ments in solving so intricate a subject. The inventor of the combi-
nation system himself was never able, as I learn, to package by
any mathematical rule . . . On account of their withdrawing
from business at the end of this year, the managers had prepared all

c 2

Xll

the necessary printing to complete their engagements, which print-
ing was done according to the making up of packages by boys in our
employ without any order or system or mathematical arrangement.
This was a tedious process, and required some months' labour and
consequent expense, and terminated in making a great number of
miscellaneous packages containing a disproportion of numbers. Had
your mathematical skill been known when they commenced business
in 1823, or even five years after, and had they adopted your arrange-
ment, they would have saved thousands of dollars expended by them
in preparing for the printer."

Sylvester was less than two years at the Liverpool Institution.
Afterwards he read for a few months with the Rev. Richard
Wilson, D.D. (late Fellow of St. John's College, Cambridge), and
then in 1831, at the age of seventeen, was entered at St. John's
College, Cambridge. He came out first in his first year ; but in
June, 1833, he became seriously ill and had to remain at home till
November. He then returned to the University, but again unfort-
unately became ill in February, 1834, and was obliged to remain at
home for nearly two years, not rejoining his college till January,

1836. In the following month he had the misfortune to break a
blood-vessel. On recovering, he pursued his studies till January,

1837, when he came out Second Wrangler. Griffin was Senior of
the year, and the list contained also the name of Green.

Being unwilling to sign the Thirty-nine Articles, he was unable to
take a degree, to obtain a Fellowship, or to compete for one of the
Smith's prizes.

At this time, on the occasion of laying the foundation stone of the
Mechanics' Institution, Mount Street, Liverpool, Sylvester presented
Lord Brougham with his pamphlet criticising Euclid's definition of
a straight line as length without breadth. He also composed his first
paper on " Fresnel's Optical Theory of Crystals," which appeared in
vol. 11 of the ' Philosophical Magazine ; ' and on the death of
Dr. Ritchie in the same year he became a candidate for the Chair of
Natural Philosophy in the London University College. The testi-
monials which he received for that occasion are evidence of the high
estimation in which he was held by tutors, examiners, and the other
scientific men with whom he had been brought into contact. The
list of his supporters includes the names of J. W. Heaviside (the
Senior Moderator in 1837), S. Earnshaw (Senior Examiner), George
Peacock, W. H. Miller, H. Philpot, J. Hymers, W. Hopkins, J. W.
Colenso, P. Kelland, J. Bowstead, J. Gumming, Frederick Thackeray,
James Hildyard, E. Bushby, Richard Wilson, J. Challis, and Olinthus
Gregory. Evidently all these were aware that a star of the first
magnitude was rising in the mathematical firmament. They seein
particularly to have noticed his analytical power and command of

Xlll

language, combined with originality and enthusiasm : qualities
which were conspicuous throughout all his subsequent scientific
career. It may be observed too that his interest was not confined to
the subject of his greatest predilection, for whilst at Cambridge he
attended regularly the chemical lectures of Gumming and the classi-
cal lectures of Bushby. This catholicity of taste, so early exhibited,
is doubtless one reason for the brightness and freshness with which,
throughout life, he could treat the dullest and most abstruse sub-
jects.

He was appointed to the Chair at University College in the session
1837-38, his friend De Morgan holding the Chair of Pure Mathe-
matics. He had some difficulty in drawing diagrams on the black-
board to illustrate his lectures. He was, in fact, never clever with
his hands, his handwriting in particular being very bad. A curious
instance of his constant desire to be thorough is brought to light by
the circumstance that for some time after taking up the professor-
ship he took lessons in drawing from the college drawing master ;
it is said, however, with small results. He published a remarkable
series of papers in the ' Philosophical Magazine,' vols. 13 to 17 »
principally on matters connected with the Theory of Equations'
Elimination, Sturm's Functions, &c., and laid the foundations of
the work with which his name will ever be associated. He retired
from University College in the session 1840-41, and immediately
afterwards accepted the Professorship of Mathematics in the Uni-
versity of Virginia. For the due appreciation of matters that will
be presently related, it should be stated that Sylvester at this period
felt strongly on the subject of slavery, and was, moreover, in the
habit of expressing himself thereon with great warmth. He was
indeed antagonistic to oppression in all its forms.

In the United States 1840 was the presidential year. It was the
eve of the introduction of new political methods. A new party was
formed, with the platform " Absolute and unqualified divorce of the
general government from slavery, and the restoration of equality of
rights among men." Feeling ran high, particularly in Virginia,
which was, later on, one of the Confederate States. Men of expe-
rience warned Sylvester that he should, on crossing the water, be
guarded in his expressions, and refrain from hotly stating his
opinions on the subject of slavery. He, however, determined to go,
and, after sitting for a full length portrait in oils, by Patten, of the
Royal Scottish Academy, now in possession of the family, he
embarked at Liverpool in a Cunard sailing vessel. The portrait
is evidently the work of a good painter, and is stated to be an
excellent likeness. It represents a young man of six and twenty, in
cap and gown, with dark, curly hair, and spectacles, seated, book in
hand, at a table.

XIV

Iii America he appears to have been at war with his surroundings
from the first. He found nothing sympathetic or inspiring, and the
cause of his exit from the country after six months arose from an
unfortunate incident with two students in his own class.

For two or three years after his return from Virginia he appears
to have done little work. As remarked by Dr. Halsted there were dis-
tinct periods of his life during which he felt much discouraged, and
seemed to have no heart for mathematical research.

In 1844 activity recommenced. He was elected to the post of
Actuary to the Legal and Equitable Life Assurance Company. This
was a responsible post, particularly at that time when, through mis-
management, one of the principal establishments in England had
been brought to the brink of ruin. He made constant valuations and
acted as check officer and scientific adviser to the directors of this
and some other companies for many years, residing for the greater
part of the time at 28, Lincoln's Inn Fields. He also accomplished
an extraordinary amount of mathematical research. A few titles of the
papers now published during this time will give a general idea of the
subjects which principally occupied his mind : — " On the Dialytic
Method of Elimination," " Elementary Researches on the Analysis of
Combinatorial Aggregation," " On a discovery in the Theory of
Numbers relative to the Equation Ax3 + By3 + Cz3 = Vxyz," "On the
Rotation of a Body about a Fixed Point," " Sketch of a Memoir on
Elimination, Transformation, and Canonical Forms," " On the
Principles of the Calculus of Forms," " On the Expressions for
the Quotients which appear in the Applications of Sturm's
Method to the discovery of the real Roots of an Equation." A
number of these papers refer to the subject now known as the
theory of invariants. It rose from its foundations, which had been
partially laid by Boole in 1844, under the strong hands of Cayley
and Sylvester. The conception of the problem and much of its
orderly development may be ascribed to the former, whilst nearly
the whole of the nomenclature and a great deal that is now recog-
nised as being of capital importance, both as regards initiation and
brilliant extension, is due to the latter. During the decade from
1845 he established his position as one of the foremost mathema-
ticians of Europe. He had the friendship and esteem of such men
on the continent of Europe as Lejeune-Dirichlet, Poncelet,
Borchardt, Duhamel, Bertrand, Serret, Hermite, Otto Hesse, Peters,
Kummer, Richelot, Joachimsthal, Chasles, with many of whom his
correspondence was frequent and voluminous. The contemporaries
in his own country — William Rowan Hamilton, Ivory, De Morgan,
Graves, MacCullagh, John Herschel, Babbage, Donkin, Challis,
Kelland, Salmon, William Thomson, and others — also testified on
occasions that they were aware a great mathematical genius had

XV

appeared in the ranks of scientific men, and was rapidly forcing his
way to the front.

In 1854, on the death of W. M. Christie, Sylvester was a candi-
date for the Professorship of Mathematics at the Royal Military
Academy at Woolwich. Christie had been professor since 1838, pre-
ceded by Gregory, 1821-38; Bonnycastle, 1807-21 ; Button, 1773-
1807; Cowley, 1761-1773; Simpson, 1743-1761.

Leading mathematicians at home and abroad testified to his
eminence and fitness for the appointment, but, as shown by the
subjoined letter, he was not successful : —

"From Lieut.-Colonel Portlock,

" Royal Military Academy, Woolwich,

" 1st August, 1854.
" Sir,

" I am directed by the Lieutenant- Governor, Major- General Lewis,
C.B., to notify to you that the Lieutenant- General of the Ordnance
has selected the Rev. Matthew O'Brien to succeed Mr. Christie as
Professor of Mathematics in this establishment.

" In making this notification, I feel it due to you to state that the
great weight of your claim as a candidate was felt and recognised.

" I have the honour to be,

" Sir,
" Your obedient servant,

" J. PORTLOCK,
" Lieut.-Col. Inspector."
" J. J. SYLVESTER, Esq."

Owing to the destructive fire of 1873 there is now no record of
this letter in the archives of the academy.

One cannot help recalling the rejection by the same establish-
ment, a century before, of the celebrated Benjamin Robins, Copley
medallist of the Royal Society, in favour of a Mr. Miiller.

Mr. O'Brien was known as a fair mathematician, and had pre-
viously held the post of Lecturer on Physical Science. He did not
take up the appointment, as a few months after his election his
death occurred, when Sylvester was elected. In the interval, how-
ever, he sought, but did not obtain, election to the vacant Pro-
fessorship of Geometry in Gresham College, and delivered a pro-
bationary lecture on geometry before the Gresham Committee on
December 4, 1854. The lecture was printed, and in the preface
occur the following characteristic remarks : — " The author will only
so far forestall the arrival of the period (quod longum absit !)
above alluded to by protesting against the use of the word
* practical ' as employed by an ingenious lecturer who succeeded him
at the desk. To discourse fluently on things of practice is no suffi-

XVI

cient evidence in itself of a practical mind. The first rale of prac-
tice is to do all things at the right time and in their proper places ;
to proportion the means to the ends and the ends to the means ;
above all to know what is possible, and to confine one's endeavours
within the limits of the feasible. The author allows, and has
habitually acted on the principle, that for the purpose of illustrating
lectures on geometry or any other abstract science, the lecturer
should lay his hands on the plough, the loom, the forge, the work-
shop, the mine, the sea, the stars, all things on earth or under heaven
which may help to arouse the attention or interest the imagination of
his auditors. But to profess to make the mere applications of a
science such as geometry the staple of the matter to be taught within
the walls of the college by the Gresham lecturer, to undertake to
comprise within a course of geometrical lectures systematic instruc-
tion in mechanics, astronomy and navigation, descriptive geometry,
engineering and drawing, the method of interpolation, the theory of
toothed wheels, the two kinds of perspective, machinery, mapping,
the art of shipbuilding, rules for cutting the best form of screws,,
and for enabling the citizens of London to qualify themselves for
being their own land surveyors, is a suggestion which, with all due
deference to its propounder, the author regards as one of the wildest
and most visionary which ever entered into the mind or issued from
the lips of a practical man." The address, composed at short notice,
is a powerful essay on geometrical science.

He took up the appointment of Professor of Mathematics and Lec-
turer in Natural Philosophy at the Royal Military Academy on the
15th September, 1855. In August, 1856, the lectureship was taken
over by the Professor of Practical Astronomy. The salary of the
appointment was £550 per annum combined with a Government
residence, medical attendance, and right of pasturage on the com-
mon. He occupied K Quarters, Woolwich Common, being the last of a
long list of residential professors. The house was commodious and
with a good garden. There he frequently entertained his friends from
London and distinguished foreign mathematicians. At the same
time he always had chambers in London in the neighbourhood
of the Athenaeum Club. These he had taken originally with
the intention to practise at the Bar, Scientifically this was a
glorious period for Sylvester, for, seated under a walnut tree
which grew in the centre of his garden, he made some of the
great discoveries with which his name will be for ever associated.
He wrote about eighty papers, and naturally it is only possible here
to glance at a few of those which are of fundamental importance.
During 1857-58 he published remarkable advances in the theory of
the Partition of Numbers, and in 1859 delivered seven lectures on
the subject at King's College, London. The outlines of these dis-

XV11

courses have this year (1897) been published for the first time by
the London Mathematical Society; they have attracted considerable
attention, and have already led to a remarkable paper by Mr. G. B.
Matthews, F.R.S.

In these researches Sylvester, standing upon the shoulders of
Cauchy, showed how to form an algebraical expression, involving
the imaginary roots of unity of different orders for the general co-
efficient in the associated generating function. It was a piece of
analytical skill that could only have proceeded from a rnind endowed
with imagination of the highest order.

In 1864 appeared in the 'Philosophical Transactions of the Royal!
Society ' a paper which will perhaps be considered his greatest
achievement. The title is " Algebraical Researches : containing a
Disquisition on Newton's Rule for the Discovery of Imaginary Roots, ,
and an allied Rule applicable to a particular class of Equations,
together with a complete Invariantive Determination of the Character
of the Roots of the General Equation of the Fifth Degree, &c.'r
Newton had given in the * Arithmetica Universalis ' a rule for dis-
covering an inferior limit to the number of imaginary roots in an
equation of any degree, but without proof or indication of method or
marshalling of evidence. Maclaurin, Campbell, Euler, and Waring
had also treated the question, but either failed to obtain a solution
or had fallen into serious error in the attempt. Sylvester's memoir,
described by him as a Trilogy, falls into three parts ; in the first he
establishes Newton's rule in regard to algebraical equations as far-
as the fifth degree inclusive ; in the second he obtains a rule appli-
cable to equations of the form

m being any positive integer, and a, b real coefficients ; in the third
he determines the absolute invariantive criteria for ascertaining the
exact number of real and imaginary roots appertaining to an equa-
tion of the fifth degree. Here, as in his treatment of the Partitions
of Numbers, he has frequently resorted to geometrical intuition. In
the present investigation every superlinear function is conceived to
be in association with a pencil of rays constructed in a definite
manner, and much of the argument is given in the language of the
geometry of pencils. During a conversation with the writer in the
last weeks of his life, Sylvester remarked as curious that notwith-
standing he had always considered the bent of his mind to be
rather analytical than geometrical, he found in nearly every case
that the solution of an analytical problem turned upon some quite
simple geometrical notion, and that he was never satisfied until he
could present the argument in geometrical language.

During these years he continually wrote upon the theory of inva -

xvm

riants, making important additions to it. The facility with which
he associated subjects the most diverse is evidenced by the titles of
some of his papers. Thus, "Thoughts on Inverse Orthogonal
Matrices, Simultaneous Sign Successions, and Tessellated Pavements
in two or more Colours, with. Applications to Newton's Rule, Orna-
mental Tile Work, and the Theory of Numbers ;" and " Astronomical
Prolusions, commencing with an Instantaneous Proof of Lambert's
and Euler's Theorems, and modulating through the Construction of
the Orbit of a Heavenly Body from two Heliocentric Distances,
the Subtended Chord, and the Periodic Time, and the Focal Theory
of Cartesian Ovals, into a Discussion of Motion in a Circle and its
Relation to Planetary Motion."

Particular events occurred during this period, which should be men-
tioned. About the year 1855 the ' Quarterly Journal of Mathematics '
was founded, and Sylvester, who took a chief part as Editor, was
anxious to have a suitable motto for the title page. He consulted
many of his-friends on the matter, De Morgan amongst others, and
finally, after much correspondence, selected the following : —

o 7t ovffca 7rpo<s fyeffti/, tTrHrrijfjii) TT/JO?
Kai ciavoia Trpos ciKaaiav CffTi.

This motto appeared upon the title-page during the whole time
that he was editor. The trouble he took in this matter is evidence
of his interest in things which may appear trivial to others, but
which, being important in his own eyes, he spared no effort to
accomplish successfully. His mathematical correspondence was of
wide range, and with De Morgan, Cay ley, Salmon, Hermite,
and Chasles he exchanged letters continuously. Cayley for a long
time resided at 2, Stone Buildings, Lincoln's Inn, and frequently
met Sylvester ; indeed, they were in the habit of taking long walks,
Cayley walking from London and Sylvester from Woolwich, meet-
ing near Lewisham. It is certain that some of the fruits of these long
•consultations are before the world to-day.

It cannot be said that he was a great success at Woolwich as a
teacher, being too far beyond his pupils who, for the most part,
regarded mathematics as an irksome duty. He had the reputation
of being eccentric and irritable. When not actually engaged in
teaching, the mind of Sylvester would occasionally become abstracted
from earthly affairs, and it is stated that on one occasion he suddenly
Jooked up from a paper in the hall of study and demanded of the
corporal on duty, " What year is it ? " An explosion of laughter in
the room led to a " scene," and the subsequent infliction of many
punishments upon the cadets.

The sight of Sylvester leaving his house pursued by his landlady
•carrying his collar and necktie is said to have been not an unusual

XIX

•one. He came into collision 011 more than one occasion with the
anthorities at the Academy and with the War Office. The culmina-
tion of these disputes was in 1870, when a War Office enactment,
abolishing the separate offices of Professor of Mathematics and Pro-
fessor of Mechanics, coupled with a limit of age for the new
appointment, forced him to retire. At first it was the intention to
make him leave without a pension, but, through the strenuous exer-
tions of his friends in and out of Parliament, it was finally deter-
mined to grant him an annuity calculated in some proportion to the
.salary he had been receiving. Sylvester was consulted as to the
assessment, and characteristically insisted that account should be
taken of the value to him of his government residence, medical
attendance, and right of pasturage on the common.

The pension was fixed at nearly £300 per annum. He had at least
•one enthusiastic fellow-worker during the time he was at the
establishment, Mr. (now Sir Andrew) Noble, who collaborated
with him in an important degree in the papers on the Theory of
Partitions.

The London Mathematical Society was founded in 1864, with De
Morgan as president, a post in which Sylvester succeeded him. In
June, 1865, he delivered a lecture in King's College, London, " On
an Elementary Proof and Generalisation of Sir Isaac Newton's
hitherto undemonstrated Rule for the Discovery of Imaginary Roots."

In 1869 he was President of the Mathematical and Physical Sec-
tion of the British Association for the Advancement of Science at
Exeter, the meeting being under the presidency of Stokes. His
address was largely a defence of mathematics from a statement that
had recently been made by Huxley in a ' Fortnightly Review ' article.
The latter had written, " Mathematics is that study which knows
nothing of observation, nothing of experiment, nothing of induction,
nothing of causation." Sylvester put in a powerful and eloquent
plea for the science as one unceasingly calling forth the faculties of
observation and comparison, and affording a boundless scope for the
exercise of the highest efforts of imagination and invention. Those
engaged in this science know the truth of Sylvester's words, but it
must be admitted that men of the highest eminence in other branches
of science frequently are unacquainted with the real nature of the
life work of a man like Sylvester, and of that inner world of thought
where the phenomena require as close attention as those which
present themselves in the outer physical world. Sylvester was a
philosopher, and was well able to take a survey of all the sciences.
While never underrating the importance of any of the recognised
divisions, he saw the intrinsic beauty of that which he loved beyond
all others, and no one was more competent to repel assaults upon it,
and, it may be added, no one could have been more successful in doing

XX

so. His enthusiasm, combined with his power over the English
language, made him an opponent worthy of any controversialist
living. The remainder of the address was on space conceptions, and
mathematics as the science of continuity. In one sentence he stated ~
"It is very common, not to say universal, with English writers, even
such authorised ones as Whewell, Lewes, or Herbert Spencer, to
refer to Kant's doctrine as affirming space to be a " form of thought,
or of the understanding." This led to an interesting controversy,
in the columns of ' Nature,' between G. H. Lewes, T. H. Huxleyr
C. M. Ingleby, G. Groom Robertson, W. H. Stanley Monck, and, of
course, Sylvester himself. The correspondence, with many critical
notes, will be found in an appendix to Sylvester's * Laws of Yerse "
(Longmans, Green and Co., 1870).

It is doubtful if Sylvester's reputation was ever higher than at this
time. The recognition of his great talents, the appreciation of his
transcendent genius, and the knowledge of the inspiring effect of
his personality were universal. Foreign scientific academies had
showered their honours upon him. Eminent men of all countries
knew him personally. A mere recital of his academic distinctions
would take up too much space. It can be found in any official list of
the Fellows of the Royal Society.

On leaving Woolwich Academy in 1870 he lived near the-
AthensBum, and for a few years his mathematical activity was in
abeyance. He had some idea of becoming a candidate for the
London School Board, and addressed several meetings of working-
men and other assemblages of electors in London. On these occa
sions he would occasionally sing to contribute to the merriment o
the evening. Such old English songs as " Simon the Cellarer " were
his favourite pieces. He also frequently recited at penny readings.
In * The Gentleman's Magazine ' for February, J 871, there appears
* The Ballad of Sir John de Courcy,' translated from the German by
Syzygeticus. He recited this versified translation at the New Quebec
Club and Institute at a reading on April 11, 1879.

In 1874 he entered the lists again. The occasion was the wonderful
discovery by Peaucellier of the straight line link-motion associated
with his name. Sylvester soon made additions and generalisations,
and finally gave a Friday evening discourse on the subject at the
Royal Institution of Great Britain. He showed amongst other-
things of great interest how to construct a link-work of seventy-
eight bars to solve the following problem : — " Required to construct
a link-work fixed or centred at two of its points, such that (when
the machine is set in motion) some other point or points thereii*
shall be compelled to move in the line of centres."

He wrote several papers on the subject, one of them bearing th&
characteristic title : — " Mode of construction and properties of a new

XXI

sort of lady's fan, and on the expression of the carves generated by
any given system whatever of link-work under the form of an
irreducible determinant."

He invented the plagiograph aliter skew pantigraph.

A synopsis only of the Royal Institution lecture was published.
The manuscript of the lecture as actually delivered is in the posses-
sion of George Bruce Halstead, of the University of Texas. Extracts
from it appear in the American journal ' Science,' of April 16, 1897,
from which it appears that it was characterised by that eloquence,
force, and poetical imagination with which students of Sylvester are
familiar.

In 1875 the Johns Hopkins University, at Baltimore, was founded,
And the Trustees sought the advice of the president, Daniel C. Gilman,
in the selection of the professorial staff. He replied " Enlist a great
mathematician and a distinguished Grecian ; your problem will be
solved. Such men can teach in a dwelling-house as well as in a
palace. Part of the apparatus they will bring; part we will furnish.
Other teachers will follow them." Joseph Henry also advised that
liberal salaries should be paid and the best men in the world secured.
He brought Sylvester's name prominently forward, and finally the
latter was offered the post of Professor of Mathematics. He de-
manded a higher salary than that offered, and this being granted
he finally stipulated that his travelling expenses and annual stipend
of 5000 dollars should be paid in gold, and then for the second time
left England to take up a professorship in the United States.

He found the conditions ideal. While not being overburdened
with rootine work, he was surrounded by able assistants and
talented pupils only too eager to aid him in his profound original
work or to catch^ inspiration from his lips. The mathematical
staff was indeed very strong, including men of such capacity as
Thomas Craig, W. E. Story, and Fabian Franklin. Sylvester's
first high class consisted of but one student, G. B. Halsted. This
gentleman, since well known in science, had the most beneficial
effect upon his master, for it was owing to his enthusiasm and per-
sistence that Sylvester's attention was again called to the Modern
Higher Algebra and the Theory of Invariants, and a fruitful crop of
new discoveries was almost the immediate result. Others, including
Franklin, Durfee, Ely, and Hammond in England joined in the inves-
tigations ; a school of mathematics was founded ; and the American
renaissance in mathematics was an accomplished fact.

Shortly after joining at Baltimore, the University founded the
* American Journal of Mathematics/ with Sylvester as editor ; and its
pages are evidence of the activity of the new school. In five years
Sylvester himself contributed thirty papers ; some of great length.
They are concerned chiefly with Modern Algebra, various points in

XXII

the Theory of Numbers, the Theory of Partitions, and Universal
Algebra. A splendid record for five years.

His address before the University, on Commemoration Day,
February 22, 1877, was most eloquent, and had an extraordinary
effect upon his hearers, amongst whom1 was James Russell
Lowell. After some remarks concerning the work of the University
and his own share therein, he discoursed upon the difficulty created
by the contending claims of teacher and investigator. He said that
the solution lay in the never-to-be-forgotten words, which had
recently been addressed to him, " The University desires from you
your best and highest work." He went on to observe on the re-
ligious and other disabilities under which students in English
universities had suffered, and brought into contrast the freedom in
American and German universities. He spoke with as much
warmth as power for, as he said, the subject came home to him.
For some time he held his audience spell-bound. His speech was never
liner than when under the influence of passion, and he abandoned
himself to a torrent of words. Those competent to form an opinion
believe that there was within him the material of a great orator.

The following remarks by some of his pupils in Baltimore are of in-
terest as showing his character and method of lecturing.

Dr. E. W. Davis states :—

" Sylvester's methods ! he had none. ' Three lectures will be
delivered on a New Universal Algebra,' he would say ; then ' the
course must be extended to twelve.' It did last all the rest of that
year. The following year the course was to be * Substitution Theory,.
by Netto.' We all got the text. He lectured about three times,
following the text closely, but stopping sharp at the end of the
hour. Then he began to think about Matrices again. ' I must give
one lecture a week on these,' he said. He could not confine himself
to the hour nor to the one lecture a week. Two weeks passed and
Netto was forgotten entirely and never mentioned again."

Mr. A. S. Hathaway says : —

" I can see him now, with his white beard and few locks of grey
hair, his forehead wrinkled o'er with thoughts, writing rapidly his
figures and formulas on the board, sometimes explaining as he wrote
while we, his listeners, caught the reflected sounds from the board..
But stop, something is not right; he pauses, his hand goes to his
forehead to help his thought ; he goes over the work again, em-
phasizes the leading points, and finally discovers his difficulty.
Perhaps it is some error in his figures, perhaps an oversight in the
reasoning. Sometimes, however, the difficulty is not elucidated, and
then there is not much to the rest of the lecture. But at the next
lecture we would hear of some new discovery that was the outcome
of that difficulty, and of some article for the journal that he had

XX111

begun. If a text-book had been taken up at the beginning, with the
intention of following it, that text-book was most likely doomed to
oblivion for the rest of the term, or until the class had been made
listeners to every new thought and principle that had sprung from
the laboratory of his mind, in consequence of that first difficulty.
Other difficulties would soon appear, so that no text-book could last
more than half the term. In this way the class listened to almost all
of the work that subsequently appeared in the journal. It seemed to
be the quality of his mind that he must adhere to one subject. He
would think about it, talk about it to his class, and finally write
about it for the journal. The merest accident might start him, but,
once started, every moment, every thought was given to it, and, as
much as possible, he read what others had done in the same direc-
tion ; but this last seemed to be his weak point ; he could not read
without meeting difficulties in the way of understanding the author.
Thus, often his own work reproduced what others had done, and he
did not find it out until too late."

Dr. W. P. Durfee, Professor of Mathematics at Hobart College,
Geneva, N.Y., has written : —

" His manner of lecturing was highly rhetorical and elocutionary.
When about to enunciate an important or remarkable statement he
would draw himself up till he stood on the very tips of his toes,
and in deep tones thunder out his sentences. He preached at us
at such times, and not infrequently he wound up by quoting a few
lines of poetry to impress upon us the importance of what he had
been declaring."

On the death of H. J. S. Smith, Sylvester was elected to the
Savilian Professorship of Geometry at Oxford, and in December,
1883, he finally left Baltimore to enter upon residence in New-
College, Oxford. At the time his mind was occupied with the
theory of a new species of invariants ; these are differential and of
more immediate application to geometry than those of pure algebra.
Sophus Lie had treated the whole subject of differential invariants
from a general point of view, and had given the various categories^,
but had made no attempt to develop the special case treated by
Sylvester. His notice appears to have been first attracted to the
subject by the well-known invariantive property of the differential
expression known as the Schwarzian Derivative, which in this country
had been studied by Cayley and Forsyth. The invariantive forms, he
quickly reached, he termed reciprocants, the name arising from the
fact that, from his original point of view, the expressions arrived at
were unchanged, to a factor pres, by the simple interchange of the
dependent and independent variables. Later he considered the
general linear and homographic transformations applied to similar
forms, and propounded an extensive theory of great geometrical

XXIV

importance. The lectures on the theory were delivered before the
University of Oxford din-ing the Hilary, Easter, and Michaelmas
terms of 1886, and subsequently published in the 'American Journal
of Mathematics.' The powerful weapon chiefly employed in the
research is due to the author himself, and is termed by him " the
method of infinitesimal variation.' In many details, and in the
orderly exposition, he was greatly assisted by James Hammond, M.A.,
and his fellow- workers in Oxford— E. B. Elliott, C. Landesdorf, and
L. J. Rogers — and others outside the University also made notable
contributions. In particular, L. J. Rogers made a capital discovery
in the Theory of Principiants (the name given to those reciprocants
which are invariantive in respect of the homographic substitutions),
which gave Sylvester material for most of the lectures in the latter
half of the series.

This theory was Sylvester's last great work. A masterly contraction
of TchebichefPs limits with regard to the number of primes occurring
between given numbers, and a tract upon Buffon's problem of the
needle, aVe the only other papers that need mention.

Failing health, frequently involving acute suffering, came upon
him when he was close upon eighty years of age. His high sense of
•the duties appertaining to his position would not allow him longer to
attempt actively to lead the mathematical studies of the University,
and in 1893 a deputy professor (Mr. W. Esson, F.R.S.) was
appointed.

The remaining three years witnessed the gradual breaking up of
an iron constitution. He lived for the most part with friends, or in
apartments in or near Mayfair, with occasional visits to Tunbridge
Wells, where lie stayed at the Spa Hotel. For some years he was
quite unable to think of mathematical subjects. He found that he
could no longer understand notes that he had made in former years,
-and this made him sad and dejected. About August, 1896, a revival
of energy and mental power took place, and till his death, March 15,
1897, he worked continuously at the Theory of Compound Partition, and
made an heroic attempt to prove or disprove the celebrated Goldbach-
Euler conjecture concerning the partition of every even number
into two primes. A fortnight before his death, while working in his
sitting-room at Hertford Street, Mayfair, he dropped his pen, and on
stooping to pick it up had a paralytic seizure. He never spoke
-again, and continuously sank until the end came.

He was a Royal Medallist of 1861, and the Copley Medallist of
1880.

While it is certain that he was one of the greatest mathematicians
of all time, it may be doubted whether he will take a place amongst
the small band who occupy absolutely the front line. His character
and temperament militated against continuity of thought. He would

XXV

be oppressed with a flood of ideas, which made it difficult for him to
suitably organise his researches. A theory, half composed, would
be forsaken that he might grapple with fresh imaginations. It is
certain that but a small fraction of his best work has been published
for the benefit of posterity. His genius and his greatness are not
properly represented by the memoirs which he has left. He had, to
some extent, the poetic faculty, and occasionally occupied himself
with the composition of sonnets, both in English and Latin.

He had literary power, and considerable knowledge of languages,
living and dead. He wrote French with ease, and conversed readily
in French, German, and Italian. He was acquainted with both
Latin and Greek, and when past seventy-five years of age read
' Athenaeus ' without a dictionary.

The writer, who had numerous opportunities of studying the cha-
racter of this illustrious man in the last years of his life, when he
was heroically battling against acute suffering, consequent upon the
infirmities of extreme old age, formed the conviction, that will never
be shaken, that his personal character was one of singular beauty,
and that its salient points were simplicity and honesty. Absolutely
and fearlessly honest from cradle to grave. Future generations will
mark with admiration the deep footprints he has left upon the sands
of time, but they will not be able to realise the effect which contact
with his great spirit had upon his contemporaries, who knew and
loved him. The superficial crust of eccentricities and slight faults
of temperament once pierced, and the kernel of his nature reached,
there was found a roundness and perfection of disposition that is not
often met with.

It cannot, perhaps, be said that his religious convictions were of a
kind which could be completely defined, but it is certain that he
believed in a Supreme Being, and in a future life, a life full of
enhanced intellectual power, and opportunities of intellectual growth.
The atheist will find nothing to give him satisfaction in the story of
this life, throughout which the faith was strong, and the conviction
that high principle should be paramount always present.

His last sufferings, extending over fifteen days, were borne with
fortitude.

So passed away one of the great spirits of the century.

" And he is gathered to the Kings of Thought."

P. A. M.

ALFRED Louis OLIVIER LE GRAND DBS CLOIZEAUX, who died on
May 6, 1897, in the eightieth year of his age, was born at Beauvais,
Departement de VOise, on October 17, 1817, and belonged to an old
magisterial family. He was educated at Paris, and the teacher to

VOL. LXI1I. d

XXVI

whom he went for instruction in "special mathematics " was the crys-
tallographer Levy : by him the young Des Cloizeaux was initiated
into the mysteries of that science, and was advised to enter upon the
mineralogical course then being given by Dufrenoy, at the ficole des
Mines. At that institution he later made the acquaintance of
Senarmont, through whose influence it was that he afterwards came
to devote himself so closely to the optical investigation of crystals.
His first paper dealt with the crystallisation of JEschynite, and
appeared in 1842 ; for the next half-century scarcely a year passed
without the issue of one or more papers recording the results of some
mineralogical research. In 1843 he was appointed Repetiteur at the
Ecole Centrale, and in 1857 Maitre des Conferences at the ficole
Normale ; from 1873 to 1876 he took the place of Delafosse at the
Sorbonne, and, on the retirement of that professor from his office at
the Paris Natural History Museum, Des Cloizeaux was appointed
(1876) to the Curatorship of that important mineral collection.
This office was particularly congenial to his tastes, for he was always
more happy in the laboratory than in the lecture-room ; he retained
it till 1892, when the rules of the Civil Service necessitated his
retirement at the age of seventy- five.

Though his life-work related almost wholly to the morphologj-
and optics of crystals, his inquiries were not limited to the examina-
tion of museum specimens ; he was much interested in modes of
origin and of occurrence, and in the geological relations of minerals ;
and he was always ready to seek an opportunity for seeing in its
native home any mineral to the determination of the characters of
which he had been devoting his attention. He went on two missions
to Iceland (1845-6) to investigate the mode of occurrence of the
well-known spar, about the scarcity of which physicists had already
become anxious, and he brought back from that island many
specimens of its minerals and rocks useful to him in his later
researches ; in 1868 he was sent on another special mission, on this
occasion to Norway, Sweden, and Russia ; and in the course of a long
life he found it practicable to visit all the more important mineral
localities of the Continent.

Two characteristics specially manifest in the work of Professor
Des Cloizeaux are accuracy and perseverance : he would spare no
pains to obtain the best values for the crystallographic constants of
the material he was investigating, while, a problem once started
upon, he would persist in its investigation for years, and return to it
again and again as new specimens or new methods became available.
For the first twelve or thirteen years his work was almost wholly
morphological, and consisted in the determination of the crystallo-
graphic constants of rare or new specimens and in the description of
the minerals associated together at new localities. To this epoch
belongs his memoir on the crystallisation of quartz ; to the thirty-

XXV11

five then known forms of this common mineral he added no fewer
that 135 new ones, many of them with complicated indices deter-
mined through the skilful use of zones : as to the remarkabla
stereographic projection prepared by Des Cloizeanx to illustrate the
observed forms of quartz, Professor Ruskin, speaking as an artist
and critic, has more than once expressed to the present writer his
great admiration of the "patient labour and entire accuracy of
workmanship " therein displayed.

From 1855 onwards his researches were mainly optical. It must
be remembered that at the time when M. Des Cloizeaux entered
upon the study of minerals, the instrumental appliances for the
optical examination of small crystals were in the rudimentary stage
of development, and were scarcely in use outside physical labora-
tories. He improved the polarising microscope of Norremberg,
giving it a new form, increasing the field of view, and making it a
convenient instrument for the examination of small sections.
Thereupon, not only did he entertain the colossal idea of determin-
ing the optical characters of all known crystals, whether natural or
artificial, but he began the work. He was soon led to emphasise
the importance of the " optical sign " for the discrimination of
minerals, and in his determination of the crystallographic system to
make constant use of the peculiarities of the distribution of colour
in the rings afforded by the sections of crystals in convergent
polarised light. In 1868 he published his observations of the
changes of optic axial angle resulting from changes of temperature.
In the case of orthoclase he found that, with a maximum tempera-
ture of 400° C. only temporary changes were induced, but that with
a temperature exceeding 700 — 800° permanent changes resulted.
Further, he pointed out that in the case of orthoclase from some
volcanic rocks this changed optical condition was already a character
of the specimens.

He was the discoverer of the circular polarisation of cinnabar,
and showed that it was seventeen times that of quartz. He was the
first to find a substance (strychnine sulphate) which rotates the
plane of polarisation, both in the crystallised state and in solution.
He showed that benzil circularly polarises when in crystals, but is
inactive when fused or in solution, and that, on the other hand,
camphors are active only when in solution. He was the first to
show, by optical characters, that there are ortho-rhombic members
of the epidote, pyroxene, and amphibole groups, and that the three
types of humite have characteristic optical features.

But more especially was he interested in the felspars, a group of
minerals of fundamental importance in the classification of rocks,
and to the investigation of which he gave more than twenty years of
his life. When he began this work it seemed unlikely that much
was left to be discovered in the case of so long known a group, and

xxvm

it was a veritable triumph for his method of work that he was able
to establish that there was a kind of potash-felspar distinct from
orthoclase ; it was anorthic instead of mono-symmetric in its sym-
metry, although approximating to the latter in the development of
its forms, and its optical characters, instead of being unstable, are
stable at all temperatures ; to this he applied the term microcline.
Indeed, it is to Des Cloizeaux that we owe our first precise know-
ledge of the optical characters of all the plagioclastic felspars, and
the determination presented constant difficulty to him by reason of
the lowness of the symmetry and the smallness and rarity of well-
developed crystals.

Much of his work has been incorporated in the treatise to which
he gave the modest title ' Manuel de Mineralogie,' and which is now
the standard book of reference for all that relates to the optics of
minerals. In its compactness and freedom from unnecessary words,
and indeed in its general characters, it bears a close resemblance to
(Brooke and) Miller's edition of ' Phillips' s Mineralogy '; and it is
interesting to know that at first he had intended merely to translate
that book, but was eventually compelled, by the extension of his
optical researches, to prepare an independent treatise. He adopted
the same general plan in giving a stereographic projection of the
observed faces for all the more important minerals, and elaborate
lists of measured and calculated angles useful in the recognition of
the substance. The preparation of this manual was a work of great
labour, and involved a vast amount of physical observation and
numerical calculation ; he made it a rule never to cite an angle with-
out verification by observation or recalculation. The first volume of
the manual was published in 1862 ; the first part of the second
volume in 1874, and the second part in 1893. The third and last
volume had not been issued at the time of his death, but is now
being prepared for publication by his successor at the Museum and
former pupil, Professor Lacroix.

Professor Des Cloizeaux was elected Metnbre de 1'Institut in
1869, and President of the Academic des Sciences in 1889. The
Royal Society awarded him the Bumford Medal in 1870, and
elected him a Foreign Member in 1875. He was a founder and the
first President (1878) of the Mineralogical Society of France, and
again served as its President eleven years later. Other Societies in
many parts of the world recognised the value of his scientific work
by enrolling him on the list of Honorary Members. An aged widow,
a widowed daughter (the Vicointesse d'Herouville), and three young-
grandchildren more especially mourn his loss ; but the memory oi
his kindly character and encouragement will long be treasured up
by those who were in any way associated with him.

L. F.

XXIX

By the death of JOHN CAERICK MOORE, science loses the last of that
band of ardent field-geologists who, during the first half of the present
century, did so much to investigate the underground structure of the
British Islands. Inspired by the example and animated by the
scientific principles of William Smith, they carried out in fuller detail
than was possible to their master, his great idea of delineating in
maps and sections the distribution and relations of the British strata
— guided everywhere by the organic remains which they contain.
But while this band of workers — which included such names as those
of Buckland, Conybeare, Webster, Mantell> Dixon, Lonsdale,
Sedgwick, Murchison, Fitton, De-la-Beche, Godwin- Austen, and
Phillips — were so deeply influenced by the teaching of William
Smith, yet they were seldom, with the exception of the last-mentioned,
personally instructed by him, but derived their knowledge of his
principles and methods at second hand from men like Richardson,
Townsend, and Farey, who were proud to act as the disciples and
interpreters of the distinguished "Father of English Geology."

John Carrick Moore came of a very famous stock. His grand-
father, Dr. John Moore, the friend and biographer of Smollett, was
the author of many works very famous in his day, of which the
novel " Zeluco " has been longest remembered. Three of the sons
of Dr. John Moore had very distinguished careers. The eldest
surviving son was General Sir John Moore, the hero of Corunna, and
a younger son was Admiral Sir Graham Moore, whose exploits on
the sea were scarely less notable than those of his elder brother in
the field. The father of John Carrick Moore was James Moore, the
second surviving son of Dr. John Moore, who studied medicine in
Edinburgh and London, and became one of the most distinguished
surgeons of his day. He was the friend of Jenner, and, as a well-
known writer in favour of vaccination, was appointed to succeed
that surgeon as director of vaccine establishments.

James Moore, who practised extensively for many years in.
London, was the author of many medical treatises and of a
biography of his brother, General Sir John Moore, published in 1833.
Having had bequeathed to him by a Mr. Carrick, a banker in
Glasgow, the estate of Corsewall, in Wigtownshire, near Stanraer
and Port Patrick, James Moore added to his own surname that of
Carrick. In 1825 James Carrick Moore retired from practice, and,
having built himself an excellent house upon his estate on the shores
of Loch Ryan, spent the remainder of his life there, dying in 1834
at the age of 71. On their mother's side, the Moores were
descended from Robert Simson, the celebrated geometrician.

John Carrick Moore was the second son of James Carrick Moore,
and was born in 1804. He went to Cambridge, and was educated
at Queen's College, proceeding to the degree of M.A., and devoting

XXX

much attention to mathematics and physics. Before the year 1838,
his attention seems to have been attracted by the rocks of the
Rhinns of Wigtownshire, near his residence, for we find that he was
in communication with Charles Lyell, who identified the fossils found
by him as graptolites. In the year named, he was elected a fellow
of the Geological Society.

In 1839 he traced out carefully the succession of strata along
the west shore of Loch Ryan, and in the following year a paper on
the subject was read by him to the Geological Society. In 1841,
Sedgwick, crossing from Ireland, paid a visit to Corsewall, and was
accompanied by John Carrick Moore in a tour through Ayrshire.
In September 1843, Lyell and his wife paid a visit to the same
hospitable dwelling, examining and confirming the accuracy of
Moore's sections. Much of Ly ell's time seems to have been spent
m studying the rain- and hail-prints, with the f ucoid- and crustacean-
markings on the shores of Loch Ryan, and he subsequently wrote to
Moore : " The Loch is a grand magazine of geological analogies —
tidal, littoral, conchological, sedimentary, &c.} which I envy you
having at your door." Subsequently to this visit, Lyell, under the
direction of Moore, visited the remarkable rocks in the neighbour-
hood of Ballantrae and bore testimony to the accuracy of his friend's
work there.

In 1846 we find John Carrick Moore had become so identified
with the work of the Geological Society, that he was elected Secre-
tary, and in the same year he became a member of the Geological
Society Club. He held the omce of Secretary for six years (1846-52),
when he was elected a Vice-President of the Society (1853-4),
resuming his post of Secretary in 1855 for one year. So active
indeed was Carrick Moore in the administration of the Geological
Society's affairs, that between 1846 and 1875 we find him absent from
the Council only in four years ; he was a Vice-President in 1862,
and again in 1864-5. In 1848 he read a more extended paper to the
Geological Society on the Silurian rocks of the Wigtownshire coast,
the fossils being described and figured by Salter. In 1856 and 1858
Moore communicated accounts of further observations on Wigtown-
shire geology to the Geological Society, while his general interest in
geological research was shown by the papers written by him in
1850 and in 1863, on fossils collected and sent home from San Domingo
by Mr. Heniker, and from Jamaica by Lucas Barrett. In 1849 wo
find him describing the Oligocene fossils found in the New
Forest.

John Carrick Moore was proposed as a Fellow of the Royal
Society in November, 1855, his nomination paper being signed first
by his friend Charles Lyell, while others who subscribed from
personal knowledge were Sedgwick, Murchison, Hopkins, Leonard

XXXI

Corner, and Faraday. He does not appear, however, to have ever
contributed a paper to the Society. By his patient labours in
studying the geology of Galloway he made valuable additions to
our knowledge of the stratified rocks of Britain, and he took a
distinguished place among the band of amateur workers — including
many landed proprietors, clergymen, soldiers, and doctors — to
whose painstaking and detailed work in the field English geology
owes so much. Among these men, John Carrick Moore was
always held in the highest esteem, and his time and energy were
ungrudgingly devoted alike to the advancement of his favourite
science by careful studies in the field, and to the promotion of the
interests of the Society identified with that science, during the parts
of the year when he resided in London.

In 1864, Andrew Ramsay spent a few days with John Carrick
Moore at Corsewall, mapping the peninsula, which terminates in
Corsewall Point, for the Geological Survey of Scotland. Of John
Carrick Moore's wide sympathies with all matters connected with
geology, and of the knowledge and ability with which, owing to his
early training at Cambridge, he was able to deal with those ques-
tions of physical geology demanding an acquaintance with mathe-
matical methods, we have abundant evidence. Between 1865 and 1867,
he sent a series of letters to the 'Philosophical Magazine,' dealing
in a very able and critical manner with Ramsay's theory of the
origin of lake-basins, and with Croll's theory of the cause of the
glacial period. These letters show that Moore had not forgotten bis
early training and had kept himself abreast of the science of the day
by his studies of physical questions ; and the substantial justice of his
criticisms has been abundantly shown by later researches. In 1875
he wrote to ' Nature,' pointing out a curious oversight of Humboldt
in his * Cosmos.'

In 1875, John Carrick Moore finally withdrew from the Council
of the Geological Society, upon which he had served so long and so
faithfully; and from that time forward he would seem to have ceased
to take any active part in scientific work. Few of the present genera-
tion of geologists can even recollect having seen the stately and
courteous gentleman, who was at one time so indefatigable in the
service of their society, and who had so frequently acted as one of
its officials. For nearly a quarter of a century after this withdrawal
from public activity, however, John Carrick Moore lived on, spending
his time between his seat in Wigtownshire and the house in Eaton
Square, where he died on February 10, 1898, at the great age of
94. His only son had pre-deceased him, but a daughter survives, the
estate passing to his nephew Colonel Sir David Carrick Buchanan,
of Drumpellier. Besides the Corsewall estate, John Carrick Moore
owned property in Kirkcudbrightshire and in England, and he was

VOL. LXIII. e

XXX11

a deputy-lieutenant of the county of Wigtownshire. He was not less
highly respected among the gentry of his county and the tenants of
his estate than in the circles of scientific society in London, in
which his presence was so long conspicuous.

J. W. J.

By the death of Baron FERDINAND vox MUELLER Australia has lost
a botanist and geographer who stood in the foremost rank of the
scientific men of the southern hemisphere. Ferdinand Jakob
Heinrich Mueller was born in 1825 at Rostock, of which town his
father was Commissioner of Customs. He was educated for the
medical profession at Kiel, where he graduated as Ph.D., after having
devoted much of his time as a student to the botany of Schleswig
and Holstein. Soon after attaining his majority he was seized with
an affection of the lungs, and having lost both parents from con-
sumption, he resolved to seek a more genial climate than that of North
Germany. He accordingly in 1847 left for Australia, to which country
there was then a considerable emigration from Germany. This was
not till after the completion of his first botanical essay, " Breviarium
Plantarum Ducatus Slesvicensis austro-occidentalis," which was not
published till 1853.* He had meanwhile been enrolled as a member
of the German Association for the Advancement of Science, which
had jnst been instituted by Oken.

After his arrival in Australia, Mueller acted for a short time as
assistant to a chemist in Adelaide, but being at once fascinated by
the interest and novelty of the flora, and having apparently some
private means, he gave himself up unreservedly to botanical and
geographical exploration. Leaving Adelaide, he crossed over to
Victoria in 1848, with the especial object of visiting the then all but
unknown Australian Alps, and connecting their flora with that of
Tasmania.

During the several years devoted to this object, he, alone and
unaided except by the contributions of a few generous friends, dis-
played great intrepidity as an explorer, penetrating into the interior
as far as the Murray River, in crossing which he nearly lost his life,
effecting the first triangulation of any part of the Victorian Alps, and
making extensive botanical collections abounding in novelty and in-
terest. At the same time he entered into correspondence with botanists
in Europe, sending them duplicates of his discoveries, and letters that
at once established his reputation as a young naturalist of great
attainments and astonishing powers of work.

Amongst his English correspondents was Sir W. Hooker, who
interested himself in his favour with Mr. Goulburn, then on the
point of leaving England as Lieutenant- Governor of Victoria, and who
* ' Flora,' vol. 36, p. 473.

XXX111

was desirous of having the vegetable resources of that Colony turned
to the best account. This resulted in the creation of a Department
of Botany in the public service of Victoria, and the appointment of
Mueller to its directorship.

In July, 1855. an expedition was organised at Sydney, with the
view of discovering the fate of Leichardt, who in 1847 had started
with a fully-equipped party in an endeavour to cross the continent
of Australia from east to west, but of whom no tidings had
been obtained for seven years. The search party was conducted
by Mr. A. C. (afterwards Sir Augustus) Gregory, and Mueller
was attached to it as botanist. Leaving Sydney in July of that
year in the barque " Monarch," the expedition sailed round the
north coast of Australia to the Victoria River, on the north-west
coast of the continent, and after spending a year in the exploration
of the sources of that river to the 17th degree of S. latitude, it
returned by land across the continent, skirting the Gulf of Carpen-
taria, and finally reaching the Darwin River in Queensland, in
November, 1856. During this remarkable journey nearly 20° of
unexplored country were traversed, and Mueller, who proved himself
an invaluable member of the expedition, obtained magnificent
collections of plants abounding in novelties, all carefully anno-
tated and in perfect condition. He subsequently made two other
extended land journeys, both in Western Australia, one in 1867,
when he explored the country between King George's Sound and the
Stirling Range; the other to the district east of Shark's Bay,
between the Murchison and Gascoigne Rivers.

In 1857 Mueller was appointed, at a suitable salary, Director of the
Melbourne Botanical Gardens, with herbarium, library and labora-
tory, which post he held till 1873, when he was deprived of the
administration of the gardens on the ground of his paying too
much attention to the introduction and cultivation of plants of
purely scientific interest, and too little to the aesthetic require-
ments of the Melbourne public, who desired to see their extensive
public grounds and garden rival in beauty the far-famed and no
less scientific establishment of the same kind at Adelaide in the
adjoining colony of South Australia. The fact is, that, great as
were Mueller's contributions in many ways to horticulture and
gardening in Australia and Europe, he was neither a practical
horticulturist nor a landscape gardener. On the occasion of his
demission the Colonial Government treated him with great
consideration and liberality, retaining his services as Government
botanist, with residence, un diminished salary, herbarium, library,
and laboratory.

The principal labours of Mueller may be classed under the two heads
of scientific and economic botany, especially forestry. It is impos-

XXXI V

sible here to give even a list of his scientific publications. Besides
104 papers registered in this Society's * Catalogue of Scientific
Papers,' he produced many works of exceptional value. Amongst
them the most notable are the ' Fragmenta Phytographise Australia^'
begun in 1858 and concluded in 1882, comprised in twelve
volumes, a work teeming with critical observations on Australian
plants which have been embodied by Bentham in the ' Flora
Australiensis ' ; the 'Eucalyptographia,' a revision of the Gum-trees
of Australia, with 129 illustrative plates ; the ' Iconography of
Australian Salsolaceous Plants,' with 90 plates ; the i AcaciaB and
their Allies,' with 130 plates ; the ' Myoporineoe,' with 74 ; and the
' Plants of Victoria,' a fragment, with 90. The descriptive portions
of these works leave nothing to be desired from a scientific point of
view, and the plates, all in quarto, abounding in anatomical analyses,
and executed altogether in the Colony, rival the best of those ot
European botanical works. In 1882 he published his ' Census of
Australian Plants,' in which the ranges of the species in the several
Colonies are given, thus initiating a botanical geography of the
continent. A second edition appeared in 1889.

From his first years in Australia, Mueller had entertained the
ambition of writing a Flora of that continent, and when the several
Colonial Governments acceded to the representations of Sir W.
Hooker that such a work should be undertaken, and had voted the
supplies for its execution, the name of Mueller was naturally the first
to be suggested as author. And he no doubt would have been selected
but for the fact that without constant access to the Australian
collections in the British Museum and at Kew it could not be accom-
plished. Mueller at once grasped the situation, and, hearing that
Bentham had been selected as author, he generously offered the use of
the whole of his materials, including that of his immense herbarium,
which he transmitted, by instalments, to Kew for the purpose. This
great work, commenced in 1863, was concluded in 1878, Mueller
loyally aiding by correspondence from beginning to end. Happily
his collections were returned to him without the loss of a specimen.

Of Mueller's works in economic botany the most important is
the ' Select Extra-tropical Plants, suitable for Industrial Culture or
Naturalisation in Australia.' This work is remarkable as a monu-
ment of botanical erudition, and, as an economic guide, it is unique of
its kind. It passed through many editions in the colony, has been
translated into four European languages, and been reprinted in thu
United States and in India. Besides being the means of introducing
many new cultures into Australia, Mueller's activity in sending seeds of
Australian plants, especially trees, all over the world, was phenomenal ;
and to him South Europe, Algeria, India, South and West Africa,
California, and South America, are greatly indebted for the groves of

XXXV

eucalypti, acacias and other trees that have done so much to adorn
their hills and plains, and even to improve their climates. To the
Royal Gardens, Museums, and Herbarium of Kew he was a perennial
contributor of botanical treasures, continuously for upwards of forty
years, often at considerable personal cost. Of this the magnificent
specimen of the great fern, Todea barbara, in the Temperate House,
is a conspicuous example. It is a native of gullies in the Victorian
Alps, from whence Mueller had it transported by wagon to Mel-
bourne, at his own expense, and shipped from thence, as a gift, to
Kew.

After botany the furtherance of geography was Mueller's constant
endeavour. He was President of the Geographical Society of
Victoria from its commencement, and author of valuable contribu-
tions to its Proceedings. According to a statement in the ' Melbourne
Argus,' it was he who induced Sir W. Macgregor to undertake the
exploration of New Guinea. He was an active member of Burke
and Will's Exploration Committee, and he ceaselessly urged upon
the attention of his fellow-colonists the importance of an Ant-
arctic Expedition. No better evidence could be adduced as to the
value attached to his own explorations and his efforts in the
advancement of geographical knowledge, than that at the Geo-
graphical Congress in Vienna he was one of the first to whom a
special vote of thanks was awarded for exceptional services in the
«ause of this science.

Amongst other instances of his devotion to science must be recorded
the fact that he was one of the three founders of the now flourishing
Royal Society of Victoria, which was established within a year of his
arrival in the colony. He was President of the Australian Associa-
tion for the Advancement of Science at its second session, held in
Melbourne in 1889, and was an active member of the Horticultural,
Acclimatisation, and various other societies of the Colony. It may
further be mentioned, that being a discriminating devotee of music,
he was chosen acting President of the Melbourne Liedertafel.

As with many other men of ardent disposition, Baron Mueller had
striking personalities. He is described as being of middle height
and frugal habits, dressing in black, wearing wooden shoes, and
boasting of never having been possessed of a watch or a looking-
glass. He was as voluble in conversation as indefatigable in
correspondence, asserting that the latter amounted to 3000 letters
annually, written with his own hand. His multitudinous titles, and
the decorations with which he delighted to adorn himself, were a
source of innocent gratification to him, especially his foreign heredi-
tary dignity of Baron, conferred on him by the King of Wurtem-
burg ; and the K.C.M.G. by Her Majesty on the announcement to
the Secretary of State for the Colonies of the completion of the

VOL. LXIJI. /

XXXVI

' Flora Australiensis.' He was generous to a fault, devoting the
whole of the savings from his official salary to science, charities,
and good works. He was elected a fellow of the Linnean Society
in 1859, of the Royal in 1861, and was awarded a Royal Medal
in 1888. Of other British and foreign scientific societies he
held 150 diplomas. He never married. His last and fatal illness
was an affection of the brain, of a fortnight's duration, due to
study, worry, insomnia, and a total abandonment of bodily exer-
cise. He died in his official residence in Melbourne, October 9th.
1896.

J. D. H.

INDEX TO VOL. LXIII.

Air, Gases in (Ramsay and Travers), 437; new Constituent of (E. and T.), 405.

Aleurone -layer, Function of, in Germination (Brown and Escombe), 3.

Alternate Currents, Aluminium- Carbon Cell as " Rectifier" of (Wilson), 329.

Aluminium Anode, apparent Great Resistance of Film on (Wilson), 329.

Amagat (Professor) admitted, 373.

Amnion, a Post-amniotic Canal in Sphenodon (Dendy), 440.

Animal Heat Calorimetry ; Relation to Oxygen Absorbed ; Effect of Food (Marcet

and Floris), 242.
Argon, Companions of (Ramsay and Travers), 437; Position among Elements

(Crookes), 408.
Ashworth (J. H.) The Stomodseum, Mesenterial Filaments, and Endoderm of

Xenia, 443.
Azores, Importance of Meteorological Observatories in (Prince of Monaco), 206.

Baker (Henry Frederick) elected, 373 ; admitted, 412.

Bakerian Lecture (Russell), 102.

Balances, Experimental Investigations on the Oscillations of (Mendeleeff), 454.

Barometers, Aneroid, Experiments on (Chree), 401.

Basaltic Rocks, Magnetic Susceptibility of (Riicker and White), 460.

Batten (F. E.) Experimental Observations on the Early Degenerative Changes in
the Sensory End Organs of Muscles, 61.

Blackman (Vernon H.) On the Cytological Features of Fertilisation and related

Phenomena in Pinus silvestris, L., 400 ; and Murray (G.) A Study of

the Phyto-Plankton of the Atlantic, 269.

Bose (Jagadis Chunder) On the Production of a " Dark Cross " in the Field of
Electromagnetic Radiation, 152 ; on the Rotation of Plane of Polarisation of
Electric Waves by a Twisted Structure. 146.

Brown (Ernest William) elected, 373.

Brown (Horace T.) and Escombe (F.) On the Depletion of the Endosperm of

Hordeum vulgare during Germination, 3.
Buchan (Alexander) elected, 373.

Burch (George J.) On Artificial Temporary Colour-blindness, with an Examina-
tion of the Colour Sensations of 109 Persons, 35; andGotch (F.) The

Electrical Response of Nerve to a single Stimulus investigated with the
Capillary Electrometer. Preliminary Communication, 300.

Calorimeter for the Human Body (Marcet), 232.

Candidates, List of, 1 ; recommended for Election, 212.

Capillary Electrometer, Electrical Changes in Nerve recorded by (Gotch and

Burch), 300.
Capstick (J. W.) On the Kathode Fall of Potential in Gases, 356.

VOL. LXIII. g

XXXV111

Cherry (T.) and Martin (C. J.) The Nature of the Antagonism between Toxins

and Antitoxins, 420.

Chlorophyll and Derivatives, Absorption Spectra of (Schunck), 389.
Chree (C.) Experiments on Aneroid Barometers at Kew Observatory and their

Discussion, 401.

Colour-blindness, Artificial Temporary (Burch), 35.
Combination Tones, Objective Reality of (Forsyth and Sowter), 396.
Contact Electricity of Metals affected by State of Surfaces, by Films, Exposure

and Temperature (Erskine-Murray), 113.
Crookes (Sir William) On the Position of Helium, Argon, and Krypton in the

Scheme of Elements, 408.
Croonian Lecture (Pfeffer), 93.

Crystallisation, Modifications by Mud (Raisin), 217.
Crystals of Cubic System with Cubic Cleavage, structure of (Sollas), 270, 286,

296.

Darwin (Francis) Observations on Stomata, 413.

Dendy (Arthur) Summary of the Principal Results obtained in a Study of the
Development of the Tuatara (Sphenodon punctatum), 440.

Des Cloizeaux (A. L. O. Le G.) Obituary Notice of, xxv.

Dewar (James) Makes Preliminary Communication on Liquefaction of Hydrogen
and Helium, 231 ; Preliminary Note on the Liquefaction of Hydrogen and

Helium, 256 ; and Fleming (J. A.) On the Magnetic Susceptibility of

Liquid Oxygen, 311.

Dilatometer, Compensated Interference (Tutton), 208.

Diphtheria — Chemical Nature of Antagonism of Toxins and Antitoxins (Martin
and Cherry), 420.

Dobbie (J. J.) and Gray (Andrew) On the Connection between the Elec-
trical Properties and the Chemical Composition of different kinds of
Glass, 38.

Echinoid Larvae, relations between Hybrid and Parent Forms of (Yernon), 228.

Eclipse, Solar, Preliminary Communications made, 205.

Edser (Edwin) An Extension of Maxwell's Electro-magnetic Theory of Light to
include Dispersion, Metallic Reflection, and allied Phenomena, 91, 374.

Election of Fellows, 373.

Electrical Discharge in Rarefied Gases ; Circumstances causing Intennittence
(Capstick), 356.

Electrodynamic Equations in Moving Media (Larmor), 365.

Electro-magnetic Radiation, production of a " Dark Cross " in Field of (Bose),
152.

Electro-magnetic Waves, Polarisation and Rotation of Polarisation Plane (Bose),
146.

Electrostriction (Larmor), 365.

Elements, Scheme of — Position of Argon, Helium, and Krypton (Crookes), 408.

Ellis (William) On the Relation between the Diurnal Range of Magnetic
Declination and Horizontal Force and the Period of Solar Spot Fre-
quency, 64.

Enamel of Elasmobranch Fishes, Structure and Development of (Tomes), 54.

Endoderm in Xenia, long Pseudopodia of (Ashworth), 443.

Endosperm, Relation of, to Embryo, Depletion, Yitality (Brown and Escombe), 3.

Erskine-Murray (J.) On Contact Electricity of Metals, 113.

'

XXXIX

Escombe (J.) and Brown (Horace T.) On the Depletion of the Endosperm of

Hordeum vulgare during Germination, 3.
Evolution, Mathematical Contributions to the Theory of. V. (Pearson), 417.

Falmouth Magnetic Observatory. Note concerning Dip Observations, 480.
Farmer (J. B.) and Waller (A. D.) Observations on the Action of Anaesthetics

on Vegetable and Animal Protoplasm, 213.
Fellows elected, 373.

Fern Prothalli, Apogamy and Development of Sporangia upon (Lang), 56.
FitzGerald (Q-eo. Fras.) Note on the Connection between the Faraday Rotation

of Plane of Polarisation and the Zeeman Change of Frequency of Light

Vibrations in a Magnetic Field, 31.
Fleming (J. A.) and Dewar (James) On the Magnetic Susceptibility of Liquid

Oxygen, 311.
Flicker, and Duration of Undiminished Impression on Retina, Fundamental Laws

of (Porter), 347.
Floris (R. B.) and Marcet (W.) An Experimental Enquiry into the Heat given

out by the Human Body, 242.
Forsyth (R. W.) and Sowter (R. J.) On Photographic Evidence of the Objective

Reality of Combination Tones, 396.
Functions, Algebraic, Connection with Automorphic (Whittaker), 267.

Germination of Hordeum vulgare, Depletion of Endosperm (Cytohydrolysis and
Starch-erosion) during (Brown and Escombe), 3.

Glass, Electrical Properties (Resistance and Specific Inductive Capacity) as related
to Chemical Composition (Gray and Dobbie), 38.

Crotch (F.) and Burch (Gr. J.) The Electrical Response of Nerve to a Single
Stimulus investigated with the Capillary Electrometer. Preliminary Com-
munication, 300.

Gray (Andrew) and Dobbie (J. J.) On the Connection between the Electrical
Properties and the Chemical Composition of different kinds of Glass, 38.

Haloid Salts of Alkalis and Silver, Structure of (Sollae), 270, 286,

Harmer (Sidney Frederic) elected, 373 ; admitted, 412.

Haswell (W.) admitted, 373.

Heat, dissipated by Platinum Surface (Petavel), 403 ; given out by Human Body,

Experimental Enquiry into (Marcet and Floris), 242.
Helium, Liquefaction of (Dewar), 256 ; Position among Elements (Crookes),

408.

Hybrid and Parent Forms of Echinoid Larvae (Vernon), 228.
Hydrogen, Liquefaction of (Dewar), 256.
Hysteresis and Permeability, Effect of Temperature on (Roget), 258.

Induction, Mutual, of a Circle and a Coaxial Helix (Jones), 192.
Iodide of Silver, Contraction with Rise of Temperature (Sollas), 286.

Jones (E. Taylor) On the Magnetic Deformation of Nickel, 44.

Jones (J. Viriamu) On the Calculation of the Coefficient of Mutual Induction
of a Circle and a Coaxial Helix, and of the Electromagnetic Force between a
Helical Current and a uniform coaxial circular cylindrical Current Sheet,
192.

Kathode Fall of Potential in Compound Gases ; Eelation to Fall in Elements

(Capstick), 356.

Kew Observatory Committee, Report of the, for the year 1897, 161.
Krypton, New Constituent of Air (Ramsay and Travers), 405; Position among

Elements (Crookes), 408.

Lang (William H.) On Apogamy and the Development of Sporangia upon Fern
Prothalli, 56.

Larmor (Joseph) Note on the Complete Scheme of Electrodynamic Equations
of a Moving Material Medium, and on Electrostriction, 365.

Light, Absorption in Dilute Solutions (Edser), 374 ; Extension of Maxwell's
Theory of, to include Dispersion, Metallic Reflection, and Allied Phenomena
(Edser), 91, 374; Relative Retardation of Components of a Stream of, when
passed through a Crystalline Plate (Walker) , 79 ; Velocity of, in Metals,
Connection with Electric Conductivity of Metal (Edser), 374.

Lister (Arthur) elected, 373; admitted, 412.

Macallum (A. B.) On the Detection and Localisation of Phosphorus in Animal

and Vegetable Tissues, 467.

McMahon (Lieut.-Qen. C. A.) elected, 373 ; admitted, 412.
Magnetic Deformation in Nickel, Influence of Temperature on Change of, with

Time (Jones), 44.
Magnetic Field, Modifications of Spectra of Iron and other Substances produced by

(Preston), 26.

Magnetic Properties of Iron, effects of heating on (Roget), 258.
Magnetic Range (Diurnal), and Period of Sunspot Frequency, relation between

(Ellis), 64.
Magnetic Susceptibility of Liquid Oxygen (Fleming and Dewar), 311 ;

of Rocks in England and Ireland (Riicker and White), 460.
Magnetism and Light ; Zeeman Effect and Faraday Rotation of Polarisation Plane

(FitzGerald), 31.
Marcet (William) A Calorimeter for the Human Body, 232; and Floris

(R. B.) An Experimental Inquiry into the Heat given out by the Human

Body, 242.

Marine Life, Animal and Vegetable, relations between (Vernon), 155.
Martin (C. J.) and Cherry (T.) The Nature of the Antagonism between Toxins

and Antitoxins, 420.

Maxwell (Sir Herbert Eustace) admitted, 63.
Meeting of March 3, 1898, 1; March 10, 25; March 17, 63; March 24, 63;

March 31, 205 ; April 28, 206 ; May 5, 212 ; May 12, 231 ; May 26, 270 ;

June 9, 373 ; June 16, 412.

Mendeleeff (D.) Experimental Investigations on the Oscillations of Balances, 454.
Metabolism in the Plant, Nature and Significance of (Pfeffer), 93.
Metargon, New Gas in Air (Ramsay and Travers), 437.
Monaco (Prince Albert I of) On the Meteorological Observatories of the Azores,

206.

Moore (John Carrick), Obituary Notice of, xxix.
Mueller, (Baron) Ferdinand von, Obituary Notice of, xxxii.
Murray (G-eorge) and Blackman (V. H.) A Study of the Phyto-Plankton of the

Atlantic, 269.
Muscles, on the early Degenerative Changes in the Sensory End Organs of (Batten),

61.

xli

Neon, New Gas in Air (Ramsay and Travers), 437.

Nerve, Electromotive Phenomena investigated with Capillary Electrometer (G-otch

and Burch), 300.

Nerves, action of Sodium Chloride on (Gotch and Burch), 300.
Newton (Hubert A.), Obituary Notice of, i.
Nickel, Magnetic Deformation of , influence of Tension and Temperature on (Jones),

44.

Obituary Notices of Fellows deceased: — Des Cloizeaux (Alf. L. O. Le Grand),
xxv; Moore (John Carrick) , xxix ; Mueller (Ferdinand von), xxxii; Newton
(Hubert A.), i ; Quain (Sir Richard), vi; Sylvester (James Joseph), ix.

Osier (William) elected, 373.

Oxygen, Liquid, Magnetic Susceptibility of (Fleming and Dewar), 311.

Papers read, lists of, 2, 25, 63, 206, 212, 231, 270, 373, 412.

Parsons (Hon. C. A.) elected, 373 ; admitted, 412.

Pearson (Karl) Mathematical Contributions to the Theory of Evolution. V. On
the Reconstruction of the Stature of Prehistoric Races, 417.

Petavel (J. E.) On the Heat dissipated by a Platinum Surface at High Tempera-
tures, 403.

Pfeffer (Wilhelm) admitted, 63; The Nature and Significance of Functional Meta-
bolism in the Plant, 93.

Phosphorus, Detection and Localisation of, in Animal and Vegetable Tissues
(MacaUum), 467.

Photographic action of Organic Bodies, Metals, and Alloys on Sensitive Plate
(Russell), 102.

Phyto-plankton of the Atlantic (Murray and Blackman), 269.

Pinus m'lvestris, Fertilisation and Related Phenomena (Blackman), 400.

Plant Energy, sources of (Pfeffer), 93.

Platinum Surface, heat dissipated by (Petavel), 403.

Polarisation, Rotation of Plane of, by Magnetism, connected with Zeeman effect
(FitzGerald), 31 ; Rotatory, of Electromagnetic Waves (Bose), 146.

Porter (T. C.) Contributions to the Study of " Flicker," 347.

Potential Energy, mutual, of Circular or Helical Current and uniform Coaxial
Current Sheet (Jones), 192.

Preston (Thomas) elected, 373; admitted, 412 ; On the Modifications of the Spectra
of Iron and other Substances radiating in a strong Magnetic Field, 26.

Protoplasm .(Vegetable and Animal), Action of Anaesthetics on (Farmer and
Waller), 213.

Quain (Sir Richard), Obituary Notice, vi.

Raisin (Catherine A.) On certain Structures formed in the Drying of a Fluid
with Particles in Suspension, 217.

Ramsay (William) and Travers (Morris W.) On a new Constituent of Atmo-
spheric Air, 405 ; on the Companions of Argon, 437.

Reid (Edward Waymoxith) elected, 373 ; admitted, 412.

Roberts -Austen (W. C.) On Surfusion in Metals and Alloys, 447.

Rock Structures, Dendritic, &c., illustrated by drying up of Muddy Fluid (Raisin),
217.

Roget (S. R.) Effects of prolonged Heating on the Magnetic Properties of Iron,

258.

xlfl

Rontgen Kays, source of, in Focus Tubes (Swinton), 432.

Riicker (A. W.) and White (W. H.) On the Determination of the Magnetic

Susceptibility of Rocks, 460.
Russell (W. J.) Further Experiments on the Action exerted by certain Metals

and other bodies on a Photographic Plate, 102.

Schunck (C. A.) A photographic Investigation of the Absorption Spectra of

Chlorophyll and its Derivatives in the Yiolet and Ultra-violet Region of the

Spectrum, 389.

Scott (Alexander) elected, 373 ; admitted, 412.
Sensory End Organs of Muscles, observations on Early Degenerative Changes in

(Batten), 61.

Seward (Albert Charles) elected, 373 ; admitted, 412.
Shenstone (William A.) elected, 373 ; admitted, 412.
Snake venom — chemical nature of Antagonism of Toxins and Antitoxins (Martin

and Cherry), 420.
Sollas (W. J.) On the Intimate Structure of Crystals. Crystals of the Cubic

System with Cubic Cleavage, Part I, 270; Part II, 286; Part III, 296.
Sowter (R. J.) and Forsyth (R.W.) On Photographic Evidence of the Objective

Reality of Combination Tones, 396.
Specific Inductive Capacity, due to Motions of Electrically Polarised Molecules

(Edser), 374.
Spectra, Absorption, of Chlorophyll (Schunck), 389; —Influence of a strong

Magnetic Field on (Preston), 26.
Sphenodon, development of (Dendy), 440.
Stature of Prehistoric Races, Reconstruction of (Pearson), 417.
Stomata, Observations on (Darwin), 413.
Stomodseum of Xenia, Gland Cells in (Ash worth), 443.
Surfusion in Metals and Alloys (Roberts- Austen), 447.

Swinton (A. A. C.) On the Source of the Rontgen Rays in Focus Tubes, 432.
Sylvester (James Joseph), Obituary Notice of, ix.

Taylor (Henry M.) elected, 373; admitted, 412.

Teeth, Incisor, independence in young Sphenodon (Dendy), 440.

Tomes (Charles S.), upon the Structure and Development of the Enamel of
Elasmobranch Fishes, 54.

Toxins and Antitoxins, Antagonism between, Chemical in Nature (Martin and
Cherry), 420.

Travers (Morris W.) and Ramsay (William). On a new Constituent of Atmo-
spheric Air, 405 j on the Companions of Argon 437.

Tuatara, Development of (Dendy), 440.

Tutton (A. E.) A Compensated Interference Dilatonieter, 208.

Vaporisation of Metals and other bodies indicated by Photographic Action on

Sensitive Plate (Russell), 102.
Veraon (H. M.) The Relations between Marine Animal and Vegetable Life, 155 ;

the Relations between the Hybrid and Parent Forms of Echinoid Larvae,

228.

Walker (James) On the Relative Retardation between the Components of a
Stream of Light produced by the Passage of the Stream through a Crystalline
Plate cut in any Direction with respect to the Faces of the Crystal, 79.

xliii

Waller (A. D.) and Farmer (J. B.) Observations on the Action of Anaesthetics

on Vegetable and Animal Protoplasm, 213.
Wave-slowness, Hamilton's surface of (Walker), 79.
White (W. H.) and Kiicker (A. W.) On the Determination of the Magnetic

Susceptibility of Eocks, 460.
Whittaker (E. T.) On the Connection of Algebraic Functions with Automorphic

Functions, 267.
Wilson (E.) Aluminium as an Electrode in Cells for direct and alternate

Currents, 329.
Wimshursfc (James) elected, 373 ; admitted, 412.

Xenia, Gland Cells in Stornata, Pseudopodia in Endoderm (Ash worth), 443.

EKRATUM.

Page 206, line 8. For " Professor Clifton " read " Captain Abney."

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