Ny 
> 


aA 8, 


a 


THE 


ANNALS 


OF 


PHILOSOPHY. 


NEW SERIES. 


JANUARY TO JUNE, 1824. 


VOL. VII. 


AND TWENTY-THIRD FROM THE COMMEXCEMENT. 


Ie 


London : 
Prinied by C. Baldwin, New Bridge-street ; 
FOR BALDWIN, CRADOCK, AND JOY, 


PATERNOSTER-ROW. 


~~ -- 


1824. 


me 


TABLE OF CONTENTS. 


NUMBER I,—JANUARY. 


Page 


Observations on the Rocks of Mount Sorrel, and of the Neighbourhood of 
Grooby, in Leicestershire. By W. sisal FLS. and S. L. te 


MGS: (CW ithia Plate.)is.:.0 aide 'se bres Af oth ba -mide »  wesomertise? dicen 
On the Crystalline Forms of Artificial Salts. By H. J. Brooke, Esq, 
BS. (Continued) $s < omsiebie¥s «a8 ould» oo woyerie de wsptie e)eepjoreiab ones srejers 


On a new Phenomenon of Electro-magnetism. By Sir H. Davy, Bart.. 
A Reply to some Observations in the Review of An Essay upon the Con- 
stitution of the Atmosphere. By J. F. Daniell, FRS......,... oe Ses 
Astronomical Observations. By Col. Beaufoy, FRS. ..........25.2004+ 
On Lupulin, asa Medicine. By N. Mill, Esq...........0eececseeecees 
On the Methods of employing the various Tests proposed for detecting the 
Presence of Arsenic. By R. Phillips, FRS. L. and E.........4..45 
Corrections in Bight Ascension of 37 Principal Stars. By J. seh. FRS. 
Description of a New Thermoelectric Instrument. By the Rey. J. Cum- 
SM: AA SRE Bera is Si g's dk papain see Tes me memrrorae fe ieices ssa 
On Organic Salifiable Bases. By MM. Dumas and Pelletier. . 
On Felspar, Albite, Labrador, and Anorthite. By M. Ee rsine us are 
OW ith B Plate.) 2 225.. .c2 500 cena sirens ealteamtinwceas ng esl eeiensed hap 
Observations on the preceding Paper, with an Account of anew Mineral. 
By M. Levy, MA. ........ccccec ee ceeeceec cece reteeeecsceneeeneecs 
Analytical Account of the Philosophical Transactions for 1823, Part II.. 
Proceedings of the Royal Society ........+s.seeeeeseeeceeeees i ia) pa é 
Supposed Origin of the Art of Smelting Iron ...........+.+ ods cisislapoiae a 
Composition of Ancient Bronze........+.+e++eereeee aniasion occ ceeee ae 
Eee EOC EPO MENT Cte t oper Oeccccccenvedocsses 
Effect of Heat in lessening the Cohesive Horce OF Tron... .cesecssecccens 
Correctness of Greenwich Observations. ........++eeeeerees cece eeeese 
British Museum and Edinburgh Review ........++eseeseeeceeeeeeeeses 
New Scientific Books..,........ Je saven shinies cccccececeecenees eececese 
Prem MEMO ATT) oh. hk 25h stl slefe «isi tela Lore aes eb eee big mihigersd se 
Mr. Howard’s Meteorological Journal. ......ceeceeceeseeeceeesevensens 


NUMBER II.—FEBRUARY. 


Experiments on the Stability of Floating Bodies. By Col. Beaufoy, FRS. 
CWithra-Plate):. 6 ssscscdeccees eevee @eeereereereeeeererer ee eeeeerteree 


1 


20: 
22 
26 
29 
29 


30 
37 


46 
47 


49. 


81 


iv CONTENTS. 


Page 
On the Liquefaction of Chlorine and other Gases. By Mr. Faraday..... 89 
New Locality of the Skorodite. By W. Phillips, FLS..........-+2+++0. 97 
On Fluorine. By J. Smithson, FRS. ..........ceseeeesercneeeeecs » oe 100 
On the Composition of the Ancient Ruby Glass. By Mr. Cooper...... 105 
On the ensuing Opposition of Mars. By F. Baily, Esq. FRS. VPAS. .. 107 
Table of the Salt Springs in Germany. By C. Keferstein...........++4- 109 


An Examination of some Egyptian Colours. By J. Smithson, FRS.... 115 
On the Crystalline Forms of Artificial Salts. By H. J. Brooke, Esq. FRS. 


(continued)... ...escedeccecesecsencencecceeeseneeeeeecerseeneeenes 117 
On the Occurrence of Cleavelandite in the older Rocks. By W. Phillips, 
FLS. MGS..... PPLE 2A, BAD IOS IE ES BASS, ee Aa neeaae 118 
Astronomical Observations. By Col. Beaufoy, FRS...........seeseees 121 
Improved Clinometer. By M. P. Moyle, Esq...........sseseeeseeeees 122 
Reply to the Editor. By Mr. Gray............ssseceeee sees ee eeen es Pie fe) 
Remarks upon the preceding Answer. By R. Phillips, FRS. &c. ...... 128 
On the Detection of small Quantities of Arsenic. By Dr. Traill........ 131 
Expansion of Gases. By Mr. Jf aN ee ac tea he cass, - 133 
Account ofa New Mineral. By M. Levy, MA. ......eeeseeeeeeee ees 134 
Corrections in Right Ascension of 37 Principal Stars. By James South, 
FRS. (concluded) ....seecvescescceeesecseeeecteeeseseraeeeeseennes 136 
Analytical Account of the Philosophioul Transactions, for 1823, Part IL. 
(continued) ..sseescreccececececeesenecerenae eeneseeetesaeeaaeenee 143 
Proceedings of the Royal Society ........... 4 apocet tice A eS Bac 147 
Linnean Society ........0. sc eeececcceecewecces eee. 150 
Astronomical Society......5 - Usesccrsb eee eevee ccm 152 
Geological Society ...........+eccecccccessceee one 153 
Meteorological Society of London..........++« oceet 154 
Dark and bright Lines traversing the Spectrum ...+.+sseeeeeeseeeeeeees 154 
Analysis of @leavelandite! (oA CL cB BIR ses a CME Rs? - 
Copper Pyrites of Orijarva........ss.seeeeeeeeseeness selaletetatera aliens 155 
Scapolite from Pargas .......... BE FEDS USE pte tenis nt etorlat betas 155 
Manufacture of Pianoforte Wire ......sseescececececeeccessceceeneees - 156 
New Scientific Books ......0..eeceeeees Rs OFS TE IR, Uae 156 
New Patents... cs... cece seee eens ete ceebreratlce Dede SOC CREAN Etofemibd e967 
Mr. Howard's Meteorological Journal..........+.+ dddtevetedcoes ies OAS 
— 
NUMBER III.—MARCH. 
On the Crystalline Forms of Artificial Salts. By H. J. Brooke, Esq. 
FRS. (continued) oi. .sseceecececeeeeneseeeeeenee een eeneneeccenenes 161 
On the Daily Variation of the Horizontal and Dipping Needles under a 
reduced directive Power. By Peter Barlow, Esq. FRS......-+..2+00+: 163 
On an Improved Apparatus for the Analysis of cone Products. By 
Mr. Cooper. (Witha Plate)... sccsccsccccvasttcrcsccccecssccecs aieeraly 0 
On the Ancient Tin Trade........secreecesneceneneneceeece id cise abaaieres pli 


On Fossil Shells. By L. W. Dilley, Esq, FRS. 0.0 se5e0sisis ideas 0; MHZ, 


CONTENTS. v 


Page 
On the Active Power of Dilatation ofthe Heart. By D, Williams, MD. 181 
A Table of Equivalent Numbers. ........s0..seeseeeeeseseeeeeeseeees 185 
Astronomical Observations. By Col. Beanfoy, FRS. .......+...seesees 197 
On Animal Remains found in Caves. By G. Cumberland, Esq........ 198 
Comparative Temperature of Pisa and Penzance. By Mr. E. Giddy..... 200 
An Account of the Volcanos at present in Activity. By M. Arago...... 201 

On certain Instruments formerly used for the Purpose of Blasting in Lead 
Mines. By Mr. Crawhall. ......secsseveseneercenteneeeesseseeerens 214 

On the Eclipses of Jupiter’s Third and Fourth Satellites. By J. South, 
Esq. FRS. ......cececeeeercceececcensceesscceeeaes seen ceeseeescees 217 

Analytical Account of the Philosophical Transactions, for 1823, Part II. 
(continued) ...se.seseeeeeeeeces bara falela cls Stine a alctelats lstolalefars sie ieia See fa 207, 
Proceedings of the Royal Society ......++..++4- coeeeeee Ceeecacesccceee 229 
Primary Forms of Sulphur. .....++++++++++ enalbd dine seis bisle Eide sevcee 234 
Uranite of Autun..... eRe se Ore Ynesh ae otbeesee ats ea sea eto eis vislemsi S35 
Phosphorescence of Acetate of Lime .....+.+++eseseeeeeeeesreceeeecece 235 
Chemical Examination of a Fragment ofa Meteor........essseeseeeeeee 236 
New Scientific Books. .......scccccccsccecevcsescccccscssccevcecscccs 237 
New Patents ......-seecececeeceeccsncetereeesseeeeeeeesesteceeee tee 238 
Mr. Howard’s Meteorological Journal. ......-+++++++ p snpitnatanue soeeee 239 

—_—— 
NUMBER IV.—APRIL. 

On Expansions. By Mr. Crichton: oii da teeees teased BP enatinoys ooo 241 


On the Atomic Weight of Boracic and Tartaric Acids. By Dr. Thomson 245 
Corrections in Right Ascension of 37 Stars of the Greenwich Catalogue. 


By J, South, FRS. (continued)...0ssseeeeseeerereeeececceseeeeeeeees 247 
On Uranium. By M. Arfwedson .......+.eeeeeereeeeeeereeeeeeenes +. 253 
Examination of the Oxidum Manganoso-Manganicum. By M. Arf- 

MVECSON« cwcegcen des nceensncnecce ce meejeisislevida-isble'esinjellpinstb bb ebislem ste 267 
On a New Mineral Substance. By M. Levy, MA.......0.seseeeeeees 275 
Examination of Babingtonite by the Blowpipe. By J.G. Children, Esq. 277 
Astronomical Observations. By Col. Beaufoy, FRS........0..see0 eens 278 
Meteorological Registers for 1823. .....ssseececeseessesseetereeeeeeees 279. 
On the Transmission of Electricity through Fluids. By Mr. Woodward 283 
Hints to an Edinburgh Reviewer. By W. Phillips, FLS.,............. 285 
On the Crystalline Forms of Artificial Salts. By H. J. Brooke, Esq. FRS. 

(continued) ..+.+++-eeeeeeeeeeeerstenenes suradbanasin do} Hate sta aes 287 
Analysis of the Nitrates of Strontia, described in the preceding Paper. By 

Mr. Cooper ......2ecceeereneessnenene teeeeeteseaegeseeeneenareens 289 


On a Submarine Forest in the Frith of Tay. By J. Fleming, DD. FRSE. 290 
Analytical Account of the Philosophical Transactions, for 1823, Part IL. 


(concluded) .......sesecerecececeeenenectseeviecwsssecepeesse oo vi dizte 298 
Proceedings of the Royal Society na cesegeestedeawbes Wb wheat) teats San 305 
——— Astronomical Society. . ee dtasticterohe apciaacie,, CUeb die 308 
———— Geological Society ........seeceeecsdeauesssenesecs 809 

— Meteorological Society... +--+ +++eeeesanee core, esdtela ied 3i1 


———————_——_——. Medico-Botanical Society of Londensisiuds, eav.wo} 318 


vi CONTENTS. 


Page 
On the Mountain Barometer. ........e0eeeeee IG ERE UES | Se - 813 
Vegetable Alkalies. ..5. 006. ecceceeeeeseeeeetsenserereerees SSL. aces 314. 
Deoebereiner’s Eudiometer ........-.cccecccccccssccecccsenccessseerces 316 
New Minerals......200 fies cece ee Ha ee rmetate cs Calan iee eclee Vets oe tretate 316 
Death of Mr. Bowdich, in Africa. ......... Cee ANP ty bd eth) 317 
Wee Scientiite Books. o35 oe teh BN OR et cee toes ae een 317 
New Batents gestern oes sae Bidtedestan cite ea altace wee emte Me 318 
Mr. Howard's Meteorological Journal ...6s6.06eeeeeee becccose beens eee 319 
eer ere) 
_ NUMBER V.—MAY. 

Remarks on Solar Light and Heat. - By Baden Powell, MA. ........ -- 321 
Astronomical Observations. By Col. Beaufoy, FRS. .7..........0000- 328 
On the Decomposition of the Metallic Sulphates by Hydrogen Gas. By 

Mi SAriwedsan se aocc atest eee es Sottero les coctics se cats once tiieaee 329 
Analysis of some Minerals. By M. Arfwedson...........ceeeeeeeeeees 343 
On the Theory of Evaporation. - By J. Herapath, Esq........-.0022-0 0+ 349 
Chemical Examination of Analcime, Copper Pyrites, and Sulphuret of 

Bismuth: “By M: Rose: \sissdseoeanwuee tole secicas sh eveileawwee mene 353 
Memoir on some Geometrical Principles connected with the Trisection | 

ofan Arc. By John Walker, Esq. (With a Plate) ..............05 356 
On the Crystalline Forms of Artificial Salts. By H. J. Brooke, Esq. FRS. 

DHABLSS Continued eee eee ee eae ee data sae eta ate 364 


Apparatus for producing Instantaneous Light. By the Rev. J. Cum- 
ming, MA. FRS. and Professor of Chemistry in the University of 


Maralridperds sascdeossae sce docs see ao ateee ae canes a tecles aes dates 805 
On Nuttallite, a new Mineral. By H. J. Brooke, Esq. FRS. &c. ...... 366 
Reply to Mr. Henslow. - By Dr. Berger ....000sccccssssccsscessdsceece 367 
Analytical Account of De la Beche’s Selection of Geological Memoirs. .. 371 
Proceedings of the Royal Society ............00s.ceeees pas a. Seale «ieee! 
——————— Linnean Society .....:...0ce.ccveesevcces Se tis 386 

ZLovlogical-Clab: si23526g0 00) VE aes eee 388 

Astrononneal Societys. cece cess cee seca te meee 389 

Geblopicul'Society 207... PE, SSA ae eee 391 

Medico-Botanical Society of London........+0++++4- 391 
The Logan Stone in Cornwall overturned...........0-2ceeeeecees Aisoe 392 
The Rate of'a:‘Chronometer #1) 02 Oe, eee SAS ee 392 
@hieltenham Wrater: sis is s535 esse SAA AL cha eet eee 393 
Detonating Silver and Mercury. ......, SSCA RACER EEO aPets ioricicesic 394 
Absorption of Air by Mercury....... Dalelsoh ne ec lccfeisemaciastesa steams - - 394 
Connexion of Phosphorescence with Electricity............0.ceeeeeeees 395. 
Preparation of Oxide of Nickel. .............. ehephocvecscesqgesreteese 395 
PRBORSDG orceweisis sess er ee ese eee ed ST eS ene 
New Scientific Books. ...... ADOC HOODOO nEMICABOORutidoSAAS wa esouive ts 396 
MM EMER ic ovderd beer cccstees tees OR are Netecs 397 


Mr. Howard’s Meteorological Journal ..........00ecce0e OF qoreneaneghesrr 399° 


CONTENTs. vil 


NUMBER VI.—JUNE. 


Page 
Remarks on Solar Light and Heat. By Baden Powell, MA. (continued) . 401 
Astronomical Observations. By Col. Beaufoy, FRS..............02.20- 406 
Remarks upon Dr. Berger’s Reply. By Prof. Henslow................. 407 
Beeaccount ofthe Logan: Boek. 24.1. .5 seed de ee ede gel Saeed ae 410 
Analysis of the Fulminate of Silver. By MM. Liebig and Gay-Lussac. 
Reitlivayelate)s Ar dimcecce ois this sss arctieetee sect oe es ale clare inte clatRiS aig 418 
Analyses of the Chrysoberyls from Haddam and Brazil. By Mr. Henry 
Bea RICE Gar fciei sia aiere nical erat. Wem isi te sioner ts) at ele: aic'atclclata/ole cos) se'e ol dlelnialale oft 427 


OF Poisons, Chemically, Physiologically, and Pathologically considered.. 432 
Speculations and Inquiries respecting the Action and Nature of certain 


CaaoNnda Gl Siipltur. apes wc ese ses cout omens Wr atee te coe 444 
On the Coliseum at Rome. By T. R. Underwood, Esq. MGS........ -- 448 
Analysis of the Argillaceous Iron Ore. By R. Phillips, FRS. &c....... 448 
Analytical Account of the Pharmacopeeia Collegii Regalis Medicorum 

Eondinensis,- 1aaesnwer! sneeelt eo PUR ie ersk el 450 
Pracecdings. of the Royal. Society, 0 uj «2010 st. /sieje0) pnd dae jepies «Wale ov'b 55 458 

GeologicalSociety. .\. i. asses od ced See oe 460 
—_—__—_ Meteorological, Society 2 siden Veidece Sciee esses e's e 464 
a Medieal. Society »....5f.0ee eae ee ee Soe she 467 
Sipermeattecer: Potashit cs. Sa 320 cae. Diskwie  aksee ees. bbe. vee See 468 
Action of Hydrocyanjc Acid on Vegetable Life.........2.......+00.00: 468 
Dinrnal Variation of the Barometer. 212... 0ss.'t os cise’ ose e's eleslesie es 468 
On the Cause of Rotatory Motion.................cccccececceescceees 469 
On the Transmission sf Electricity through other Fluids. .............. 469 
Palpenity of Salts of Gtrychwuaiay sah ois he les ed see es eee dee oles 470 
Crystallization of the Subcarbonate of Potash.,.......2.+0222ceeeeeeeee 470 
New Scientific Books .........0000- ras take ae pistes seo fees de cele ae 470 
UE TMEABED. chan ain)s'h'e's pa wiv ales aeeinte ere aoe atte eMEetea sr ones ce deal ae 471 
Mr. Howard’s Meteorological Journal. ..........0000seeeeeeseeeseeeees 473 


a a ebartemieltalat.), Steaamiens pee MRA Dae Aphid Br ge i cee 475 


PLATES IN VOL. VII. (New Series.) 


ae 


Plates. Page 
XXIV.—Rocks of Mount Sorrel. «<0. ...creccles 0 + sipnciebiais deve py re ae 
XXV.—On Felspar, Albite, Labrador, and Anorthite ............. - 49 
XXVI.—On the Stability of Floating Bodies. ..... SRR OE ate sil 
XXVII.—Apparatus for the Analysis of Organic Products, .......... .» 170 

XXVIII.—On some Geometrical Principles connected with the Trisec- 
EIOH GLAM AAE wcrctlete eect weaisislsiette tis sie a cieige anise eae 356 
SX .— On Fulminate of Silver, «2.6: adeiet dustles bh x00 -naidianslage 415 

ERRATA. 
—=_— 


Page 29, line 18, for Lapulin, read Lupniin. 
83, line 10, for Ther. read Thus, 
325, line 19, fur infringe, read impinge. 
327, line 2, for assent, read agent. 
384, line 4 from bottom, for L. Italioa, read L, Italica. 
388, line A, for Harleston, read Starston. 
5, for Clarton, read Clacton. 


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Pagel 


EO sce G@nal Hoyelt ry 


SCAIM, ONE INCH TO 4 MILE. 


engraved for the.tnnats of Pridosop's. for Baldwin Qradack RY, Sane 


MSPLATE Xyp 


SKETCH 


OF A 
GEOLOGIGAL War 
of 
CHARNWOOD FOREST. 


E 


Loughboroughe 


i 


Quorndon 
° 


ANNALS 


PHILOSOPHY. 


JANUARY, 1894, 


Articte I. 


Observations on the Rocks of Mount Sorrel, of Charnwood Forest, 
and of the Neighbourhood of Grooby, in Leicestershire. By 
~ William Phillips, FLS. &c: and Samuel Luck Kent, MGS, 
~ (With a Plate.) . 


- Tue tract to which the following observations are confined, 
may, in general terms, be said to Be coniprehended within a 
triangle, of which the angles are Mount Sorrel, Grooby, and 
Thrinkston. (See the annexed Map*, Plate XX1V.) Two sides 
of this triangle até about nine miles in length, namely, from 
Mount Sorrel to Thrinkston, and from Thrinkston to Grooby ; 
the third side, namely, from Mount Sorrel to Grooby, is 
between five and six miles long. This triangle comprehends 
rocks remarkably differing from those of the vast plain of new 
ted sandstone which they overtop, though not to any considera- 
ble elevation, the highest point of the whole being Bardon Hill, 
situated nearly midway between Grooby and Thrinkston, and 
which attains the height of 853 feet above the level of the sea, 
On the south-west of this tract, however, rocks of the same 
nature as those near Grooby, are, according to Mr. Greenough’s 
map, to be found for some little distance ; but the extent of 
these we did not visit. 

The rocks of the area we have mentioned vary greatly in their 
external characters ; but before we proceed to describe them, it 


* The accompanying map is not given as an accurate representation of the forms of 
the hills, but chiefly to assist the reader, or the traveller, in forming some idea of their 
telative position, ~ ‘ Ft . os 

New Series, vou, Wil. B 


2 Messrs. W. Phillips and Kent on (Jan. 


may not be amiss to give a general outline of the principal fea- 
ture of the district in question. 

From the height which has already been mentioned, it will at 
once be decided that it cannot be considered as mountainous, 
but only hilly. The whole tract, however, may be divided into 
three parts, when viewed in relation to its surface, and its geolo- 
gical features. As regards the latter, itis divided only into two 
parts in Mr. Greenough’s map; the green colour correctly 
denoting the existence of trap rocks on the south-eastern parts 
of the district, being incorrectly carried up to the north-eastern, 
where an essentially different rock prevails, to the ‘exclusion of 
all others, and which is coloured red in the annexed map. 
These two extremes are less elevated than the central and 
western parts, which consist of another rock perfectly dissimilar 
to either of the former. 

The extreme extent of this tract on the east, is formed by the 
cliffs above the town of Mount Sorrel: from near the summit of 
these cliffs, which may be assumed scarcely to exceed at their 
highest part the height of 150 feet above the river Soar, the 
country descends gently on the west and south-west for about 
two miles, if we except two or three well wooded hills, termed 
Buddon’s Wood, and attains its greatest depression along a line 
extending by Swithland, Rushfield, and Woodhouse, to Lough- 
borough Park; and here the country is at least as low as the 
general level of the red sandstone surrounding the tract of which 
we are treating. The small patch forming the south-east angle 
of our tract, which is coloured green in the annexed map, on the 
north and north-west of Grooby, is generally of inconsiderable 
height, the highest point being the knowl on which the windmill 
stands close to Markfield. The remainder of our district 
(coloured yellow in the map) may be considered as one large 
hill, rising into frequent eminences, of which one of the most 
lofty near the centre, Beacon Hill, is but little lower than Bar- 
don Hill, the highest point of the whole. The short and nume- 
rous valleys dividing these eminences, though much above the 
general level of the new red sandstone, are nevertheless covered 
by it in several instances ; and it is manifest that its beds repose 
on the western side of Beacon Hill. 

The numerous eminences already adverted to have received 
each its own designation as a separate hill, and it is chiefly on 
the summits of these that the nature of the rocks constituting 
them is to be perceived, being frequently crowned by rugged and 
bare masses, which, particularly as viewed from near Grace 
Dieu, have a serrated outline. This district for some miles east 
of Thrinkston, where the hills are numerous and very rugged, is 
little or not at all cultivated, the depressions between and 
among them being covered by a long and very coarse grass, 
beneath which, in some instances, as near Pedler Hili, the 
ground is extremely soft, and even swampy. ‘The other parts 
of the district, however, differ greatly from this in their general 


1824,] the Rocks of Mount Sorrel, &¢.’ a 


aspect, being often highly cultivated, even to near the summits, 
of the hills, as in the instance of the south-western side of 
Beacon Hill, while the lower parts, in some few instances, are 

well wooded, and even some of the loftier summits are crowned. 
with woods, as is the case with those termed the Outwoods, 

NW of Beacon Hill, and the hill in which are situated those 

slate quarries near Swithland, which are the most distant from 

that place on the SE, and Bardon Hill to its very summit. 

Everywhere, however, except where the eminences are crowned. 
by bare rocks, a herbage forms the surface, covering a more or 

less deep alluvium of fawn-coloured, or reddish and loose earth, - 
as was frequently manifested by the labours of the mole, even. 
on some of the most elevated ridges; and that this alluvium is” 
at least occasionally of considerable depth, is proved on the side 

of Whittle Hill, in which are situated many little quarries of five , 
to fifteen feet deep, wrought in search of fragments and loose » 
pieces of that peculiar variety of the rock ofthe forest, so greatly 

used in different parts of the kingdom for setting penknives, 

and which is termed the Charnwood or Charley Forest hone. 

This very slight sketch of the external characters of this tract, 
will evince that the opportunities of judging of the nature of its: 
rocks is far more limited than could be wished, but suffices at: 
least to furnish such information as may serye, if not to deter- 
mine, at least to afford some probable notion of the relative eras : 
© which they belong, even though some points must necessarily 
oe left undecided. ; 

These difficulties are, first, that having found it impossible to 
discover the actual connexion of any two of the three rocks: 
constituting this tract, and which differ greatly in aspect and 
composition, we are deprived of any direct means of ascer- 
taining their relative periods of formation; and, secondly, : 
that neither the one nor the other is seen reposing upon any 
other rock which, in that case, might be assumed to be anterior, 
and might therefore serve, in some degree, perhaps, to assist in 
deciding their relative age. It is indeed true that we are justi- 
fied in considering them older than the surrounding new red 
sandstone, since its beds actually repose upon these rocks, 
which pass away gradually beneath them. This circumstance, 
which is visible in a quarry at the eastern end of the cliffs 
above the town of Mount Sorrel, and to a still greater extent at 
both extremes of an old and deserted slate quarry near Swith- 
land, would seem to prove, that in the section annexed by the 
Rey. W. D. Conybeare to the “ Outlines of the Geology of 
England and Wales,” the rocks of Charnwood would have been 
represented with somewhat greater accuracy, if instead of deli- 
neating the beds of the new red sandstone as abutting against 
them, their extremes had been shown reposing on them, and 
the rocks of this district passing gradually, but at a considerable 
angle, beneath them. As represented in that section, the rocks 

B2 


4 Messrs. W. Phillips and Kent on [JaN, 


of the Forest may possibly serve to convey a notion that they 
have been thrust up by some subterranean force—a notion 
which we conceive would be erroneous, arguing from the 
remarkable regularity with which the sandstone beds repose on 
the rocks, dipping wherever they are visible at an angle not less 
than six nor greater than eight degrees. 

- The regularity of the sandstone beds seems also to come in 
proof of another fact ; namely, that the rocks of the Forest have 
not suffered by convulsion—a conclusion strengthened by the 
observation that the direction of the slaty cleavage of these 
rocks, which is mostly apparent, or becomes so by the assist- 
ance of the hammer, is everywhere either NW by W, and SE by 
E; or differs but very slightly from it towards the W and E. 

For the reasons which have already been given, we shall treat 
separately of the rocks of the three parts into which this district 
is divided, as the Mount Sorrel, the Charnwood, and the Grooby 
tracts; and first of the former. 


Of the Rocks of Mount Sorrel. 


_ The rocks of Mount Sorrel are admirably laid open to view by 
means of a line of quarries overhanging the town, and giving to 
these rocks the appearance of cliffs, perhaps one-third of a mile 
in length, and of the average height of nearly 100 feet, but not 
absolutely continuous. Other small and detached quarries are 
wrought on the eastern side, the whole being chiefly for the 
purposes of road-making. The rock when sound is broken into 
the proper form for paving stones, which are shipped on the Soar 
for various parts of the kingdom, when less so, for mending 
roads in lieu of the gravel employed in the neighbourhood of 
London, for which purpose the Mount Sorrel rock is far supe- 
tior.* Immediately on quitting the town on the W, the rocks 
sink beneath a comparatively low and verdant covering, for 
some little distance, and then again swell into trifling elevations 
a little south of the road passing from Mount Sorrel to Quorn- 
den, or Quorn, as it is commonly termed by the inhabitants of 
both places. In Buddon’s Wood, which occupies the greater 
part of these little eminences, and within half a mile of Quorn- 
den, are situated two or three inconsiderable quarries, one of 
which, however, is remarkable, as will presently be noted, for 
the veins or dykes traversing the rock. 

The openings abovementioned, together with a small one situ- 
ated about a mile nearly SW of Mount Sorrel, and called Simp- 
son’s Pit, remarkable also for its exhibiting the appearance of a 
very determinate dyke, form the whole catalogue of the 
quarries observable in this rock, and which offer the principal 


_* We request thus to express our obligations to —— Jackson, Esq; residing at 
Mount Sorrel, and the present proprietor of the quarries, for his polite attention in 
directing our observation.to eyery point which he considered the most likely to inte- 
rest us, 


1824;] the Rocks of Mount Sorrel, &¢. 5 


opportunity for studying its nature. Some rocks, however, 
appear i. sitw on an eminence between the town and Buddon’s 
Wood ; while some also oyertop the surface of Rothley Plain, 
of which the gradual descent begins at the abovementioned 
quarry, called Simpson’s Pit; and in the earlier part of the 
descent of this plain, rocks perfectly resembling those of Mount 
Sorrel occasionally overtop the general surface, sinking, as has 
already been observed, ultimately beneath it, and so completely 
that it is impossible to discover their connexion with those of 
the Forest. 
The aspect of the Mount Sorrel rock is granitic, and hand 
specimens may, perhaps, be found, of which the ingredients 
appear to be confined to those commonly considered as being 
essential to granite; namely, quartz, felspar, and mica; for the 
hornblende which generally is sufficiently apparent, and which 
often abounds, is occasionally so neatly wanting, or so minute 
in small specimens, that it may easily be overlooked. In reality, 
howeyer, much of that which appears to be felspar, is not that 
mineral, but cleayelandite. Epidote occasionally enters into its 
composition, but is more generally found in small nests or veins, 
with semi-transparent quartz, when it is sometimes associated 
with magnesian carbonate of lime, which cleaves into rhom- 
boids, and slowly effervesces, in diluted muriatic acid ; silvery 
talc appears sometimes on the quartz found in veins or nests in 
the rock, and the same substance of yarious colours enters into. 
the composition of some of those which overtop the grassy slope 
of Rothley Plain. Chlorite also in small quantity is sometimes 
diffused through the mass, and occasionally appears traversing 
it in thin irregular veins. 
- The quartz entering into the composition of this rock is 
transparent or semitransparent, the mica in thin hexagonal 
plates, and the surfaces produced by dividing them parallel to 
the terminal plane are very splendent and of a colour nearly 
approaching to black, but by transmitted light the laminz appear 
of a dingy-brown. The hornblende is of a dark bottle-green, 
approaching to black. The felspar and cleavelandite, which are 
almost constantly the prevailing substances, vary greatly in 
colour, are intermingled in the mass, and cannot always be dis- 
tinguished from each other by their external characters. Both 
are commonly red or reddish, and this colour is sometimes so 
powerful in the cleavelandite as to impart to it the aspect of red 
jasper, particularly whenever it assumes in any degree the 
appearance of a vein ; the planes produced by fracture are then 
generally curvilinear, and without lustre. Sometimes, however, 
the felspar and cleavelandite are intermixed, either simply, or in 
such a manner as to impart to the rock a porphyritic character ; 
the felspar is generally translucent, and the imbedded cleave-. 
landite white and nearly opaque, and the other ingredients of 
the rock then form a small grained paste. We were not in the 


6 Messrs; W. Phillips and Kent on [JAN. 


first instance aware of the intermixture of these two minerals in 
this rock, and considering the whole as felspar, we should have 
contented ourselves with the observation that a part of it yields 
to the pressure of the edge of the hard mineralogical knife, 
which felspar does not, but for the discovery of M. Lévy, that 
much which has been considered as felspar is cleavelandite ; the 
announcement of this in the Annals for November last, induced 
us to examine all the varieties of this rock with great attention, 
and we have been convinced of the intermixture of the two 
minerals by procuring fragments from the same specimen ; 
which, submitted to the reflective goniometer, afforded us sepa- 
rately the angles of the two substances ; felspar cleaves with 
ease only in that direction which affords an angle of 90° ; while 
cleavelandite yields with nearly equal ease parallel to all the 
planes of its primary crystal, and we have consequently obtained 
the measurement of all its angles. 

The Mount Sorrel rock thus constituted* will be judged by 
some to be a syenite; while others will consider it to be a gra- 
nite of the compound kind described by Dr. Mac Culloch, in his 
excellent Treatise on Rocks, under the Third Division, relating 
to that rock (p. 258), and it is to be regretted that no sufficient 
means of determining its actual geological position (which alone 
might settle the question) is afforded, since it is not seen in 
connexion with any other rock, save the beds of the new red 
sandstone, which, as has already been stated, repose on it. 

But there are still some circumstances regarding this rock 
which merit attention. It not unfrequently includes either 
irregular or somewhat spherical masses, varying in size from 
about an inch in diameter to nearly a foot, and possessing a totally 
different aspect to the rock itself; some of these have at first 
sight the appearance of fragments, but not even a close inspec- 
tion with a glass can discover the precise line of junction with 
the rock. Their aspect is fine-grained, and their composition 
appears to be, minute quartz, felspar, hornblende, and chlorite, 
apparently imbedded in a substance of a hair-brown colour, 
which yields to the knife readily, and resembles steatite. The 
mass partakes of a brown colour with a tinge of green, espe- 
cially when moistened : in one instance, specks of yellow copper 
ore and whitish pyrites were apparent; in another, the same 
ingredients are visible, and as effervescence is produced by the 
application of diluted muriatic acid, it may be assumed also to 
include calcareous spar. 

This rock also contains veins or dykes: the substances of 


* We must not make any particular exception of this rock, on account of its contain- 
ing cleavelandite abundantly. This mineral has since been found entering into the com- 
position of a porphyritic granite from Cornwall; in the granite of Shap in Westmore- 
land, and in a porphyry from Glen Tilt. in Scotland, as announced in the Annals for 
December ;_ and still more recently in the porphyritic rocks of Charnwood Forest ; and 
probably also in the neighbouring trap rocks of Grooby, in Leicestershire ; in each of 
these it is accompanied by felspar. ‘ mae Fare . ery) 


1824.] the Rocks of Mount Sorrel, &c. 7 


these differ greatly in aspect and composition. In some 
instances they are scarcely discermble from the rock itself which 
incloses them; in others, they appear to consist chiefly of - 
steatite ; and in others, of a substance which occasionlly has 

much resemblance to the inclosed masses just adverted to, and 

which, in one instance at least, is not to be distinguished by 

the eye from fine-grained basalt. 

The dykes of which the substance greatly resembles the rock 
of Mount Sorrel, though in a somewhat disintegrated state, and 
‘containing some reddish steatite, are situated not far from the 
eastern extremity of the line of quarries at the back of the town: 
they are two in number, both run E and W, have pretty determi- 
nate walls, and are visible for about 12 feet; that is, to the depth 
‘at which the rock has been quarried where they occur. One 
is about 20 inches wide at top, and after narrowing a little, 
divides into two narrow branches; the other is about two feet 
wide, and underlies a little towards the north. 

- The veins or dykes which consist primarily of steatite, traverse 
a rock perfectly resembling the reddest variety of Mount Sorrel, 
in Beaumont’s quarry, which is situated on the edge of Buddon’s 
‘Wood, beside a road leading from Quornden to Rothley, and 
about half a mile from the former place. Three veins are here 
visible which are parallel, run nearly due E and W, and each 
may be traced on an average about 30 feet, the walls being 
mostly very determinate : the two southern veins are about four 
feet apart, and the third is about 22 feet on the north of the 
nearest to it: they vary from 18 inckes to two feet in thickness. 
‘The substance of the southernmost vein, which underlies a little 
to the south, is a greenish steatite, which is translucent, 
yields to the pressure of the nail, and incloses a few specks of 
hornblende and tale. Externally it is, however, in a state of 
disintegration probably from exposure, and readily crumbles 
down into a greyish-white, and somewhat unctuous powder ; 
and in places it-is associated with a harder substance which is 
granular, and which has the aspect of steatite of a mixed red 
and green colour,‘and incloses quartz and hornblende. The 
steatite of the middle and northernmost veins, which are nearly 
or quite vertical, is not quite: so soft ; itincloses specks of horn- 
blende and chlorite, together with small masses composed of a 
reddish substance resembling hornstone, or compact felspar, 
associated with decomposing hornblende. It is obsérved by 
Dr. Mac Culloch, in treating of some of the more rss 
varieties of granite described by him, that it is doubtful whether 
the apparent steatite of some varieties may not be decomposed 
talc or chlorite, an observation that may, perhaps, have some 
bearing on the steatite of these veins. 

- On the face of the rock S of these veins, we observed a mass 
ofa bluish cast, about 20 feet wide, and 6 feet high, greatly re- 
sembling the substance of the dykes, presently to be noticed, and 


8 Messrs, W. Phillips and Kent on (Jan. 


reposing on the rock of the quarry, and bounded by it on each 
side ;, we could not, however, perceive the actual junction, . 
There are two dykes of which the substances much resemble 
each other, except that in one part of one of them the rock has 
greatly the external characters and appearance of a fine-grained 
‘basalt. Just beside the road that divides the line of quarries 
which overhang Mount Sorrel, we perceived among other stones 
broken up for the repair of the roads, many fragments of a bluish 
hue ; and on inquiries respecting the place from which they 
were taken, a vein running nearly N and 8, and about a foot 
in thickness, was described to us as existing beneath the rubbish 
just where the road turns to the left round the house inhabited 
by a clergyman whose name we did not learn, but on the oppo- 
site side of the road. We, therefore, did not see the dyke in 
question. The rock has, in no inconsiderable degree, the aspect 
of a granular basalt, and ,though considerably hard, it yields to 
pressure with the knife a grey powder pretty readily. ‘The only 
discernible substances in it are extremely minute and_ slender 
crystals of transparent felspar, and sometimes cubic, sometimes 
octohedral crystals of magnetic iron pyrites, together with oeca- 
sional specks of a yellowish-white substance which appears to 
be laminated, but does not effervesce on the application of 
diluted muriatic acid. The base or imbedding substance is not 
sufficiently characterized to enable us to decide upon its nature; 
it is, however, considerably soft, and when reduced to thin frag- 
ments is translucent, of a slightly brownish hue, and contains 
extremely minute specks of a dark-green colour. It seems, how- 
ever, intimately connected with that of the mass constituting apart 
of the dyke about to be described. This dyke is situated in the 
small quarry called Simpson’s Pit, in a rock perfectly resembling 
that of Mount Sorrel, and about a mile SW of the town, at the 
head of Rothley Plain. It appears to run through the mound in 
which the quarry is situated nearly due N and 8, is visible for 
about 20 feet in height, is six feet wide at the lowest visible 
place, and somewhat narrower at the surface, is nearly perpen- 
dicular to the horizon, has very determinate walls, and reappears 
about one-fourth of a mile SW in a field occupied by the landlord 
of the Crown Inn at Mount Sorrel. The substance of this dyke 
as it appears in the quarry, is of a bluish cast, yields readily to 
the knife a grey powder, but is translucent in thin pieces, exbi- 
biting, by the assistance of the glass, a multitude of dark specks 
which appear occasionally to tinge the mass of a green colour ; 
it scratches glass feebly (a circumstance not anticipated from 
the use of the knife, and which may be owing to the presence 
here and there of minute and slender crystals of felspar, or of 
quartz too finely intermixed for observation), but its substance is 
left on the glass. The mass itself has somewhat the aspect of 
steatite, an aspect which is not to be observed where the dyke 
reappears below; here it very greatly resembles a granular 


1824.) the Rocks of Mount Sorrel, se, 9 


basalt, and is sufficiently hard’ to admit of a flat eonchoidal 
fracture ; it yields to the knife, though not without considerable 
pressure ; is of a dark colour, owing to the thorough intermix- 
ture of specks of a dark-green substance, and the slender crystals 
of felspar are innumerable ; but neither quartz nor any other 
mineral is to be detected even by the help of a highly magnify- 
ing glass. The rock in immediate contact with this dyke did not 
appear to have suffered any alteration, 

The rocks of Mount Sorrel are occasionally also traversed by 
small veins which more decidedly belong to the rock itself. 
These veins sometimes resemble granular felspar, sometimes 
granular quartz: they are always of a red hue: when of felspar, 
they appear to include minute specks of quartz, hornblende, and 
chlorite ; while those of quartz inclose crystals of quartz, felspar, 
hornblende, and iron pyrites. The veins of white or translucent 
quartz usually contain chlorite, and sometimes epidote. 

No appearances of regular stratification are to be observed in 
any of the quarries of this rock; at the western termination of 
their line at the back of the town, however, slabs of considera- 
ble dimension are procured, owing to the presence of nearly 
parallel fissures 4n two opposite directions, both being nearly 
vertical, and those producing the largest plane, running nearly 
due E and W. In the quarry at the other side of the hill, and 
due E of the windmill on its summit, are to be seen some natu- 
ral cleavages in various directions, which, without sufficient 
caution, might be mistaken for dykes. 


Of the Rocks of Charnwood Forest, 


The rocks ef the district of Charnwood Forest, coloured 
yellow in the accompanying sketch, differ greatly in respect of 
aspect and composition, and vary so greatly in their external 
characters, that although, from the circumstances attending 
them, it is impossible to doubt their common origin, there are 
varieties which, if taken separately, would, without previous 
acquaintance with them, be judged to be of very different ages, 
since eyen some of the proximate rocks appear to possess as 
little mineralogical affinity as chalk and flint. 

The greater part of these rocks are certainly schistose, but in 
degrees varying from a fissility apprcaching that of common slate 
to that of the rudest kind in which this seeming consequence of 
structure is to be perceived; even the most completely schistose 
varieties differ greatly in composition and external character ; 
while those that are least so often contain fragments of other 
substances which, perhaps, tend to characterise the whole (since 
all the varieties occur interstratified without any order), as belong- 
ing to that class of rocks which are denominated by Dr. 
Mac Culloch primitive slates; by others greywacke. And here 
it may be pertinent to remark, that in no instance was any trace 
of organic exuvie observed. 


10 Messrs. W. Phillips aud Kent on (JAN. 


- The slate which most nearly approaches that of Wales in 
colour and general characters is found in a small quarry at the 
eastern extremity of Woodhouse Eaves, but it is not so fine, and 
is less fissile. ‘The still coarser varieties of the several quarries 
near Swithland are preferred as roofing slates, though rarely less 
than one-fourth of an inch in thickness, and frequently varying 
to half an inch, being of unequal thickness throughout, with a 
surface often undulating, though ‘ at odd times,’ as the quarry- 
men expressed it, they are reduced to one-eighth of an inch. 
These slates are split by the workman while in a standing posi- 
tion, the slate being supported by one band covered by leather, 
and also by the arm ; while it is struck on the upper end by the 
other hand, with the edge of a sharp instrument, in form resem- 
bling a cooper’s adze. ‘The general hue of these slates is green- 
ish, and they readily yield to the knifea greyish powder, a cir- 
cumstance inducing the conclusion of their softness ; while, on 
the other hand, their edges cut window glass freely, showing 
them to be compounded of at least two substances differing 
greatly in respect of hardness. The reapplication of the point 
of the knife along the surface gently, and with the knife loosely 
held by-the hand, indicates the passing of the point from one 
hard substance to another through a softer, the line of. section 
becoming consequently irregular. The thin edges of the slate 
are translucent, when very. thin approaching to transparent in 
spots; and by transmitted light it becomes evident, that: the 
greenish hue of the slate is derived from the presence of a mul- 
titude of specks of a blackish-green colour, which we consider 
to be chlorite, because veins of that substance are frequently seen 
traversing, the slates in connexion with opaque quartz. The 
muriatic acid has no perceptible action on these slates ; and we 
conceive them to consist of a granular quartz, and of chlorite, 
imbedded in another mineral which. is considerably. soft: this 
we believe to consist of silex and alumine, in a schistose form, 
thus imparting its slaty character to the rock.. On examining 
these slates with a very powerful glass on ‘the fractured edges at 
right angles to the plane of cleavage, minute and brilliant sur- 
faces are perceived which have the aspect of transparent quartz. 
A vein of yellowish tale inclosing grains of quartz traverses the 
quarry at the extremity of Woodhouse Eaves. 

We have been the more particular in describing this slate, 
which is the prevailing one of the country, from the belief that 
all the varieties assumed by the rocks of this tract, are consti- 
tuted of the same materials, differing in their several proportions 
and state of aggregation ; of course we do not include the foreign 
substances. imbedded in some of the varieties, and which occa- 
sionally have the appearance of fragments, though we cannot 
doubt from .the composition and character, that some of the 
included masses are of contemporaneous formation with the 
rock itself. Hence it becomes requisite to give some account of 


1824.) - the Rocks of Mount Sorrel, &c. 11 


the various forms in which these substances appear. In some 
instances, the chlorite, instead of being disseminated through- 
out the mass, is arranged in irregular layers, thus imparting a 
schistose character to it(Windgate Hill, Great Bucks Hill, Xc.) 

Near Swithland are several quarries of the slate just described, 
one of which is estimated at 150 feet in length, and as much in 
breadth and depth. In all the quarries the run of the edge of 
the slaty cleavage is, as before related, NW by W, and SEby E, 
the broad surface of the slate dipping about 72° towards the NE, 
and it is to be remarked, that in each quarry, and particularly in 
the largest, there is a run of the best slate, about 15 feet wide, 
forming a kind of vein parallel with the direction of the cleavage, 
and flanked on each side by an inferior kind of slate; parallel 
also to this vein of superior slates, is another vein (if so it may 
be called) of a substance which is of a grey or greenish-grey 
colour, of a granular appearance, and consisting apparently of 
the imbedding substance or paste of the rocks of this district, in 
which chlorite is abundantly disseminated in particles and nests, 
and occasional specks of tale ; quartz, from its hardness, may 
be concluded to be ah ingredient of the mass, but is too small 
to be detected by the glass, and there is no appearance of 
texture. 

Other instances in which this substance assumes a granular 
appearance occur, and without any perceptible mineral imbedded 
in it (Hangingstones, Beacon Hill, &c.): sometimes it forms a 
ei of a dull-green colour, which appears nearly or altogether 

omogeneous, possessing a splintery fracture, and varying greatly 
in hardness (above Whittle Hill quarry, High Swanmore, Short 
Ciiff Hill); sometimes it is so soft as to yield readily to the 
knife ; and the quartz is so sparingly disseminated through it, 
that although it slightly scratches window glass, the substance 
itself is left upon it as a ‘grey powder (Hone-stone of Whittle 
Hill) ; in other instances, it is much harder, owing most proba- 
bly to the presence of a greater proportion of quartz, but still so 
minute as to escape the eye (Bird Hill, Beacon Hill, and other 
places) ; these varieties are generally fissile ; as well as others 
in which chlorite is perceptible as giving the greenish tint to the 
slate ; in others, the green colour is totally wanting; the sub- 
stance has then a yellowish tinge with every appearance of 
homogeneity, is frequently hard, sometimes so hard, owing to 
the abundant dissemination of siliceous particles throughout the 
mass, as to resist the knife, and it then assumes the aspect of 
compact felspar, or of hornstone (Bird Hill, base of Windgate 
Hill, &c.); but a substance of the same nature and degree of 
hardness'also occurs, which is considerably schistose, greatly 
resembles flinty slate, is greenish, arising, as is visible by trans- 
mitted light through thin fragments, from the presence of chlo- 
rite often disposed in irregular lines (Morley Hill quarry); All 
these varieties are more or less:slaty, and the Jamine have the 


12 Messrs, W. Phillips and Kent on [JAn. 


same direction and dip as the more perfect slates of the quarries ; 
but although they occur in layers varying from one-eighth of an 
inch to two inches in thickness, these layers have not the same 
direction as that of the cleayage; but this we shall presently 
deseribe. Mee : 

The preceding may be said to constitute the principal varie- 
ties of the imbedding substance or paste in what may be termed 
its purer state; in which, however, it is sometimes rendered 
irregularly slaty, by the intervention of layers of chlorite ; the 
substance then, as well as in some of the purer varieties, some- 
what resembles potstone. 

* The quartz which forms so important a feature of the slates, 
and which doubtless is more finely disseminated throughout the 
harder varieties of the rock in the state ofa mechanical mixture, 
occurs in two instances at least under very different circum- 
stances,; in one asa bed or vein of considerable dimension and 
extent, of granular quartz, having the aspect of quartz rock, and 
consisting apparently of grains of pure and nearly transparent 
quartz closely and strongly aggregated without any intervenin 
cement ; this bed or vein occurs in Grooby Park, and appeare: 
to us to run in the direction of the slaty cleavage observable in 
the quarries and elsewhere, and with the same dip. Slates were 
observable on each side, though not in close contact with it. 
In the other instance, compact quartz of a green colour, and 
which but for the translucency of the edges might be mistaken 
for green jasper, exists in layers in a large mass in a field behind 
the last house of Newton Linford, which is most distant from 
Grooby. It lies immediately between layers of the granular 
looking varieties of the coarse slates before described, and with- 
out any precise line of demarcation. But this rock will be more 
fully described in adverting to the subject of the stratification of 
the rocks of this district. 

- Hitherto we have not mentioned these rocks in their more 
ordinary state of porphyries ; the aspect of these differs greatly 
in different places ; but whatsoever their nature may be, they 
are usually found connected with those we have already described, 
and generally in layers alternating with them without any regu- 
lar order of succession. Sometimes, however, they appear to 
form almost exclusively the rocky eminences, already described 
as receiving each its'own individual name, and especially those 
of the western part of the forest, near to Thrinkston. 

The imbedded substances of the porphyritic rocks are various ; 
these consist of transparent crystals of quartz, which generally 
are small, or of translucent crystals of felspar, often very minute, 
and which frequently are macles, or hemitrope crystals, and also 
of cleayelandite ; these substances occur either separately 
(Broad Hill, Bardon Hill, &c.) or together in the same mass 
(High Swanmore, High Sharpless, &c.) and they are rarely 
abundant. Not unfrequently, however, instead of regular 


1824.] the Rocks of Mount Sorrel, &. 13 


érystals, we find small angular fragments of qtiartz (base of 
High Swanmore, &c.) which, when the surface of the imbedding 
Substance is somewhat decomposed into a white or greyish- 
white and granular mass, of which the particles possess but little 
cohesion, are left protruding. In othier iistances the fragments 
of quartz are intermixed with the regular crystals of quart and fel- 
spar (High Swanmore, &c.). But the imbedded fragmetits some- 
times possess all the characters of the slate already desctibed 
as including irregular lines of chlorite, and as forming layers 
between the other varieties of the rock (Morley Hill quarry), ot 
they resemble a reddish jasper which mostly is very hard, some- 
times brittle (tidge of Bardon Hill), and occasionally other an- 
gular fragments appear of less decided character. It is, how- 
ever, manifest to us, that the imbedded substance occasionally 
differs greatly from any of the preceding, in possessing altoge- 
ther the appearance of some of the more- homogeneous and 
greyish varieties of the rock itself, but much harder, and inclos- 
ing transparent crystals of quartz, and occasionally of felspat ; 
these occur in nodules, varying from the size of a nut fo several 
inches in diameter (Chamber Hill, Pedler Hill, ridge of Bardon 
Hill); and though they may be separated from the rock from 
which they project owing to the progress of its decomposition, 
yet there does not appear to be any precise line of separation 
etween them; these, therefore, we consider to be of contem- 
poraneous formation with the rock itself, as also may those 
numerous specks and patches be, which at fitst sight appear like 
imbedded fragments, but in reality present no line of separation 
from the rock itself, and are generally harder ; they are of various 
colours, grey, brown, or red (SW foot of Beacon Hill, High 
Sharpless, Little Gun Hill, &c.) , 

The paste of these porphyries consists of all the varietiés of 
the slaty rocks already described; but occasionally is mach 
harder than any of them, since it resists the knife completely, 
Owing, as we assume, to the mechanical diffusion of silex abun- 
dantly throughout the mass, which then partakes little or not at 
all of the schistose character (base of Windgate Hill, Pedlet 
Hill, &c.) and resembles hornstone or compact felspar. % 


In regard to the actual stratification of the rocks of Charn- 
wood Forest, two opposite appearances claim attention. 

It has been mentioned that the direction of the cleavage of 
the slates and slaty rocks is everywhere nearly the same ; that 
the edges of the slates uniformly run within a point or two of 
NW by W, and SE by E; and that the only difference is 
eeearent in their more nearly approaching NW andSE. It has 
also been mentioned, that in the largest quarry near Swithland, 
a seam of the best slates runs in this direction, and parallel with 
it a seam or vein of rock, quite different from the slate ; that in 
the quarry close to Woodhouse Eaves, a seam or vein of talc 


14 Messrs. Ws Phillips and Kent on (JAN: 


inclosing grains of quartz, takes the same course, and we may 
add that on Old John Hill, in Grooby Park, and in other places, 
some of the varieties of the slaty rocks obviously et each 
other under the same circumstances. In Hind’s new quarry 
near Swithland, and in the quarry near Woodhouse Eaves, the 
course of the best slates, which, in both cases, is about 12 feet 
wide, is not parallel to the cleavage, but crosses it in both cases 
at about the same angle, which, however, we did not ascertain. 

We have also mentioned that the rocks of particular parts of 
this district are banded of various colours, dependant, as we 
assume, on examination, upon the quantity of chlorite, which 
we have no doubt is the colouring substance of these rocks 
generally, whenever, as is mostly the case, the hue is green or 
greenish. These differently coloured bands or layers are disposed 
with the utmost regularity parallel to each other, and vary from 
the 16th of an inch, or even less, to some inches in thickness, 
and the slaty rocks thus disposed comprehend almost every 
yariety found in the district. This appearance is particularly 
obvious on Morley Hill, in the northern part of the district, on 
the hill called Hanging Rocks on the eastern, on Old John Hill, 
on the south-eastern ; while on the western side, as for some dist- 
ance on the north of Whitwick, the rocks possess this character. 
in a less degree, and there is more confusion apparent among 
them from the operation of external causes having left large 
blocks piled in the rudest manner on each other. 

Although these bands or layers are visible in the rocks of 
several other hills besides those just mentioned, we select them 
because, though there is a perfect uniformity on each hill, in 
the dip and direction of the bands, each ditfers from the other in 
these respects. On Morley Hill, the dip is 45° to the N; on 
the Hanging Rocks it is 45° to the E, and on Old John Hill 32° 
to the 8S, but that of the rocks at the foot of it are 45°. It is 
worthy of note, therefore, that as these several hills are situated 
on the extremes or outer edges of the tract, the bands of each 
dip away from the centre; and if these regular layers he 
taken as the order of deposit, and, therefore, as regular stratifi- 
cation, they tend to show it to have taken place in the mantle- 
shaped form. 

But in whatever direction these layers may dip, it is remarka- 
ble that the dip and direction of the more slaty parts of the rock 
is invariably as above quoted, and it is impossible to exhibit a 
more striking instance of this fact, than is manifest in a rock 
situated in a field at the south-western foot of Old John Hill, 
and immediately behind the last house in Newton Linford, 


° 


1824.) the Rocks of Mount Sorrel, &c. 16 


This rock, represented by the above sketch, is about 12 feet 
high, and is constituted of alternate layers of green or greenish 
rocks more or less slaty (SR), and of blue slates (S) ; the central 
band consists, as do certain of the others, of some of the more 
granular looking varieties of rock, alternating with that which has 
already been described as greatly resembling a green jasper; 
there is no precise line of demarcation between them, nor does 
there appear to be any schistose structure parallel with these 
bands, except what is produced by long exposure to the atmo- 
sphere, which acts of course differently on substantes appa- 
rently composed of very different materials, or, more accurately 
spea ing perhaps, of the same materials in very different propor- 
tion, and consequent state of aggregation. The bands here, as 
near the summit of the hill, dip to the 8S, but the angle differs ; 
above it is 32°, here it is 45°; the cleavage of the slates, how- 
ever, which are interstratified with the rock, is in another direc- 
tion, being perfectly consistent with that of the actual slates in 
all other parts of the tract; namely, 72° to the NE; and it is 
remarkable that the weathering of the rocks lying between the 
slates has a tendency to separate them chiefly in the same 
direction. 

The weathering of these rocks, however, when composed of 
more uniform materials, is too striking in one or two cases to be 
passed over in silence. The masses chiefly seen on the hill 
termed the Hanging Rocks, have almost altogether the form of 
tetrahedrons, from two to six or eight feet high resting on the 
base, and having one plane constantly dipping towards the E at 
an angle of 45°, and this plane is parallel to the variously 
coloured bands of which the whole mass is constituted, and 
which in some cases have separated by the action of the atmo- 
sphere upon them. The other instance is on the summit of 

eacon Hill: here the action has been carried still further: a 


16 Messr3 W. Phillips and Kent on [Jan. 
single rock about eight feet high stands in the form of a doubly 
oblique prism, of which only the base is beneath the surface. 


This prism is traversed by crevices, or by indications of them 
matked by imperfect lines parallel to all its planes ; and so com- 
plete has been the action of the elements in some parts of this 
rock, that we succeeded in extricating from it some natural 
fragments in the form of the rock itself. This rock consists of 
bands of somewhat different colours lying parallel to the upper 
plane, and dipping towards the E at an angle of 45°; these 

ands differ but little in character, being mostly of the mote gra- 
nular-looking varieties, and considerably hard. Close to this 
rock are several others of less dimension, but of the same form, 
atid whose upper planes dip at the same angle. It remains to 
bé added that we found the only cleavage practicable by mecha- 
nical force, though somewhat obscure, is in this rock parallel to 
the ordinary cleavage of the slaty rocks of the country, and, 
therefore, parallel to one of the sides of the prism, visible in the 
preceding sketch. This, however, is one among a multitude of 
proofs visible in various parts of the forest, that although no 
other cleavage is attainable by mechanical means than that 
which has so often been alluded to, yet a long exposure to the 
elements produces similar effects in another direction; and 
hence are to be observed in various places, rhombic prisms of 
this rock, but the angles at which the planes meet, are by no 
means constant, and where the rock is not banded, as it is in 
the above instance, the upper plane is altogether wanting. 

In conclusion it may be observed, that although in several 
instances (some of which have been quoted) these rocks 
appeared to be stratified parallel to the cleavage plane—that is 
to say, some of its varieties succeed each other in that direc- 
tion, yet we are disposed to believe from examination, that the 
stratification, which may be termed the order in which these rocks 
were deposited, is in fact parallel to the variously coloured bands, 


1824.]} the Rocks of Mount Sorrel, &c. 17 


which always are in a direction different to that of the cleavage 
plane of the slates—never at right angles to it. 


It is impossible to view the rocks of Charnwood Forest either 
an situ, or in hand specimens, without being forcibly struck with 
their resemblance to several of those in many parts of North 
Wales. The less perfect slates lying between the granular- 
looking and imperfectly slaty rocks above Nantfrancon quarry, 
almost perfectly resemble the coarse slates of the Swithland 
quarries ; while in several of the granular varieties of the rocks 
of the two tracts, the resemblance is absolutely perfect. Chlo- 
rite is abundant, and appears to be the colouring matter of both; 
and both include small crystals of transparent quartz and of 
felspar, when the rock is very coarsely slaty. In Charnwood 
Forest, however, we perceived in many places layers containing 
angular fragments of quartz, and which are left adhering to the 
surface, owing to the decomposition of the rocks, which in that 
state, like those of Wales, are of a greyish-white colour. In Wales, 
however, the included fragments, which alone may suffice to 
characterize tle whole series of Charnwood as belonging to grey- 
wacke, have not yet been describedas occurring, though from the 
very great similarity of its rocks and coarser slates to of those the 
Forest, they may probably hereafter be discovered; for in 
Wales the fragments hitherto observed in its rocks appear to be 
chiefly confined toa slaty substance, not unlike flinty slate, and 
which is actually found zn situ between layers of the rock itself ; 
the same substance, as well as the nodules which appear to be 
contemporaneous with the rock, is likewise found in Charnwood 
Forest. 

If, however, the characters of the rocks of some parts of 
North Wales should hereafter decide them to be greywacke, 
there are others in which the characters seem so absolutely 
talcose, that it may be found difficult to assign the whole to one 
common origin, and equally so to separate them, on account of 
the close connexion of the whole as regards position and the 
constant direction of the slaty cleavage through all the varieties. 
In Wales this direction is about NE and SW, the slates being 
either vertical, or dip at an angle of about 72° to the NW or 
SE; while in Charnwood Forest the upper edge of the slate 
always runs about NW by W, and SE by E, dipping uniformly 
about 72° a little to the east of N. 

Assuming the direction of the variously coloured layers so 
obvious in many parts of Charnwood Forest, to be that of the 
stratification, which, perhaps, will scarcely be doubted, and 
which, as has already been said, differs in different parts of the 
tract, it may be remarked that this has not been observed in the 
same degree in North Wales, although it is sufficiently visible 
near the summit of the Cleweth, a point but little imferior in 
elevation to that of Snowdon itself. 

New Series, vou, vit c 


13 Messrs. Wi Phillips and. Kent on (Jani 


Rocks of Grooby and its Neighbourhood. 


Considering the nature of these rocks, which appear to belong 
to the trap family, it would have been especially desirable to 
have perceived their connexion either with those of the forest, 
or of Mount Sorrel, to neither of which do they seem to possess 
any affinity; but although we anxiously sought the junction, 
there did not appear any opportunity of perceiving it. Owing 
to the causes before mentioned, we did not observe any place 
where their approach appears on the surface nearer than about 
one-fourth of a mile, as on the north of Markfield Knowl, which 
‘ consists of trap. It is remarkable that when this knowl is 
viewed from the road from Grooby to Markfield, and just before 
it turns southwards to that place, five ridges of the trap rock are 
perceived running down its side in the direction of the slaty 
cleavage of the rocks of Charnwood. We mention this fact as 
it exists, without any suspicion of its cause, or that these rocks 
have any connexion with slates of any kind, and especially with 
those of the forest; the spaces between the ridges are covered 
by a thick herbage. 

About one-fourth of a mile on the north of the lower extre- 
mity of these ridges is a quarry beside the road from Grooby to 
Thrinkston, and called Round Cliff Pit, in which the rocks of 
Charnwood are broken for the purposes of the road, and which 
here are traversed by veins of a yellowish-green substance, 
which, from its hardness, and from the forms of some minute 
crystals observed in crevices of the rock, we consider to be 
epidote. The space between this quarry and the termination of 
the ridges of trap at the foot of Markfield Knowl, is, however, 
covered by grass, or by cultivated soil, except the small part 
occupied by the road. 

We observed this rock but partially ; namely, on the N in 
Bradgate Park ; thence by Grooby Pool to Grooby, and from 
the latter place by Markfield to Markfield Knowl; but these 
rocks extend, according to Mr. Greenough’s map, 8 and SW of 
the latter place, above two miles. 

This rock consists primarily of hornblende often distinctly 
laminated, intermixed with small masses, never exceeding the 
size of a pea, of a reddish substance, often greatly possessing 
the aspect of compact felspar, the fractured surfaces being com- 
monly without lustre; these two ingredients constitute the rock 
in about equal proportions ; in other instances the red felspar (if 
so it may be termed) has a distinct though not brilliant cleavage, 
but only in one direction. With the reddish substance is often 
associated another, either of a light or bottle-green colour, of 
which the surfaces are more brilliant than those of the former, 
and we succeeded in detaching several fragments, having cleav- 
ages at least in two directions, but scarcely bright enough for 
the use of the reflective goniometer: one of them, however, 


1824.] the Rocks of Mount Sorre/, &c. 19 


afforded, by several trials, an angle so very near to one belong- 
ing to cleavelandite, and which of course does not belong to 
felspar, that we have scarcely a doubt of the existence of the 
former mineral in this rock also; the green crystals are some- 
times obviously included in those of a red colour; and we con- 
ceive it to be not improbable, that the close intermixture of these 
two minerals in that which is termed compact felspar, will 
account for the presence of soda and potash, both of which, it is 
observed by Dr. Mac Culloch, are constant ingredients of that 
substance. Both the red and green varieties yield to pressure 
with a hard mineralogical knife, the green being somewhat the 
softer of the two, and therefore appear to be less hard than 
felspar usually is: sometimes this rock contains minute, slender, 
and transparent crystals, which, from their superior hardness, 
we consider to be felspar, and specks of green or of yellowish 
steatite, and oxidulous iron in minute regular octohedrons; 
quartz is a frequent ingredient; mica and epidote occur more 
rarely ; in the quarry W of Grooby, we observed the rock 
traversed by veins, in one instance two inches thick, of a hard 
flesh-coloured substance, which may be cleaved into curvilinear 
thomboids, in the cavities of which were minute crystals in that 
form ; and as these crystals, and the substance including them, 
effervesce slightly, and dissolve slowly in diluted muriatic acid, 
and as the crystals afforded angles of about 106° 30’ by the 
reflective goniometer, we conclude them to be magnesian car- 
bonate of lime. The sides of the veins are coated with chlorite, 
which also is included in the vein itself. 

In the quarry on the E of Grooby, we perceived a vein of 
quartz and chlorite, and some appearance of the rock being 
traversed by a dyke ina N and S direction, but in too rude a 
manner for us to ascertain the fact, the walls, or what we con- 
ceived to be such, being very irregular and indeterminate, and 
the substance of the supposed dyke being composed of the same 
materials as the rock inclosing it, but much finer grained. 

Although the connexion of these rocks with those of Charn- 
wood Forest was not perceived, we consider it to. be worthy of 
note, that after descending the south-western slope of Beacon 
Hill, and traversing a field at its base, we found, beside a’small 
brook, some rocks of very considerable dimension, and which 
we fully believed to be in situ, so perfectly resembling those of 

-Grooby, that it was impossible to doubt their identity of compo- 
sition ; and it may be remarked that fragments of the same rock 
almost constitute the walls of the neighbouring fields. Whether 
this rock be a dyke, or in what manner it is connected with the 
forest rocks of the surrounding elevations, we had no means of 
ascertaining, since it is the only one which overtops the herbage 
in this comparatively low situation. rivevienine 


ec 


20 - Mr. Brooke onthe [Jan. 


ARTICLE II. 


On the Crystalline Forms of Artificial Salts, 
By H.J. Brooke, Esq. FRS. 


(Continued from vol. vi. p. 439.) 


Ir has been suggested to me that these descriptions of the 
crystalline forms of the salts ought to be accompanied by an 
exact analysis of each, in order to avoid the chance of misnomer, 
and to render the description of each complete. It certainly 
would be more satisfactory to know the composition of the salts 
described. This cannot, however, be conveniently given with 
the figures, but I have stated generally the authority upon 
which they have been severally named, and they may at any 
time be compared with the forms of ascertained compounds, 


Sulphate of Potash. 


The primary form of this salt was, I believe, first determined 
Ay Mr. Levy to be a right rhombic prism, and described in 

o. 80 of the Royal Institution Journal; but probably from not 
possessing sufficiently explanatory crystals, Mr. L. has not 
pointed out the relation of its primary form to the bi-pyramidal 
figure under which it generally occurs. 

I have been enabled to do this in a 
very satisfactory manner by means of a 
compound crystal which | have obtained 
from the solution of a portion of this salt 
in distilled water. 

Fig 1. is a single modified crystal. 


MonM’.,..... VIO BOS 
M On feo. ain .ad xvi, 8120 145 
Mionel 08 oi 2k 640. 94H 92D 
Mbodeavols maton 146 10 
e.0nte sd ..UN i eB 22 


Fig. 2 is the compound crystal, which 
consists of three single crystals, so united 
that their upper edges meet at angles of 
120°, and consequently their planes of 
junction incline to each other at the same 
‘angle. Hence 


LS: 1192.80’ 
COME Men tics sie heed LOU, oe 


1824.) Crystalline Forms of Artificial Salts. 21 


Fig. 3 is one of the common bi-pyramidal 
crystals, whose relation to the preceding 
figures may be perceived from the corres- Fig. 3. 
ponding letters on the planes. 

The union of these three crystals at an 
angle of 120° is a fact which requires some 
little explanation. 

It has been hitherto supposed, that when 
crystals mutually ¢ntersect or penetrate each 
other, the planes of intersection are parallel 
to the primary planes, or to secondary planes 
resulting from some simple law of decre- 
ment. And the theoretic order of arrange- 
ment of the molecules of crystals seems to require this mode of 
combination in intersecting crystals. But the union of the three 
crystals which compose fig. 2 is probably the result of simple 
accretion, in the same manner as crystals of different substances 
are found adhering strongly together by the close apposition of 
their surfaces; with this distinction. however between the two 
cases, that the union of the crystals in fig. 2 is the result of some 
law which does not govern the accidental union of heterogene- 
ous crystals, nor always even of homogeneous ones. 

I have been led to this conclusion relative to the structure of 
these by-pyramidal crystals, from having observed an apparently 
intersected crystal of chrysoberil, separate easily into six seg- 
ments, the planes of section being sufficiently bright for measute- 
ment with the reflective goniometer, and inclining to each other 
at an angle of 60°. 


Sulphate of Soda. 


I do not find any distinct cleavage in the 
crystals of this salt, whose primary form is 
an oblique rhombic prism. 


Poon: M, oi Moo «<» wh 301° 20’ 
Pgh: O8 25 Aa stewhie A3B),.48 
Brant hh. dsichy eles «i OY), 44. 
Dione! sats 20 20> seereréy BAO gti 
My om ii-e 0% & oes ne ore 9 BO, 424. 
Mion fi) -palewad. we 490.142 
Mom | said mano ou £00262, 138 
DI onde caterv ews gots 1389 1148 


Nitrate of Lead.—Nitrate of Barytes. 


The primary form of these salts is @ regular octahedron, but 
the crystals are commonly so much flattened in one direction 
that their relation to the primary form is not very apparent. 


28 


Fig. 1 is the regular primary crystal resting on one of its 
planes, and having its solid angles truncated. 


ab 40 ee te Guile mck 109° 28’ 
OMB? ca Gos Matin bite ahkids Cee 


Fig. 2 is the more common shape of the secondary crystals, 
resulting from a disproportionate extension of some of their 
planes, 


Articie III. 


On a new Phenomenon of Electromagnetism, By Sir Humphry 
“ht Bart. Pres. RS.* 


Ox a subject so obscure as electromagnetism, and connected 
by analogies more or less distinct with the doctrines of heat, 
light, electricity, and chemical attraction, it is not difficult to 
frame hypotheses; but the science is in a state too near its 
infancy to expect the developement of any satisfactory theory ; 
and its progress can only be ensured by new facts and experi- 
ments, which may prepare the way for extensive and general 
reasonings upon its principles. Influenced by this opinion, I 
am induced to lay before the Society an account of an electro- 
magnetic phenomenon I observed about fifteen months ago in 
the laboratory of the Royal Institution, and which I have lately 
had an occasion of witnessing in a more perfeet manner, through 
the kindness of Mr. Pepys, by the use of a large battery, con- 
structed under his directions for the London Institution, and 
containing a pair of plates of about 200 square feet. In describ- 
ing this phenomenon, I shall not enter into very minute details, 
because the experiments, which led to the discovery of it, are 
very simple, and, though more distinct with a large apparatus, 
yet it may be observed by the use of a pair of plates containing 
‘from ten to fifteen square feet. r 
» Immediately after Mr. Faraday had published his ingenious 


- ‘ 


+ From the Philosophical Transactions for 1823, Part II. 


.1824.] new Phenomenon of Electromagnetism. 23 


experiments on electromagnetic rotation, I was induced to try 
the action of a magnet on mercury connected in the electrical 
circuit, hoping that, in this case, as there was no mechanical 
suspension of the conductor, the appearances would be exhibited 
in their most simple form; and I found that when two wires were 
placed in a basin of mercury perpendicular to the surface, and 
in the voltaic circuit of a battery with large plates ; and the pole 
of a powerful magnet held either above or below the wires, the 
mercury immediately began to revolve round the wire as an axis, 
according to the common circumstances of electromagnetic 
rotation, and with a velocity exceedingly increased when the 
opposite poles of two magnets were used, one above, the other 
below. 

Masses of mercury of several inches in diameter were set in 
motion, and made to revolve in this manner, whenever the pole 
of the magnet was held near the perpendicular of the wire ; but 
when the pole was held above the mercury between the two 
wires, the circular motion ceased ; and currents took place in 
the mercury in opposite directions, one to the right, and the 
other to the left of the magnet. These circumstances, and 
various others which it would be tedious to detail, induced me 
to believe that the passage of the electricity through the mer- 
cury produced motions independent of the action of the magnet ; 
and that the appearances which I have described were owing to 
a composition of forces. 

I endeavoured to ascertain the existence of these motions in 
the mercury, by covering its surface with weak acids ; and dif- 
fusing over it finely divided matter, such as the seeds of lycopo- 
dium, white oxide of mercury, &c. but without any distinct 
result. It then occurred to me, that from the position of the 
wires, currents, if they existed, must occur chiefly in the lower, 
and not the upper surface of the mercury; and I consequently 
inverted the form of the experiment. I had two copper wires, 
of about one-sixth of an inch in diameter, the extremities of 
which were flat and carefully polished, passed through two 
holes three inches apart in the bottom ofa glass basin, and per- 
pendicular to it ; they were cemented into the basin, and made 
non-conductors by sealing-wax, except at their polished ends ; 
the basin was then filled with mercury, which stood about a 
tenth or twelfth of an inch above the wires. The wires were 
now placed in a powerful voltaic circuit. The moment the con- 
tacts were made, the phenomenon, which is the principal object 
of this paper, occurred: the mercury was immediately seen in 
violent agitation ; its surface became elevated into a small cone 
above each of the wires ; waves flowed off in all directions from 
these cones; and the only point of rest was apparently where 
they met in the centre of the mercury between the two wires. 
On holding the pole of a powerful bar magnet at a considerable 
distance (some inches) above one of the cones, its apex was 


24 Sir H. Davy ona “PJan. 
‘diminished and its base extended : by lowering the pole further, 
these effects were still further increased, and the undulations 
were feebler. Ata smaller distance the surface of the mercury 
became plane ; and rotation slowly began round the wire. As 
the magnet approached, the rotation became more rapid, and 
when it was about half an inch above the mercury, a great 
‘depression of it was observed above the wire, and a vortex, 
which reached almost to the surface of the wire. 

In the first experiments which I made, the conical elevations 
or fountains of mercury were about the tenth or twelfth of an 
inch high, and the vortices apparently as low; but in the expe- 
riments made at the London Institution, the mercury being 
much higher above the wire, the elevations and depressions were 
much more considerable, amounting to the fifth or sixth of an 
inch. Of course, the rotation took place with either pole ofa 
magnet or either wire, or both together, according to the well- 
known circumstances which determine these effects. 

To ascertain whether the communication of heat diminishing 
the specific gravity of the mercury, had any share in these phe- 
nomena, I placed a delicate thermometer above one of the 
wires in the mercury, but there was no immediate elevation of 
temperature; the heat of the mercury gradually increased, as 
did that of the wires; but this increase was similar in every 
part of the circuit. 1 proved the same thing more distinctly, 
by making the whole apparatus a thermometer terminating in a 
fine tube filled with mercury. At the first instant that the mer- 
cury became electromagnetic, there was no increase of its 
volume. 

This phenomenon cannot be attributed to common electrical 
repulsion ; for in the electromagnetic circuit, similar electrified 
conductors do not repel, but attract each other ; and it is inthe 
case in which conductors in opposite states are brought near each 
other on surfaces of mercury, that repulsion takes place. 

Nor can the effect be referred to that kind of action which 
occurs when electricity passes from good into bad conductors, 
as in the phenomena of points electrified in air, as the follow- 
ing facts seem to prove. Steel wires were substituted for copper 
wires, and the appearances were the same in kind, and only less 
in degree ; without doubt, in consequence of a smaller quantity 
of electricity passing through the steel wires: and by comparing 
the conducting powers of equal cylinders of mercury and steel 
in glass tubes, by ascertaining the quantity of iron filings they 
attracted, it was found that the conducting powers of mercury 
were higher than those of steel; the first metal taking up 
fifty-eight grains of iron filings, and the second only thirty- 
seven. 

Again ; fused tin was substituted for mercury in a porcelain 
vessel into which wires of copper and steel were alternately 
ground and fixed: the elevations were produced as in the met- 


1824.) new Phenomenon of Electromagnetism. 25 


cury, and the phenomena of rotation by the magnet; and it was 
found by direct experiment, that the conducting powers of the 
tin, at and just before its point of fusion, did not perceptibly 
differ, and that they were much higher than those of mercury. 
Lastly, the communication was made from the battery by two 
tubes having nearly the same diameter as the wires filled with 
mercury, so that the electricity, for some inches before it entered 
the basin, passed through mercury; and still the appearances 
continued the same. 

. From the rapidity of the undulations round the points of the 
cones, [ thought they would put in motion any light. bodies 
placed above the mercury ; but I could not produce the slightest 
motion in a very light wheel hung on an axle; and when fine 
powders of any kind were strewed upon the surface, they merely 
underwent undulations, without any other change of place; and 
fine iron filings strewed on the top of the cone, arranged them- 
selves in right lines at right angles to the line joining the two 
wires, and remained stationary, even on the centre of the cone. 
The effect, therefore, is of a novel kind, and in one respect 
seems analogous to that of the tides. It would appear as if the 
passage of the electricity diminished the action of gravity on 
the mercury. And that there is no change of volume of the 
whole mass of the mercury appears from the experiment, p. 24 ; 
and this was shown likewise by inclosing the apparatus in a kind 
of manometer, terminating in a fine tube containing air inclosed 
by oil; and which, by its expansion or contraction, would have 
shown the slightest change of volume in the mercury: none 
however took place when the contacts were alternately made 
and broken, unless the circuit was uninterrupted for a sufficient 
time to communicate sensible heat to the mercury. 

This phenomenon, in which the same effects are produced at 
the two opposite poles, seems strongly opposed to the idea of 
the electromagnetic results being produced by the transition 
currents or motions of a single imponderable fluid. 

On the conjectural part of the subject I shall not however 
enter, for the reasons stated in the beginning of this paper; but 
iJ cannot with propriety conclude, without mentioning a circum- 
stance in the history of the progress of electromagnetism, 
which, though well known to many Fellows of this Society, has, 
I believe, never been made public, namely, that we owe to the 
sagacity of Dr. Wollaston, the first idea of the possibility of the 
rotations of the electromagnetic wire round its axis, by the 
approach of a magnet; and I witnessed, early in 1821, an 
unsuccessful experiment which he made to produce the effect 
in the laboratory of the Royal Institution. 


6 . v! Mr. Daniell’s Reply to g. (Jan. 


| ArTICLE IV. . 


A Reply to some Observations in the Review of An Essay upon 
the Constitution of the Atmosphere. By J. F. Daniell, FRS. 


(To the Editor of the Annals of Philosophy.) 


MY DEAR SIR, Gower-street, Dec. 10, 1823. 


In the review of my Essay upon the Constitution of the 
Atmosphere contained in the last number of the Annals, your 
correspondent Z appears to me to have fallen into some miscon- 
ceptions which I should be sorry to leave uncorrected in a work 
of so much authority. I therefore trust that you will do me the 
favour to spare me room for a short reply. : 

In the first place, it is objected to my theory, that “ it 
rests upon the sandy foundation of assumed partial changes of 
temperature in the higher regions of the atmosphere, of the ex- 
istence of which we have very insufficient evidence.” This 
assertion, [ must own, greatly astonishes me: for I certainly 
conceived that no meteorological fact rested upon better autho- 
rity. I thought it indeed to be so generally admitted, that I did 
not refer in my Essay to the particular observations upon which 
it is founded, but merely illustrated it by the observation of 
De Luc, of ‘the sudden rise of temperature accompanying the 
formation of clond at a great elevation. I might now appeal, I 
believe, to every ascent of every mountain, and every aerostatic 
voyage, during which the thermometer has been consulted ; for 
they all appear to me to agree in the same result. Among the 
latter, more purticularly, there are abundant instances in which, 
not only the temperature of the atmosphere has not followed 
the regular progression due to the density, but warm strata have 
been found interposed between cold, and cold between warm. 
I shall content myself, however, at present, with referring Z to 
the simultaneous registers kept at the summit of St. Bernard 
and at Geneva, and which are published every month in the 
Bibliothéque Universelle. He will there find that the difference 
of temperature between the two stations is perpetually varying, 
and that, although the changes oscillate round the point of equi- 
librium, the general law of the decrease for the altitude is only 
developed from a mean of many observations. 

The second objection is, “ that to evolve so much heat as 
would raise the temperature of a considerable mass of air, and 
cause it to diffuse itself rapidly into distant regions, would 
require the condensation of a greater quantity of aqueous vapour 
than is likely to be present in any given space, and also that 
this condensation should not be gradual, but should take place 


1824.) Mr. Daniell’s Reply to 2. 27 


suddenly to a very great amount.” From this extract I am 
almost tempted to believe that Z has not done me the honour to 
read my Essay, but on/y to review it. { have taken much pains 
to show at p. 31, e¢ seg. that such a sudden condensation ofa 
large quantity of vapour is not by any means requisite to pro- 
duce an effect upon the barometer, but on the contrary, that a 
gradual partial increase of temperature in the strata of an atmo- 
spheric column of only two degrees is sufficient to depress the 
mercury 0°63 in. If this part of my illustration should not have 
been overlooked, I can only at present join issue upon the 
opinion ; pledging myself to examine impartially and thankfully 
any argument which Z may hereafter bring against my con- 
clusions. 

My reviewer objects in the third place to an error into which 
not only myself but Mr. Leslie has fallen, viz. that the particles 
of air in passing over the surface of the globe do not for a 
moment cease to gravitate, and that no horizontal movement of 
them will produce the slighest derangement in a perpendicular 
direction. He observes, “ Now it is well known that any 
body, to which a projectile motion of five miles per second has 
been imparted, would revolve around the earth like a planet, and 
would cease to exert any pressure on its surface. Any less 
velocity must produce a proportional decrease of weight in the 
particles of air, which is known to move at the rate of from 60 to 
100 miles per hour.” 

_ As this argument, if correct, is indeed decisively subversive 
of my theory, I trust that I may be allowed to illustrate it some- 
what particularly. According to the proposition set forth by Z, 
a loaded waggon presses less upon the earth when at rest than 
when in motion upon the road! A steam boat must rise out of 
the water in proportion to the velocity communicated to it by its 
engine! ! And many vessels must doubtless have been upon the 
eine of upsetting from this ill-understood cause!!! To these 
‘bodies, it 1s true, we cannot communicate a projectile motion of 
five miles per second, but the former will move about five miles 
per hour, and the latter probably ten, and “ these lesser degrees 
of velocity must produce-a proportional decrease of weight.” 
Why a cannon ball indeed when projected from a gun does not 
‘mount in the air like a soap-bubble, is not quite obvious; for such 
a result one might undoubtedly expect from the theory of Z. 
But to be serious:—With a laudable desire of correcting my 
blunders, it is clear that the reviewer has fallen himself into an 
error of no trivial importance. It is not true that any body to 
which a projectile force of five miles per second has been 
imparted, would revolve around the earth like a planet, unless 
this motion were to take place in vacuo, and were unopposed by any 
pressure whatever: and no body that ever pressed at all upon the 
surface of the earth would cease to exert such pressure in con- 


28 Mr. Daniell’s Reply to 2. [JAN. 


sequence of any degree of projectile motion that might be com- 
municated to it. It is not for me to surmise in what way it can 
have been possible for your correspondent to confound together 
pressure and gravitation, but certain it is that the planets do 
not press upon the sun, nor the moon upon the earth. It isno 
less certain that all the particles of the atmosphere do press upon 
the earth, and, like the waggon upon the road, the vessel upon 
the water, or the cannon ball in the air, their weight is in no 
degree dependant upon their motion or rest. 
) These are the only objections brought forward by Z against 
my theory of the Constitution of the Atmosphere; but he 
“suggests that the third table in Part I. is founded-upon an 
erroneous principle.” In reply to this, I must observe that the 
tables in this part of my work were not meant to be accurate 
representations of the different states of the atmospheric columns, 
but mere rough approximations ; and their use 1s to assist the 
mind in following the train of reasoning in the same way that 
rudely-sketched diagrams assist the mathematician in solving a 
problem of Euclid. The principle upon which they were con- 
structed is this: I assumed the mean temperature of the latitude 
for which I wished to calculate the atmospheric column as the 
temperature of an homogeneous atmosphere; and I thence 
derived the pressures at different altitudes from the surface, and 
from these the regular decrease of temperature for the density. 
It is clear that for accurate purposes, both the pressures and 
temperatures so obtained require correction, and that the tables 
include an error which should be divided between the two, and 
does not fall wholly upon the pressure as suggested by Z. The 
labour of applying these corrections would have been very con- 
siderable; and the tables, which, even in their present state, 
cost me much pains, would not have better answered the pur- 
poses of illustration. 

In conclusion, I cannot but express my acknowledgments to 
Z for the general courtesy of his review, but am still inclined to 
appeal from his tribunal ; for I must own that my ambition 
cannot yet content itself with the somewhat meagre consolation 
which has been offered to me, that ‘ there can be no discredit 
to any one who fails to unfold the causes of phenomena which 
have been acknowledged by one of the first philosophers of 
the present times to have hitherto baffled all attempts to reduce 
them to fixed principles.” 

{ remain, dear Sir, yours most faithfully, 
J. F, DaNIELL. 


1824.] Col. Beaufoy’s Astronomical Observations, 29 


ARTICLE V. 


Astronomical Observations, 1823, 
By Col. Beaufoy, FRS. 


Bushey Heath, near Stanmore. 
Latitude 51° 37’ 44°3” North. Longitude West in time 1’ 20-93”, 


Dec. 7 Immersion of Jupiter’s third §¢ 9h 24’ 41” Mean Time at Bushey. 


BAVCINEC's ba slew cs2 0's = Pia 9 26 O02 Mean Time at Greenwich, 
Dec, 12. Immersion of Jupiter’s first ¢ 12 21 19 Mean Time at Bushey. 

Ratcllites |. $64 ce. a beyErsas 12 22 40 Mean Time at Greenwich, 
Dec, 12. Immersion of Jupiter’s second ¢ 14 17 04 Mean Time at Bushey. 

BAtciEC. Vcc cse aren dacces ; 14 18 25 Mean Time at Greenwich, 


A grievous error must exist in the time set down for the emersion of Jupiter’s third 
satellite, Dec. 7. : 

According to the Nautical Ephemeris, it should have taken place at 12h 27’ 01”; 
but after fruitlessly watching at the telescope until 144 29’, that is for more than two 
hours after the time specified, clouds relieved me from further attendance. 


ArticLe VI. 
On Lapulin, as a Medicine. By Nicholas Mill, Esq. 
(To the Editor of the Annals of Philosophy.) 


SIR, Bridge Cottage, Camberwell, Nov. 20, 1823. 


Havine noticed in an American journal the experiments of 
Dr. Ivesat New York onthe annon hop, and which appeared to 
me of considerable importance in medicine, I was induced to 
extend those inquiries, and apply the result, if beneficial, to prac- 
tice among my own particular friends. 

Preparations of the hop have been occasionally used in medi- 
cine in this country. The whole of the plant has usually been 
employed to form a tincture, but from the extraneous matter 
introduced by this means, it has doubtless rendered this medi- 
cine inert, if not prejudicial. Dr, Ives discovered that the true 
aromatic bitter of the hop resided solely in a pulverulent matter, 
which he called lupulin, for the collection, preparation, and 
administration of which 1 am about to give specific directions. 

Take any quantity of the best hops, and rub them strongly 
between the hands, or put them in a bag, and beat them for 
some time ; when the beating is completed, throw them ona 
coarse wire sieve, which will only suffer the dust, Xe. to pass 
it; let them be well rubbed on the sieve till every thing has 
gone through, except the leaves and stems of the plant ; reject 
the leaves and stems altogether, and sift what has already passed 


30. eo Mr. Millon Lupilin, (Jaw. 
the wire through a lawn sieve; nothing will now pass but a 
very fine powder resembling red sand: this is the lupulin in 
which the whole virtue of the hop resides. 

The preparations of this substance which I have found to be 
most efficacious are the decoction and tincture. 

The decoction may be made by putting a sufficient quantity 
of lupulin into a Florence flask, ina sand heat, and filling it three 
parts full with distilled water ; boil the whole for half an hour, 
and strain through cotton cloth. The solution thus obtained 
will be feculent, and does not become clear by repose ; therefore 
add, while hot, a small quantity of solution of gelatine in hot 
water; shake the whole together, and let it remain till cold, 
then filter through paper, and a clear yellow liquid will be 
obtained. It is intensely, but not unpleasantly bitter; and when 
administered in doses of a tea-spoonful at a time in a table 
spoonful of cold water, is a true stomachic, It is tonic, narcotic, 
and aromatic. It does not produce constipation of the bowels, 
as almost all other tonics do. It appears to act entirely on the 
nervous system, and may be prescribed with manifest advantage 
in all cases of debility and inaction of the digestive organs 
where powerful tonics would be injurious. 

The tincture may be prepared by digesting the lupulin in 
strong and warm alcohol, till saturated, when it must be filtered 
through paper, and a deep-red solution will be obtained. 

From 40 to 60 minims of this tincture act as an anodyne, and 
have a powerful effect in allaying great nervous irritation ; and 
that stupidity which often accompanies the use of opium, is never 
induced by this medicine. 

Tam, Sir, your obedient servant, 
Nicnuoras Mitt, 


raheatisieceneeanaiamianreds 
ArticLe VII. 


On the Methods of employing the various Tests proposed for 
detecting the Presence of Arsenic. By R. Phillips, FRS. &c. 


So much has at various times been offered to the public on 
the subject of ascertaining the presence of arsenic, whether 
taken from the stomachs, or mixed with the food of those who 
have fallen victims to its poisonous agency, that some apology 
may seem requisite for resuming the subject, more especially as 
it has lately been treated of in so able a manner by Dr. Paris, in 
his work on Medical Jurisprudence. My object on the present 
occasion is not to offer any new test for arsenic: what I propose 
is, to modify some of the methods of using the means already 
known, and to simplify their application. I shall not enter into 
any history of the various means which have been proposed, but 


1824.] Tests for detecting the Presence of Arsenic. >} 


confine myself to treating of the mode of employing the follow- 
ing tests ; viz. the reduction of the arsenious acid to its metallie 
state ; the use of sulphuretted ng doogenns sulphate of copper ; 
and nitrate of silver; and I hope to be able to describe 
the little apparatus required in such a manner as to remove 
some ambiguity and difficulty. 

It is justly observed by Dr. Paris (Jurisprudence, vol. ii. p. 
252), that ‘‘ the detection of the presence of arsenic amidst a 
complicated mass of alimentary matter has long been a problem 
of interest and difficulty,” because “ coloured fiuids are capable 
of obscuring and changing, and even altogether preventing the 
arsenical indications.” Dr. Paris then adverts to the proposal 
of M. Orfila to destroy or modify the colouring matter by means 
of chlorine; this method is justly stated to be liable to great 
difficulties in its application, and from sources too obvious to 
require notice. Dr. Paris, therefore, advises that a solution of 
ammoniuret of silver should be added to the fluid to precipitate 
indiscriminately all bodies which it may be capable of so affect- 
ing ; and then subjecting the precipitate to the action of black 
flux in a glass tube for the purpose of subliming the arsenic 
in its metallic state. 

On considering this part of the subject, it appeared to me that 
animal charcoal (ivory-black) might be advantageously employed 
for the purpose of destroying the colouring matter. I there- 
fore, mixed some of it with a coloured solution of arsenious 
acid, viz. the liquor arsenicalis of the London Pharmacopeia. 
I found that the colouring matter was so completely destroyed 
in a few minutes, that the test of nitrate of silver, or any other, 
might be readily applied. I repeated this experiment with port 
wine, gravy soup, and a strong infusion of onions *, and suc- 
ceeded in these cases in procuring a solution sufficiently co- 
lourless for the application of the most delicatetests. It might 
be supposed that the phosphoric acid which the animal charcoal 
contains might have some share in the production of the yellow 
precipitate with silver; I found, however, that water or wine 
which was merely digested on the animal charcoal, produced 
no effect with the nitrate of silver, excepting a slight precipitate 
of chloride; and to prevent this, the ivory-black should be 
washed on a filter with aap. distilled water, till the fluid run- 
ning through ceases to be affected by nitrate of silver. _ If, how- 
ever, the ivory-black is of good quality, this precaution is un- 
necessary. 


Of Sulphuretted Hydrogen. 


Supposing the substance suspected to contain arsenious acid, 
to have been boiled in distilled water without any alkali, and 
deprived of its colouring matter as now described, the test, to 


#7 particularly mention infusion of onions, because much stress has been laid upoh 
the ambiguity which its yellow colour may occasion. It immediately becomes colowrlests 
“Wee Paris and Fonblanque’s Med. Jurisprudence, yol, iii, p, 199.) hp 


ere Mr. R. Phillips on the [Jan. 


which it may at first be subjected is a solution of sulphuretted 
hydrogen gas in water. This is to be preferred to any coloured 
fluid containing sulphuretted hydrogen, such as the hydrosul- 
phuret, or, perhaps more properly, hydroguretted sulphuret of 
ammonia; for this fluid possesses the colour when diluted, 
which we expect to produce by the action of sulphuretted 
hydrogen upon arsenious acid. .The method of preparing this 
solution of the gas is perfectly simple. Put into an oil flask 
about two ounces of muriatic acid undiluted with water, and an 
ounce and a half of powdered sulphuret of antimony ; fit a cork 
to the flask, and pass through it the shorter leg of a small hollow 
glass tube twice bent at right angles; pass the longer leg of the 
tube into a vial containing distilled water, and then by the. heat 
of a spirit-lamp applied to the flask, sulphuretted hydrogen gas 
will be readily procured, and though much of it will escape, yet 
a sufficient quantity will be dissolved by the water. If distilled. 
water cannot be procured, then rain water may be used, or if 
that be not at the moment obtainable, water, which has been 
boiled and become clear, must be substituted. The annexed cut 
will sufficiently explain this apparatus. : 


Ifa glass tube is not at hand, one may be readily formed of 
tin plate soldered. I have employed one for the purpose of 
trying the experiment, which was made in about an hour; the 
shorter leg may be about two inches and a half to three inches 
long; the intermediate space, and the longer leg, each six inches 
in length; the diameter may be about one-fourth of an inch ; 
this passed through the cork, and used instead of the glass one, 
answers the purpose perfectly, notwithstanding the tin is 
slightly acted upon by the gas during its passage, and by the 
solution in which it is immersed. 

To this solution, clear and colourless, add, in a wine glass, or 
a vial, some of the suspected fluid ; if it contain arsenious acid, 
a yellow-coloured fluid will be produced, and, after the lapse of 
some hours, a yellow precipitate will fall down. It has been 
objected to this test, that antimgny produces a similar appear- 


1824.) Tests for detecting the Presenceof Arsenic. 33 


ance; while, however, there exists some resemblance in the co- 
lours, there aré these differences in the effects; antimony furs 
nishes a precipitate immediately, and with more of an orange tint. 


Sulphate of Copper. 


Arsenious acid produces no effect upon a solution of sulphate 
of copper; but with the assistance of an alkali, a green precipi- 
tate of arsenite of copper is readily produced. It has been 
objected to this test, that a fallacious appearance is produced if 
the suspected solution be of a yellow colour; but for this case I 
have already provided. If the sulphate of copper be impure, 
owing to the presence of peroxide of iron, a greenish precipitate 
may also be obtained by simply adding potash to the solution. 
This test may be employed in two ways; first, add a few drops of 

_an alkaline solution, as potash or its sub-carbonate to the suspect- 
ed solution, and when mixed pour them into the sulphate of cop- 
per. If arsenious acid be present, a green precipitate will be form- 
ed; and there is a mode of removing any ambiguity which, if it 
does not escape my recollection, has not been previously noticed. 
To be certain that the sulphate of copper contains no peroxide 
of iron, add first to the solution some potash; if pure, a fine blue 
precipitate will be obtained ; to this add the suspected solution ; 
and if arsenious acid be present, then it will convert the blue 
precipitate to a green one. 


Nitrate of Silver. 


To confirm the results obtained by sulphuretted hydrogen and 
sulphate of copper, nitrate of silver is a test which may be very 
usefully employed. The first method is simply to add the sus- 
pected solution to one of nitrate of silver, which should be pre- 

ared either from the crystallized or fused nitrate (lunar caustic), 
in order that all excess of acid may be avoided. After the 
suspected solution has been mixed with that of silver, drop in 
a solution of ammonia or of potash, liquor ammonia, or liquor 
potasse of the London Pharmacopeeia; if arsenious acid be 
present, a bright-yellow precipitate of arsenite of silver will be 
formed, which is readily dissolved by excess either of ammonia 
or nitric acid; so that supposing too much ammonia to have 
been employed, nitric acid will restore the precipitate. Potash 
does not possess the inconvenience of ammonia in redissolving 
the arsenite of silver formed: but there is one inconvenience 
attending the use of silver; the animal fluids all contain mu- 
riatic ‘salts ; and, therefore, the fluid contents of the stomach 
will probably give a white precipitate of chloride of silver when 
mixed with the nitrate. If, however, the presence of arsenic 
has been determined by the use of the preceding tests, then 
the chloride and arsenite of silver must be precipitated together, 

New Series, vou. vit. D 


54 | Mr. R. Phillips on the [Jan. 


and the mixture, after being dried, must be subjected to the 
metallizing process, to be described presently. 

Nitrate of silver is liable to ambiguity, and on this subject I 
cannot do better than quote what Dr. Paris has stated in the 
work already alluded to, vol. ii. p. 241. 

“ The alkaline phosphates are found to produce precipitates 
with silver, analogous in colour and appearance to the arsenite 
of silver. This constituted one of the principal points in the 
evidence for the defence, on the trial of Donnall for the murder 
of Mrs. Downing; and it must be admitted as a valid objection, 
if the experiment be performed in the manner just stated ; but 
there are other reagents which will immediately distinguish these 
bodies, as we shall presently have occasion to state, under the 
history of the ammoniuret of silver, as a test for arsenic. The 
author has also shown, that there is a mode of so modifying the 
application of the present test, that no error or doubt can arise 
in the use of it, from the presence of any phosphoric salt. This 
method consists in conducting the trial on writing paper, instead 
of in glasses ; thus—drop the suspected fluid on a piece of white 

aper, making with it a broad line; along this line a stick of 
poo caustic is to be slowly drawn several times successively, 
when a streak is produced of a colour resembling that known by 
the name of Indian yellow; and this is equally produced by the 
presence of arsenic, and that of an alkaline phosphate, but the 
one from the former is rough, curdy, and flocculent, as if effect- 
ed by a crayon, that from the latter is homogeneous and uniform, 
resembling a water-colour laid smoothly on with a brush ; but a 
more important and distinctive peculiarity soon succeeds, for in 
less than two minutes the phosphoric yellow fades into a sad 
green, and becomes gradually darker, and ultimately quite 
black ; while, on the other hand, the arsenical yellow remains 

ermanent, or nearly so, for some time, when it becomes brown. 

n performing this experiment, the sunshine should be avoided, 
or the transitions of colour will take place too rapidly. It would 
be also prudent for the inexperienced operator to perform a simi- 
lar experiment on a fluid known to contain arsenic, and on 
another with a phosphoric salt, as a standard of comparison.” 

The ambiguity arising from the use of nitrate of silver has 
also been most satisfactorily obviated by Mr. Smithson (Annals 
of Philosophy, Aug. 1822). This method consists in converting 
the arsenious into arsenic acid, or rather into arseniate of 
potash; and Mr. S. observes, “ that a drop of a solution of 
oxide of arsenic in water, which at a heat of 54°5° of Fahr. con- 
tains not above 1-80th of oxide of arsenic, put to nitrate of 
potash in the platina spoon and fused, affords a considerable 
quantity of arseniate of silver. Hence when no solid particle of 
oxide of arsenic can be obtained, the presence of it may be 
established by infusing in water the matters contained in it.” 


1824.] Tests for detecting the Presence of Arsenic. 36 


Instead of using a platina spoon, a glass tube, or the bottom of an 
oil flask, may be employed ; into either of these, put a little of 
the suspected solution, and which has exhibited indications of the 
presence of arsenic by other tests; then drop in a small crystal 
of nitre, evaporate the solution to dryness by means of a spirit- 
lamp, and afterwards heat it strongly in the same way. Adda 
little distilled water to the residuum, dissolve it, and then add 
nitrate of silver; if the solution before heating contained arse- 
nious acid, it will now contain arseniate of potash, which will 
give a brick red precipitate with the nitrate of silver, and with- 
out the intervention of any alkali. From repeated trials, I con- 
sider the confirmatory evidence afforded by this experiment as 
amounting almost to demonstration. ‘This experiment is ren~ 
dered shorter, and not less conclusive, by employing the arse- 
nious acid and nitre both in the state of powder; but as the 
former is not always procurable after fatal effects have been 
produced by it, I have mentioned the solution as affording very 
satisfactory results. 

I shall now mention the method of confirming the previous 
experiments by reducing the arsenious acid to its metallic state. 
If the quantity of arsenious acid procurable be very small, then 
it is proper to dissolve the whole of it in distilled water, and the 
precipitates which are obtained by the action of the various 
reagents should be collected and submitted to the metallizing 
process ; but if the quantity of arsenious acid be so large that a 
few grains, or not less than one grain, can be spared for metalli- 
zation, then the precipitates may be rejected, and much trouble 
will be spared. 

This process is thus recommended to be performed by Dr. 
Paris, in his work before alluded to, vol. 11. p. 233 :— 

“« Mix a portion of the suspected substance in powder, with 
three times its weight of black flux ;* put the mixture into a thin 
glass tube, about eight inches in length, and a quarter of an inch 
in diameter, and whichis hermetically sealed at one end. Should 
any of the powder adhere to the sides of the tube, it must be 
carefully brushed off with a feather, so that the ner surface of 
its upper part may be perfectly clean and dry. The closed end 
of the tube, by way of security, may be thinly coated with a mix- 
ture of pipe-clay and sand; but this operation is not absolutely 
necessary. The open extremity of the tube is to be loosely 
plugged with a piece of paper. The coated end must now be 
submitted to the action of heat, by placing it in a chafling dish 
of red-hot coals, for ten minutes, or a quarter of an hour ; when, 
if our supposition respecting the nature of the substance has 
been correct, metallic arsenic will sublime, and be found lining 
the upper part of the tube with a brilliant metallic crust. The 


* This substance may be said to consist of charcoal in a state of extremely minute 
division, and the subcarbonate of potash. It is prepared by deflagrating, in a crucible, 
two parts of supertartrate of potash with one part of nitrate of potash. 

D2 


36 Tests for detecting the Presence of Arsenic, [JaN. 


glass tube, when cold, may be separated from its sealed end by 
the action ofa file, which will enable us to collect and examine 
the metallic sublimate. If a portion of this brilliant matter be 
laid on heated iron, it will indicate its nature by exhaling in 
dense fumes, having a powerful smell of garlic. Another por- 
tion should be reserved for future experiments. 

“This method of detecting the presence of arsenious acid has 
been considered the most decisive, and indeed the only unex- 
ceptionable one, but of this we shall speak hereafter ; at present 
we have only to observe, that it is very far from being a minute 
test; for Dr. Bostock confesses that where less than three- 
fourths of a grain were used, he could not say that the metallic 
crust was clearly perceptible; and Dr. Black appears to have 
considered that one grain was the smallest quantity which could 
be distinctly recognised by such a process.” ; 

This method is unquestionably excellent, but I have found 
that the metallization may be very conveniently effected by 
means ofa spirit-lamp. Indeed it may possibly happen that a 
glass tube, such as is requisite for the above process, cannot 
be procured at the moment in which it may be wanted; a 
spirit-lamp may also be wanting, I have adopted the fol- 
lowing plan: let a piece of tin plate, about an inch long, be 
coiled up into a cylinder of about 3-8ths of an inch in diameter, 
and if the edges be well hammered, it is not necessary to use 
solder. Perforate a cork previously fitted to a vial, and put a 
cotton wick through the short tin tube, and the tube through 
the cork, the lamp is now complete, and will afford a strong 
flame, taking care of course not to prevent the rise of the spirit 
by fitting the cork too closely. Instead ofa test tube about six 
inches in length, which however is certainly much to be prefer- 
red, I have employed, with the precautions copied from Dr. 
Paris, a common draught vial ; those best adapted for the pur- 
pose are called ten drachm vials, for they are long in proportion 
to their diameter. In using these vials, the suspected powder 
and black flux must not reach the bottom of the vial, for, on 
account of its thickness, it will readily break on the application 
of heat. The vial, therefore, must be heated laterally, the 
arsenic will readily sublime, and will, after the vial has been 
divided by a file, if heated in the spirit-lamp, give out the well- 
known alliaceous smell. Indeedif the quantity of arsenious 
acid be large, the smell which the volatilized metal affords may 
be resorted to in confirmation of other evidence ; but it is to be 
observed, that it must be mixed with charcoal, or some sub- 
stance which reduces it to the metallic state, for arsenious acid, 
though volatilized by heat, and exhibiting white fumes, does not 
give any smell. 

I have now concluded the sketch which [ proposed giving, 
and, if I mistake not, the use of animal charcoal in the mode 
described, will afford some facilities, I hope also that I have, 
in some degree, strengthened the evidence which is afforded by 


1824.] Corrections in Right Ascension. 37 


using sulphate of copper, and rendered the process of metalliza- 
tion less difficult by usmg common instruments, and such as are 
within the reach of every practitioner, or readily procurable by 
him. In concluding, I beg to refer the reader to the work on 
Medical Jurisprudence, to which I have been so largely indebted, 
as one which will afford him much and minute information on a 
subject of some difficulty, and of great importance. 


Articte VIII. 


Corrections in Right Ascension of 37 Stars of the Greenwich 
Catalogue, together with an Inquiry how far it would be advi- 

_ sable that the Daily Corrections in R.A and North Polar Dist- 
ance of the 46 Zero Stars should be computed Annually at the 
Public Expence. By James South, FRS. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Blackman-street, Dec. 18, 1823. 


Havine for some years principally devoted myself to the pur- 
suit of practical astronomy, | have seen with much zegret the 
various difficulties which the private observer has to contend 
with ; having also severely felt some of them, I have endeavoured 
occasionally to diminish them for others: knowing also that 
some of these auxiliaries have been used in the most important 
observatories in the country, and that to some private indivi- 
duals they have proved welcome, in the absence of others hav- 
ing stronger claims to confidence, I am induced to publish the 
corrections in right ascension of the 37 stars of the Greenwich 
catalogue, for every day of the year 1824. 

I had indulged a hope (as a reference to this journal two 
years ago will prove) that the daily corrections not only in Right 
Ascension, but also in North Polar distance, not only of the 37, 
but of the 46 Zero stars, would long since have made their 
appearance, under the sanction of a ont instituted expressly 
for the purpose of promoting astronomical science. As, how 
ever, these hopes are not realised, owing probably to the little 
want which most of its leading members have of such a publica- 
tion, it may be worth while to see whether a case cannot be 
made out sufficiently strong, to justify government in having 
such corrections computed, at the public expence. 

Our inquiry will then be divided into three parts ; first, what 
will be the probable benefits resulting from such a publication ; 
secondly, what the expence of procuring it; and lastly, how far 
the former is equivalent to the latter. In doing this it will be 
necessary to enter somewhat minutely into the matter, as there 
are many individuals, although perfectly conversant with the 
principles of astronomy, who have little idea of the routine of 
observatory business, 


38 Corrections in Right Ascension of [Jan. 


The province of the practical astronomer is to determine the 
apparent place of all sidereal bodies which come within the 
reach of his instruments, and to observe such phenomena as 
from time to time present themselves ; in the present instance, 
we shall confine ourselves to the former. It is scarcely neces- 
sary to mention, that by the place of any body in the sidereal 
heavens is understood its right ascension and north polar dist- 
ance; each is determined generally at the moment in which the 
object passes the meridian of the observer, by the aid of instru- 
ments fixed in its plane; the transit instrument (with its 
appendage, the clock) giving the former, while the quadrant or 
circle indicate the latter. 

But by the successive labours of Bradley, Maskelyne, and 
Pond, the places of 46 stars have been determined with extreme 
accuracy, these we consider as Zero points when we would 
assien to any celestial body, its right ascension or north polar 
distance. Accordingly the business of the practical astronomer 
among us, as far as right ascensions are concerned, is to secure 
ihe meridian passage of each of these stars, or as many of them 
as possible, and also of as many other stars, planets, or comets, 
as opportunity will allow ; he then finds the error of his clock 
by each Zero star, at the time of observation, thence deduces its 
mean error ata corresponding time; he next determines the 
clock’s daily rate by comparisons with previous observations of 
the same stars; and hence obtains a mean rate. With these 
materials he is now prepared, by the aid of a little calculation, to 
apply the clock’s error to each observed transit, and is thus fur- 
nished with the observed right ascension of each sidereal object 
at the time of its passing the meridian of his observatory. 

_ Of all these calculations, however, that whereby he arrives at 
the error of his clock is by far the most troublesome ; for before 
he can find its error by a single star, he must apply corrections 
to the star’s mean right ascension, brought up to the Ist of Jan. 
of the current year; and these he must seek by reference to the 
17th and 18th tables of Dr. Maskelyne’s ; the first of which 
cives him the sum of the corrections for aberration, precession, 
and solar inequality of precession. Nine times out of ten, how- 
ever, he has to iind the equation by proportional calculation, 
and when gotten, it is sometimes positive, sometimes negative. 
Having proceeded thus far, he refers to the Nautical Almanac 
for the place of the moon’s node, and consults Table 18, which 
affords him, rarely without calculation, the correction for lunar 
nutation; again sometimesa positive, sometimes a negative quan- 
tity: he now applies one correction to the other, and procures a 
result which, added to or subtracted from the stars mean right 
ascension, affords him the star’s apparent right ascension at the 
time required; and which compared with the observed transit, 
presents him with the clock’s error, by that particular. star. 
Thus has he to hunt out corrections for every one of the 36 stars 
before he can convert its observation to any useful purpose; and 


1824.) Thirty-Seven Principal Stars. 39. 


I know by experience, that less than three minutes will not suf- 
fice to procure with care, the correction in right ascension for 
each star: and he must have little experience, or less candour, 
who will not acknowledge that, with all his circumspection, he 
has not occasionally taken out a false quantity from a wrong 
column, or applied one correction to the other with a wrong 
sign. 

“Bat it may be said, a reference to preceding observations will 
immediately detect the error: not so perhaps; many days may 
have elapsed since a transit of the same star may have been 
observed ; or it may be urged, that the amount of error, should 
it escape unnoticed, will be such as not materially to invalidate 
the result. Now as faras small instruments, suchas are usually 
stuck out of a window, are concerned, I will concede the point, 
for with these, an erroneous computation, amounting to two or 
three-tenths ofa second, may really do no harm; but where an 
instrument is used, adequate under favourable circumstances, to 
assign to any star south of our zenith, its right ascension by a 
single observation, accurate to the largest of these quantities, an 
error in the calculation of the correction becomes extremely 
injurious ; for it may so far vitiate others, as to require many 
additional observations to invalidate its force. We shall then, 
perhaps, be told, reject it when reduced to the Ist day of the 
year ; this may certainly be done, but I hold it a bad principle 
to discard any observation, unless posted as bad at the time of 
entering it in the rough journal; it leads to temptation which 
ought zn limine to be checked. Observations, be it never for- 
gotten, are not less entitled to our confidence because they are 
not always, uniform; and were I asked why the observations 
made at our Royal Observatory have acquired the influence they 
have over Europe, I should reply, not only because its instru- 
ments are superior, but because every observation, good, bad, 
and indifferent, which has been entered in the Observatory 
Journal, has been honestly recorded in the printed copies. 

The remaining process of computing is extremely simple. 
When, however, 50 or 60 stars are observed daily, its irksomeness 
is quite sufiicient ; a circumstance which induced me some time 
since to remove as much of the drudgery as could be removed, 
by computing a table, in which the clock’s daily rate and error 
at a particular time of the day being known, its corresponding 
error at any given time might be found by znspection. 

(To be concluded in our next.) 


The accompanying Corrections are computed from Dr. Maske- 
lyne’s tables, except those of the pole star, which are derived 
from its apparent right ascension, given in the Nautical Alma- 
nac for 1824. For the mean right ascensions, | am indebted to 


the kindness of the Astronomer Royal. 


— 

Note.—It being generally admitted that something in the shape of an Astronomical 

Ephemeris is much needed, I shall publish in the Journal of Science and the Arts for 

January next, a list of astronomical phenomena arranged in order of succession for the 
first three months of the year 1824. 


40. Corrections in Right Ascension of - (Jan. 


: 
Rigel é Tauri |x Orionis 


y Pegasi| Polaris |: Arietis | « Ceti /Aldebaran iT 
Mean ae: m. s. jh. s. {h.m. s. |h. m. s. h. a. 8. {h. m. Fa s. |h.m. h. 
Arid 6 96240 2)2 3 6 Sli 315 10925 45 39°93 


Jan. 1) + 0° 82” +1 09" + 151"4 1 "a0" + 2°32" + 3-21) + 2:24 4 2-69") + 2°41” 
2 81 0°39 56 719 32 21 24 69 Al 
3 80 |— 0°31 55 79 32 21 24 69 A2 
4 i9 1-01 53 78 31 21 24 69 AQ 
5 78 1-70 52 TT 1 fecal 21 24 69 43 
6 17 2°38 51 76 31 21 24 69 43 
7 75 3°06 50 16 30 2) 23 69 A4 
8 74 3°74 49 75 30 20 23 70 45 
9 13 4-42 AT 75 29 20 23 10 45 
10 71 S11 45 74 29 20 23 10 46 
1) 70 5°82 44 73 28 19 23 10 46 
12 69 6:52 43 72 28 19 22 69 46 
13 68 7°23 Al 71 27 18 22° 69 46 
14 67 7-93 40 10 26 17 21 69 46 
15 66 8°64 389 69 25 16 21 68 46 
16 65 9°34 38 67 25 16 20 68 46 
lq 64 | 10°05 37 66 24 15 20 68 45 
18 64 | 10°75 35 65 23 14 19 67 45 
be 63 | 11-46 34 64 23 14 19 67 Ad 

20 62 |. 12°15 33 63 22 13 18 67 45 
21 61 12°83 32 62 21 12 17 66 45 
22 60 | 13°50 30 61 20 ‘Bi 17 66) + 44 
23 59'} 14:17). 29 59 19 10 16 65 44 
24 58 | 14°84 28 58 18 09 15 64 43 
25 57 | 15°50 27 57 17 08 14 64 43 
26 56 | 16°17 25 56 16 06 14 63 43 
27 56 |. 16°84 24 54 16 05 13 62 42 
28 55 | 17°51 23 53 15 04 12 62 42 
29 54 | 18°18 21 52 14 03 12 61 41 
30 53 | 18:83 20 51 413 02 11 60 Al 
31 52 | 19-49 19 50 12 ol 10 59 40 

Feb. 1 55 |. 20°06 17 47 09 2:98 09 58 38 
2 54 | 20°68 16 46 08 9T 08 57 3T 
a 52] 21-30 14 At 07 95 OT 55 36 
4 51 | 21-92 13 43 05 94 06 54 35 
5 50 | 22°54 11 42 04 92 05 53 34 
6 A8 | 23°15 10 40 03 91 04 52 34 
7 AT | 23°77 09 39 02 89 03 51 33 
8 46 | 24:39 07 38 ol 88 |. 02 49 32 
9 45 | 25°00 06 37 1-99 86 00 48 31 
10 45 |. 25°55 05 36 98 84 1:98 47 30 
1} 44 | 26°10 03 34 96 82 97 45 29 
12 44 | 26°64 02 33 95 80 95 44 27 
13 44 27°19 ol 31 93 18 94 43 26 
14 43 | 27:73 1-00 30 92 16 92 41 25 
15 43 | 28°28}. 0°98 29 91 74 91 40 24 
16 A2 | 28°83 97 aT 90 12 89 38 23 
17 42 | 29°37 96 26 88 70 87 37 21 
18 41 | 29°91 94 25 85 68 85 36 20 

1g 41 | 30-46 93 23 85 66 84 34 19 
20 41 | 30°91 92 22 83 64 83 33 18 
2] 40 | 31:36 91 20 §2 62 Si 31 16 
22 40; 31°81 90 19 80 60 80 30 15 
23) AO | 32°26 89 17 78 58 78 28 14 
24 40} 32-71 88 16 77 56 TT 27 13 
25 39 | 33-16 S7 15 75 55 7 25 It 
26 39 | 33:61 86 13 74 53 74 24 10 
27 39 | 34-06 85 12 12 51 12 22 09 
28 39} 34°51 84 ll 71 49 71 21 OT 


29 38 | 3496 83 09 70 Al 69 19 06 


ed 


1824. Thirty-Seven Principal Stars. 4) 


Sirius Castor | Procyon | Pollux | a Hydre| Regulus | @ Leonis |é Virginis Pare 
li. m.s. [h.m ih. m. h.m. s. |h.m. h. m. h, m. h. m. mm. 
6 37 23-497 23 ‘o146 7 30 52 yl "34'32'18.9 18 66°44 9 58 39°57 Ti 40 £7311 AV 31°86 15 18 56007 


Jan, 1\4+ 2°32") + 2°91") + 2- a + 2:80"| + 2-04”) + 2-03" 4 1: et + 1-41” 


+ O84” 


2 33 93 82 06 06 44 87 
3 33 94 4 83 08 09 38 48 91 
4 34 96 A5 85 11 ll 60 51 94 
5 35 97 Al 86 13 14 63 55 98 
6 35 39 48 88 15 17 66 58 1-01 
7 36 3°01 50 90 17 20 69 62 04 
8 3T 02 52 91 19 23 13 65 08 
9 37 04 53 93 22 25 16 68 12 
10 38 06 55 95 24 28 719 TL 15 
1] 38 07 56 96 26 30 82 14 18 
12 38 08 5T 97 28 33 85 17 22 
13 39 09 57 98 30 35 88 719 25 
14 39 10 58 99 321° 31 91 82 28 
15 39 ll 59 3°00 34 40 94 85 Ry 
16 39 11 59 ol 36 42 96 87 35 
17 39 12 60 02 37 AA 99 90 38 
18 40 13 61 03 39 A6 2°02 93 42 
19 40 14 62 04 Al AQ 05 96 45 
20 40 15 63 05 43 51 08 99 48 
21 40 15 63 06 44 53 il 2°02 51 
22 AO 16 64 06 46 55 13 04 54 
23 40 16 64 OT AT 57 16 oT 58 
24 39 MG 65 OT 49 59 18 10 61 
25 39 17 65 08 50 61 20 12 - 64 
26 39 18 66 09 51 63 23 TPE) suGT 
27 39 18 66 09 53 64 25 18 10 
28 38 19 67 09 54 66 28 20; "4 
29 38 19 67 10 55 68 3l 23 TT 
30 38 20 68 11 57 10 34 26 80 
31 37 20 68 11 58 it Fe -.36 28 83 
Feb. 1 35 20 67 Il 58 72 39 28 ‘89 
2 34 20 67 11 59 73 Al 30 91 
3 33 20 67 Il 60 75 44 33 94 
4A 33 19 67 il 61 16 46 35 96 
5 32 19 67 11 62 17 49 37 2°00 
6 31 19 67 ll 62 19 5l 40 02 
7 31 19 66 ll 63 80 54 A2 o4 
8 30 18 66 11 64 8l 56 44 OT 
9 29 18 66 il 65 83 5T AT 09 
10 28 17 65 10 65 84 59 49 Il 
11 27 re 65 10 66 85 61 51 14 
12 26 16 64 09 66 86 63 53 16 
13 25 15 63 09 67 87 65 55 19 
14 24 15 63 08 67 88 67 57 21 
15 23 14 62 08 67 88 68 59 24 
16 22 13 61 OT 68 89 10 60 26 
17 21 13 61} 06 68 90 V2 To Oe 29 
18 20 12 60 06 68 91 74 64 31 
19 19 11 59 05 69 92 16 66 34 
20 18 10 58 04 69 92 17 67 36 
21 16 09 5T 03 69 93 18 69 38 
22 15 08 56 02 69 93 80 70 40 
23 13 OT 56 ol 69 94 sl 71 A2 
24 12 06 55 00 69 94 82 12 44 
25) =i 05 54 00 69 94 83 13 A6 
26 09 0A 53 2°99 69 95 84 15 49 
27 OT 03 52 98 69 95 85 16 | 51 
28 06 02 52 91 69 96 87 11 53 
29 05 ol 51 96 69 96 88 19 55 


A2 Corrections in Right Ascension of [JAN. 


Arcturus | 2 Libre ja Cor.Bor.| Serpent | Antares ees aLyre | y Aquile 


h. m. h. s. |h. h. m. s.'{h. m. s. lh. ms. 
Jia 7 Sih BY i 271 i]t U8 uF 6 ara 17264618 15 53°68 


- 


Jan, 1] 4 0°55” + 0°42" — 0°04”) + 0-114 0°03" — 0:29"|— 0-31] — 1-01 — 0° as! 


2 58 45 01 14 06 27 29 00 32 
3 61 49 |4 02 17 09 25 21 0:99 3k 
4 64 52 05 20 12 22 *o5 98 3l 
5 67 55 08 23 15 20 23 97 30 
6 70}. 59 11 25 18 18 21 96 29 
4 73 62 15 28 21 16 19 94 28 
8 16 65 18 31 24 14 17 93 28 
9 79 69 21 34 27 11 15 92 QT 
10 82 72 24 37 30 09 13 91 26 
1} 85 15 27 40 33 07 11 89 25 
12 89 78 30 43 36 04 09 88 2 
13 92 82 33 46 39 02 06 86 23 
14 95 85 36 49 42 |+ Ol 04 &5 22 
15 99 88 39 52 Ad 03 02 83 21 
16| 1-02 ol 43 55 48 05 00 $2 20 
7 06 94 46 58 52 08 |+ 02 80 18 
18 09 98 49 61 55 10 05 79 17 
19 12] 101 52 64 58 12 07 7 16 
20 15 04 55 67 6l 15 09 15 15 
21 18 07 58 70 64 18 Il 73 14 
22 | 11 61 13 68 20 14 71 12 
23 24 14 64 16 71 23 16 69 11 
24 21 18 68 79 15 26 19 67 09 
25 30 21 71 82 18 28 21 65 08 
26 34 25 74 85 82 31 24 62 06 
27 37 28 11 89 85 33 26 60 05 
28 40 32 81 92 $8 36 29 58 03 
29 43 35 84 95 92 39 31 56 02 
30 46 39 87 98 95 42 34 54 00 
3) 49 42|}- 90]. 101 98 A5 31 52|+ 02 
Feb. 1 52 A4 94 04}. 1:02 48 40 49 03 
55 AT 97 07 05 51 43 AT 05 

58 51 |. lol 10 09 54 A6 44 07 

61 54 04 13 12 56 48 42 08 

64 58 07 16 16 59 51 39 10 

67 6l 10 19 19 62 54 36 12 

7 64 14 23 23 61 56 34 13 

74 68 17 26 26 67 59 31 15 

a if q 20 29 29 10 62 29 17 

10 80 74 23 32 32 13 65 26 19 
1] 83 11 26 35 36 16 68 24 at 
lo 86 80 29 38 39 19 70 2k 23 
13} 89 83 32 4l 43 82 13 18 25 
14 92 86 35 44 46 85 16 16 27 
15} 95 89 39 AT 50 88 18 13 28 
16 97 93 42 50 53 90 81 11 30 
17 00 96 45 53 57 93 84 08 32 
18 03 99 48 56 61 96 87 05 34 
19 06 | 202 51 59 64 99 99 02 36 
20 08 05 54 62 67 | 1:02 93 |+ Ol 38 
21) 211 07 56 G4 70 04 95 03 40 
Qu 13 10 59 67 14 07 98 06 42 
23 15 12 62 69 17 09 | 1-00 09 A5 
24 18 15 64 712 80 12 03 rf AT 
25 20 17 67 14 83 14 06 14- 49 
26 vg 20 70 11 86 17 08 17 Bl 
27 e4 22 13 19 89 20 11 19 53 
28 26 25 15 82 93 22 13 22 56 
29 29 28 78 85 96 25 16 25 58 


* Mean AR of 1 « Libra 144 40’ 58°21”, 


1824.] 


ThirtysSeven Principal Stars. 


43 


pA Ai RE SE ER a es ee eee 
x Aquile | @ Aquile |2* 2Capric.| a Cygni | Aquarii 


h. m. s. |h. m. s. |h. m. s. [h. m. s.- Mm. S 
19 42 11°88 1946 40°23/20 8 17°02\2035 26°21 \2] 56 44:67 


h. 


Fomalhaut | « Pegasi |x»Androm. 


h. m. s. |h.m. s. |h. ms. 
22 47 54°34/22 56 0717/23 59 18°67 


Jan. 3}|— 0°30" |— 0:27"! — 0:09"'|— 1°03”| + 0-22) + 0°55” |+ 0°39’ + 0°70" 


29 
29 
28 
28 
27 
27 
26 
26 
25 
24 
23 
21 
20 
19 
18 
17 
16 
14 
13 
12 
10 
09 
O07 
06 
05 
03 
02 
ol 
+ ol 
03 
O+L 
06 
08 
10 
11 
13 
14 
16 
18 
20 
22 
24 
26 
28 
30 
33 
35 
37 
39 
Al 
43 
45 


26 08 04; 2) 54 
26 08 04} 2 53 
25 07 05] 20 52 
24 06 05 20 51 
24 06 06 19 50 
23 05 06 19 49 
23 05 07 18 48 
22 04 07 18 47 
21 03 08 17 A6 
20 02 08 17 45 
19 01 08 17 44 
18 00 08 17 44 
17 | + 0-01 01 11 43 
16 02 07 17 42 
15 02 07 17 41 
13 03 07 17 40 
12 04| 06 16 39 
N 05 06 16 39 
10 06| 06 16 38 
09 07 06 16 38 
07 09 05 16 37 
06 10 05 17 31 
04 i 04 fg 36 
03 13 04 7 36 
02 14| 03 17 36 
00 15 03 17 35 

+ Ol 16| 02 17 35 
03 18 02 18 34 
04 19| 02 18 34 
06 20 01 18 34 
06 29 00 19| > 34 
08 24 | 0-99 19 34 
10 25| 98 i9 34 
i 27 97 20 33 
13 28 95 20 33 
15 30| 94 20 33 
16 32 93 20 33 
18 34 92 21 32 
20 35| 90 21 32 
22 31 88 22 32 
24 39} 87 23 32 
25 4l 85 24 32 
28 43| 4 25 33 
30 45| 82] 26 33 
32 47 81 27 33 
34 48 719 27 33 
35 50 11 28 33 
31 52 16 29 34 
39 54 7 30 34 
4l 56 72 31 34 
43 58 71 32 35 
45 60 69 33 35 
47 62 67 34 36 
49 64 66 35 36 
51 66 64 36 37 
53 61 62 36 37 
5b 69 60| 31 38 
58 71 59 38 38 
60 13 57 39 39 


* Mean AR of J « Capricor. 205 7’ 53°23”. 


38 
37 
36 
35 
34 
34 
33 
32 
31 
30 
30 
29 
29 
28 
28 


A4 Corrections in Right Ascension of (JAN. 


: y Pegasi | Polaris |a Arietis| a Ceti |Aldebaran| Capella | Rigel @Taurt |# Orionis 
Mean AR) |h. m. s, [h. m. 8. |h. m, s. jh. m, s. b. m. 8. \h. m.s. {he m.s. |b. m, ss. |h. m. s. 
1824. §|0 4 11°17/0 58 2°66 /) 57 16-4212 53 54414 25 50015 3 422155 6 511/515 10°52)5 45 38:93 


i | mes ee 


March 1) 4- 0-38|—35°41"| + 0°82”) + 1.08") + 1°69) + 2°45") + 1°68) 42617 | + 2:05! 
‘ 2 66 


38 | 3574| 8 07 67 43 16| 03 
3) 38| 3607| 80} 05] 66| 41 64 ian ol 
4). °g8| 3640) 79} Of] 64] 39) 68 13 | 1-99 
5) 38: | 3673 18 02 63 36| 61 11 98 
6) 38| 3706| 17 01 61 34] | 80 09 | 97 
7|. 38| 3739| 76) 0-99] 60 32| 5% 07 | 95 


8 38 | 31-72 15 98 58 30 55 06 94 
9 38 | 38:05 14 97 55 28 54 04 92 
10 38 | 38°38 13 96 54 25 52 02 91 
1] 38 | 38°71 12 95 53 23 50 00 89 


1g 39 38:92 71 94 52 ai 48 1-98 87 
13 39 | 39:12 val 93 50 18 47 96 86 
14 40 | 39°33 10 92 49 16 45 95 84 
15 40 39°53 10 91 AZ 14 43 93 83 
16 41 | 39°74 69 90 46 12 Al 91 81 
V7 Al 39°95 69 89 44 09 40 89 99 
18 42 40°15 68 88 43 OT 38 88 18 
19 42 40°36 67 87 Al 05 36 86 16 
20 43 40°56 67 86 40 02 35 ' 84 TA 
21 43 | 40°77 66 85 38 2-00 33 82 712 
22 44 40°85 66 84 37 1:98 31 80 10 
23 45 40:93 65 83 35 96 30 19 69 
24 45 A101 65 83 34 94 28 17 67 
25 46 41:09 64 82 33 92 27 75 66 
26 AT ALIT 64 81 31 90 25 74 64 


27 48 41°25 64 80 30 88 24 12 63 
28 AY 41°33 63 80 28 86 22 70 6L 


29 50 | 41-41 63 19 27 83 21 68 60 
30 51 41°49 62 18 25 81 19 67 58 
31 51 41°56 62 7 24 19 17 65 bali 
Sirius Castor | Procyon | Pollux | @ Hydre | Regulus | @ Leonis |@ Virginis |SpicaVirg. 
Mean AR} {h. m._s. |h. m. s. |h. m._s- ‘h, m, 8. |h. m, s. ih. m. s. |h. m. s, [h. ms. |h, m. s. 
1824, § \6 37 23-4917 23 21:46)7 30 5°32 7 34 32°18/9 18 56'449 58 59°57|11 40 4:73)11 41 31°86 13 15 56°07 
March 1|4 2:04’\+ 3:00”| + 2°50” | + 2°95"| + 2°69"|+ 2°96"! 4 2°89"|+4 2°80"|+ 2:57” 
2 02 2:99 49 94 69 96 90 81 59 
3 01 97 48 92 68 96 91 82 61 
4| 1:99 96 AT 91 68 96 92 83 63 
5 97 94 46 90 67 96 93 84 64 
6 96 93 45 89 67 97 94 85 66 
7 94 91 As 87 66 97 95 8 68 
8 92 89 42 86 66 97 96 87 70 
9 91 88 41 85 65 97 97 88 72 
10 89 87 40 83 65 91 98 89 4 
ll 87 86 39 82 64 97 99 90 16 
12 85 84 38 80 63 96 3-00 91 718 
13 83 83 36 19 62 96 00 91 19 
14 82 81 35 17 62 95 ol 92 81 
15 80 80 34 76 61 95 OL 93 82 
16 18 18 33 1A 60 94 02 93 84 
17 16 77 31 12 59 94 02 94 85 
18 75 15 30 71 58 93 03 95 8T 
19 13 13 29 10 58 93 03 95 88 
20 val 71 27 68 57 92 04 96 90 
21 69 69 26 66 56 92 05 97 92 
22 67 67 24 64 55 91 05 97 93 
23 65 66 23 63 54 91 05 97 94 
24 63 64 21 61 53 90 05 97 95 
25 61 62 20 60 52 89 05 98 96 
26 59 61 18 58 51 89 05 98 98 
21 57 59 16° 56 50 88 06 98 99 
28 55 58 15 55 A9 87 06 98 3:00 
29 53 56 13 53 48 87 06 99 ol 
30 51 54 ll 52 AT 86 06 99 02 
31| 49 52 09 50 46 85 06 99 03 


ee 


Thirty-Seven Principal Stars. 45 


panne ieliee ix Cor.Bor.|« Serpent | Antares fe eit a Lyre |" vi a 
h.m.s. |h. m. s. |h. m. 
ig 7 Beas 14 iT 9°63 15 27 14 45)15 35 36°47/16 18 37° “O1. 7 6 37: Saliyae 36 16" 24 ian 4058-99 19.3759°68 
March 1) + 2°31'/, + 2-31” + 1-81") 4 1°88) 4 1-99") 4 1-28” +1°19"| + 0°28" + 0-60" 
33 34 84 |. 91 2:02 31 22 31 63 
36 36 87 93 05 33 25 34 65 
38 39 90 96 09 36 | 28 37 68 
40 Al 93 99 12 38 31 Al 5 70 
43 44 96 2-01 16 Al 34 44 73 
45 46 98 04 19 43 37 AT 15 
AT A9 201 OT 22 A6 40 50 78 
49 52 04 10 26 49 43 54 81 
52 55 OT 12 29 5g 46 5T 84 
54 57 10 15 32 5A 49 60 86 
56 59 12 18 35 57 52 63 88 
58 62 15 20 38 61 55 67 91 
60 64 17 23 Al 64 58 70 93 
62 66 20 25 44 67 61 74 96 
64 68 22 28 AT 10 64 77 98 
66 71 25 30 50 14 67 80 1-01 
67 13 2T 33 54 17 69 83 03 . 
69 15 30 36 57 80 12 87 06 
71 78 32 39 60 84 15 91 0s 
713 80 35 Al 63 87 718 94 ll 
15 82 37 43 66 90 81 97 14 
76 84 40 46 69 92 84 101 16 
18 86 42 48 12 95 87 04 19 
80 88 44 50 15 98 90 07 22 
81 90 46 52 18 2-00 93 10 24 
83 92 AQ 55 81 03 95 13 27 
85 95 51 58 84 06 98 17 29 
86 97 53 60 87 08 2-01 20 32 
88 99 56 62 90 11 04 24 35 
90 3-01 58 64 93 14 OT 27 38 


« Aquile | ¢ Aquile hoe a a Cygni le Aquarii |Fomalhaut |} « Pegasi laAndrom. 


Mean AR} |h. m h. m._s. |h. s. |h. h. m._s. |h. h. 
1824. Wig 421189| 9 40 40°53)00 8 17: 2196 35 2691/21 56 4467/23 47 54°34 29 56 017 3.59 1857 


March 1| + 0°60") + 0°62”) + 0°75’|— 0°55”) + 0°40’ + 0°39”! + 0-23”) + 0-19” 


2 62 64 17 53 Al 40 24 19 
3 65 67 80 50° 43 Al 25 19 
A 67 69 82 48 44 AQ 25 19 
5 70 72 85 45 45 43 26 19 
6 72 74 87 A3 46 AA 27 19 
1 15 76 90 40 48 “ADS 28 19 
8 TT 78 92 38 49 AG 29 19 
7 9 80 81 95 35 50 AT 29 19 
10 82 83 97 32 52 A8 30 19 
1] 85 86 1:00 30 53 49 31 19 
12 88 88 02 27 55 50 32 19 
13 90 91 05 24 56 52 33 20 
14 93 93 07 22 58 53 34 20 
15 95 96 10 19 60 54 35 21 
16 98 98 12 16 61 56 36 . Qi 
17| 1°00 1-01 15 13 63 57 3T 22 
18 03 03 17 ll 64 58 39 22 
19 05 06 20 08 66 60 40 23 
20 08 08 22 05 68 61 41 23 
2 i if 25 02 10 63 A2 24 
22 14 14 28 \+ Ol 12 65 AZ | 25 
23 17 17 31 04 74 66 45 26 
24 19 19 33 08 16 68 46 QT 
25 22 22 36 1) 18 69 48 28 
26 25 25 39 14 80 71 49 29 
21 28 28 42 17 82 73 51 30 
28 31 3l 44 20 84 15 52 3t 
29 33 33 AT 23 86 16 54 32 
30 36 36 50 27 88 18 55 32 
31 39 39 53 30 90 19 51 34 


46 Prof. Cumming on a new Thermoelectric Instrument. [JAan. 


ArTICLE IX, 


‘Description of a New Thermoelectric Instrument, _ By the Rev. 
J. Cumming, Professor of Chemistry in the University of 
Cambridge. 


(To the Editor of the Annals of Philosophy.) 


MY DEAR SIR, Cambridge, Dec. 20, 1823. 
WHATEVER contributes to confirm the close analogy which 
subsists between the electricity excited by heat and that by 
galvanic action, will, I conceive, be acceptable to those who 
‘take an interest in this subject. For this purpose, I have con- 
structed an instrument, the description of which you will oblige 
me by inserting in the next number of the Annals of Philosophy. 
It exhibits the rotation of a wire round a magnet, and its deli- 
cacy is such that when excited by the thermoelectricity of a 
silver and platina wire, each of 1-22d inch diameter, it revolves 
between 30 and 40 times in a minute ; if, instead of these wires, 
a pair of galvanic plates of half an inch in diameter be used, the 

rotation is rather more rapid. 
I am, my dear Sir, very truly yours, 
J. CUMMING. 


A B, a cylindrical magnet. 

abecd,a glass tube containing mercury, cemented on the top 
of the magnet. 

C DEF, a brass wire poised by a needle point passing 
through I, and resting upon an agate cemented upon the 
magnet. 


1824.] MM. Dumas and Pelletier on Organic Salifiable Bases. 47 


C G, F H, platina points soldered to the wire CD EF. 

K L, a cylindrical piece of wood, having a perforation to admit 
the magnet, and a circular groove containing mercury, in which 
the points G and H revolve. E 

e f, a copper wire passing through the bottom of K L, and 
communicating with the mercury in the groove. 

M O, cups filled with mercury. 

P N, wires passing from the positive and negative ends of the 
exciting apparatus. 

The current from the positive pole P ascends through the 
magnet to I, descends down D G, EH, into the mercury in the 
circular groove, and from thence through the copper wire e f, 
into the cup M, connected with the negative pole by the wire N. 


ARTICLE X. 


On Organic Salifiable Bases. By MM. Dumas and. Pelletier.* 


The following is the analysis of these compounds. given by 
these chemists : a, 


Carbon. Azote, Hydrogen. | Oxygen. 


ee ee | SO 


IB waa dd's os ainsie},., 12°00 8-45 6°66 10:43 
Cinchonia..,....-..| 76:97 9-02 6:22 7:79 
TUCIBD £62, 5,3)0.0.4,0% 75°04 7:22 6:52 11-21 
Strychnia ..........| 78:22 8-92 6:54 6:38 
WMATA wescececes| 66°75 5°04 8°54 19°60 
Emetin ,.....0....| 64:57 4:30 chy id | 22°95 
Morphia............| 72°02 5:53 7:01 14-84 
Warcotin ...+,«+.0..| 69°88 7:2) 591 18-00 
OS ool, 46°D1 |, 21°54 4-81 27°14 


MM. Dumas and Pelletier calculate that quinina is consti- 
tuted of 


Atoms. 
Carbon .....+++++.. 60 or in 100 parts nearly 75°38 ' 
Azote. wccccsevvees 3B 8°72 
Hydrogen.......... 30 6°15 
ORyGeM . aeccsciesee 19 9°85 
96 100-00 


If, however, we calculate the weights of the atoms as given 
by Dr. Thomson, Dr. Henry, and Mr. Brande, it will be found 
that the number of atoms which enter into the constitution of 


# From the Annales de Chimie et de Physique, vol, xxiv. p. 191. 


48 MM. Dumas and Pelletier on Organic Salifiable Bases. (Jan. 


this, and probably the other substances, are much fewer, and 
the calculated result is rather nearer that obtained by experiment. 


~ Carbon. .. 20 atoms 6 x 20 = 120 or in 100 parts 75-00 
14 


1 a fe 8°75 
Hydrogen. 10 = 10 6:25 
Oxygen.. 2 Sx aoe ap 10-00 

he s098 160 | 100-00 


In concluding, the authors observe, that the results of the 
analyses of the substances in question are equivalent to 


Carbonic acid. Azote. 
UG Sb Ne eeen, TOU eknee ae : OF 
Oinchonia. 10). as. pg ee ete erate 5:0 
Strychnid cos. ccccns a TOU. cease sie 4:9 
Wanegtnl *. es cekeys ss POU, asda cee 4:5 
Brae Ty. ke Fy ASOT OO. cas ces a ae 
Morphia. ee ee ee ee 100 ee eeeeee 3°2 
Veratria. .....000% £10622, S45 +» 32 
Pimiertn so. ae wes ag 1 nites piitdignes. A So | 
Cmem het en. ee, BRT tocn ane cone 20-0 


With respect to the last mentioned substance, MM. Dumas 
and Pelletier observe, that no particular memoir has as yet 
appeared upon it. It was discovered in 1821 by M. Robiquet, 
in his researches to discover quinina in coffee. The authors of 
this paper obtained the same principle about the same time, but 
the priority is due to M. Robiquet. The properties of cafein are 
stated to be, that it is white, crystalline, volatile, and but slightly 
soluble. } . . 

The method of analysis adopted was that suggested by Gay- 
Lussac; the peroxide of copper employed was prepared by cal- 
cining the nitrate at a dull red heat; it was then carefully 
washed, and again heated at the same temperature to expel the’ 
moisture; and before use it was moderately heated in a platina 
erucible, and weighed while still warm. 

MM. Dumas and Pelletier adopt the specific gravity of 
gases as determined by Dulong and Berzelius, and their calcu- 
aa are founded on the weights of atoms given by the same 
chemists, 


1824.)  M, Rose on Felspar, Albite, Labrador, &c. 49 


ARTICLE XI, 


On Felspar, Albite, Labrador, and Anorthite, 
By M. Gustavus Rose.* 


Some differences I had found in the angles of crystals 
described hitherto as felspar, induced me to examine them with 
greater accuracy. From my observations, it results that four 
different species, which differ as much in their form as in their 
chemical composition, had been united under the common name 
of felspar ; it is true that there is a great analogy in their crys- 
talline forms. 

Among these species, that which will retain the name of 
felspar, K S* + 3 AS%, is the one met with most frequently. 
Under that name must be classed the adularia from St. Gothard, 
vitreous felspar from Vesuvius and from Siebengebirge, the 
amazon-stone, the felspar from Friedrichwarn, in Norway, which 
had been taken for labrador, the felspar from Baveno, from 
Carlsbad, from Fichtelgebirge, and in general the greater part 
of what Werner has called common felspar. 

The second species called albite (cleavelandite}+) N S°+3 A S# 
is not so common as felspar. We are indebted to M. Eggerts 
for the first notice of this substance; he examined a radiated 
variety of it from Finbo and from Broddbo, near Fahlun. 
Since, MM. Hausmann and Stromeyer have also found it in a 
rock from Chesterfield in North America, and M. Hausmann 
named it Kieselspath. M. Nordenskiold found the same sub- 
stance in a granite from Kimito, near Pargas, in Finland; and 
lastly, M. Ficinus in a granite from Penig, in Saxony ; but all 
these varieties were not regularly crystallized. The crystals of 
the same substance which I have had an opportunity of seeing, are 
the crystals from Dauphiny, which Romé de L’Isle had described 
under the name of schorls blancs, and which afterwards Haiiy 
took for felspar ; the crystals from Salzbourg and the Tyrol, de- 
scribed as adularia; the crystals from Kerabinsk in Siberia, 
from Arendal in Norway, from Prudelberg near Stirschberg in 
Silesia; as well as many other crystals from different localities. 

The third species is the labrador (labrador-felspar) which 
Klaproth had already analyzed and separated from felspar; the 
external characters of this substance had, however, prevented 
mineralogists from making a distinct species of it. From the 


* Translated (with some omissions) from the Annales de Chimie et de Physique, 
tome xxiv. p. 5. ws 

+ This name (cleavelandite) was proposed for albite by Mr. Brooke, but the origi« 
nal term has been preserved in this translation. 


New Series, vou. v11. E 


50 ) M. Rose on Felspar, [Jans 
analysis of Klaproth, M. Berzelius has found that the formula 
was NS'4+3C8°34 12 AS. 

The fourth species is the scarcest of all; I have only met with 
it in small groups of crystals in blocks of carbonate of lime, which 
are found near Vesuvius. I have found that their chemical 
formula was MS.+2C8S + 8A58, and I have given them 
the name of anorthite. 

I shall now describe the principal properties of these four 
species. In the description of the crystals I have only given 
the primitive form, the signs of the secondary planes, and the 
principal angles, I have thought it useless to describe more 
minutely the secondary crystals.* The figures I have given, 
especially when compared with their signs, are perfectly suffi- 
cient, to form an exact idea of the relative situation of these 
planes, and of the parallelism of the edges. The signs of the 
secondary planes are given according to the method of Haity, 
and J have calculated them from the angles of the primitive 
form, which I have measured with as much exactness as possi- 
ble, by means of spherical trigonometry, and by the parallelisms 
of the edges. But the primitive forms of these species being 
doubly oblique prisms, the theory of which is not yet perfectly 
known, their determination depends on five measurements, while 
the determination of oblique rhombic prisms depends only on 
two; it is for that reason that I can only consider the angles I 
have given as approximations not very far from the truth. 

The.specific gravity has been determined with care. WhenI 
had only small crystals to examine, I weighed some of them in 
a.small flask of glass, the weight of which both in water and in 
air was subtracted from the weight of the flask containing the 
small crystals, and weighed under the same circumstances. I 
have given the temperature of the water I used in my experiments. 
I have not reduced my results to the same temperature, because 
they would be but very little altered by that reduction. 

he hardness of all the species described is less than that of 
quartz, and differs but little from that offelspar. Albite has in 
general appeared to me to be the hardest, and labrador the 
softest. ) 
First Species. —Felspar. 


The system of crystallization is, according to M. Weiss, bino- 
singulaire. The primitive form is an oblique rhombic prism, in 
which the ratio of the three dimensions which are perpendicular 
to each other, and equal to the diagonals of the section perpen- 
dicular to the lateral edges, and to the length of one of these 
edgesis = / 13: J313: V7 3. 

The chemical formula is, according to Berzelius,; K 8° + 


* The figures of crystals are not all given in the translation—Ldit. 


PAS def Sty 


\o 


ie Whe Ait ee mm) TL 


PLATE XXV- 


ALBITE. 


Fug. 


pe ] | 
me ' H 
a Se 
| ‘sh 
| | 1 
ie 
i | t 
ys Ne eaeys 
4" ! ! 

: Wks eh 

1 

| 1 

l ts 

\ 


Engraved ror the Annals of Philosophy, ror Baldwin, Gradock & Joy. Jin1b24. 


1824.) Albite, Labrador, and Anorthite. 51 


3 AS*. If we calculate from this formula the proportion of the 
constituent parts, we find that 100 parts of felspar contain 


Silex . eeeewes eevee eeeteoecenesves es 65:94 
Alumina, e@e eee eereree eee eeeeeeesen 17°75 
Phtask yin oo.ebus Aesaha ould. wows 


Observations.—Although felspar is common, yet it is rarely 
met with in such perfectly brilliant crystals as are necessary 
for measurement by the reflecting goniometer The collection 
of minerals in the University of Berlin, which is extremely rich 
in crystals of felspar, does not contain a specimen the crystals of 
which could have been measured by that instrument. The best 
for that purpose with which I am acquainted are the cry stals of 
glassy felspar from Vesuvius, and I have measured the angles of 
some which ‘differ a little from those given by M. Weiss. I have 
found for instance the obtuse incidence of the lateral planes of 
the primitive to be 119° 18’, and that of the base of the primitive 
upon one of the lateral planes 112°141’*, These measurements, 
however, I did not consider as sufficiently exact to ground my 
calculations upon. 

I was rather surprised by what I found to be the specific gravity 
of the felspar of Bayeno. I had weighed it several times, and 
I had chosen not only the hemitrope crystals which are so fre- 
quently met there, but also simple crystals which are perfectly 
pure, and did not appear to contain any foreign substance. The 
results I obtained were always the same, and I was induced to- 
think that the composition of the crystals of Baveno differed from 
that of felspar, and that since the crystallisation was perfectly 
the same in both, some isomorphous principle was replaced by 
another. I, therefore, analyzed a crystal from Baveno. In 
fusing it with carbonate of potash, and in treating it in the 
usual manner, I found the proportion between the silex and 
the alumina exactly the same as that which exists in common 
felspar; so that though I had not separated the potash, I 
thought I had no reason to suppose the composition different 
from other felspars. 


Second Species.—Albite. 


The primitive form of albite is a doubly oblique prism (Plate 
XXYV), figs. 1,2. The planes M and T of which are inclined 
at an angle of 117° 53’; the planes M P form angles of 93° 36’ 
and 86° 24’; the planes T’ and P angles of 115° 5’ and 64° 55’, 
The section perpendicular to the planes M and Tis an oblique- 
angled parallelogram, fie. 2, the obtuse angle of which is divided 
by a plane / produced by a decrement of two rows along the 


* Mr, W. Phillips gives for the same angles 119° 20’ and 112° 5’. 
E2 


52 M. Rose on Felspar, [JAN. 


edge G, into two angles of 60° 8’ and 57° 45’, the first of which 
has one of its sides situated in the plane M, and the second, one 
of its sides in the plane T. The section perpendicular to the 
planes M and P is an oblique-angle parallelogram, the obtuse 
angle of which is divided by the plane x, produced by a decre- 
ment by one row on the edge B, into two angles of 46° 5’ and 
47° 31’; the first of which corresponds to the edge of the paral- 
lelogram situated in the plane P ; the other to the edge of the 
parallelogram situated in the plane M, 
The planes I have observed are 


1 2 4 2 ~ 
PMT Gs Gs sHAAB CC (sce fips. 3, 4). 
l fii Se Le o g 


z 


Incidences.* 


TB ot MI RG a Be Oe ae ot LAGE HER. 
OMG 62S ARO, oI oi A ee 
NR ORT iG SEER MG eos ote TID OBIE 
ERDAS IS), sare vik eee ee oud. FS one 
Roe ayer aves Vee eo, PaO eae 
AVE WOTEIA ‘a dn av ealg 6: Cee wave’ a wi ais a 148 30 
POMP SOLU RAG. UO as) ae das 
POM Te ee UE EG he's o PUGS) 
Proms ELLIPSE On 
Pron ory SUN ee A laa 
Mpa ett is AA eh ea a 
PA EL EEA eee te Oe Ce 
Reuter iyt susiaiies ee -.-. LOO 52 
Pron ME eta, eee eee: BaD Cee 
bok Gite a 133 55 

Ong! MIO lk ewes cnet Or Oe 
OH PL Oe Se ces HA TOR 1D 
PM SSSI LS PAE eh bce cet REO Chee 
Pog ents ere OTe Pe one 127 93 


Plane Angles of the Primitive Form. 


Those of plane P 119° 12’and 60° 8 
M 116 35 63 25 
T 99 45 80 15 


The crystals of albite are frequently or almost always met 
under the form of hemitropes.| These hemitropes are formed 


* TI have marked * the angles from which the others are calculated. 

+ I found, however, afterwards, that the crystals of St. Gothard, the prisms of 
which are so short that the planes of one of the summits meet those of the other, are 
very likely albite: they are met commonly in simple crystals, and seldom in hemi- 
tropes. ‘Their planes were not sufficiently brilliant to be measured ; but it is likely that 
they were albite, since, when digested in hydrochloric acid, they were not decomposed, 


-1824.] Allite, Labrador, and Anorthite. 53 


when two crystals are so joined to each other that the upper plane 
of the one is applied upon the inferior plane P’ of the other, in 
the manner exhibited by fig.3. The two crystals have gene- 
rally the same size ; however all the differences which are known 
to occur in the hemitropes are also met with in this substance ; 
frequently one of the crystals is only visible by a narrow line on 
the plane P of the other. A third crystal is often applied on the 
second; and a fourth upon the third, &c. The hemitropes 
attached to the matrix present always the same end upwards, 
and that corresponds to the upper part of fig. 3. 

This substance can be cleaved parallel to every plane of the 
primitive ; the cleavage parallel to Pis the most brilliant. The 
colour of the crystals is white or reddish-white ; the crystals are 
translucent or transparent, either wholly or in part as in those of 
Kerabinsk. 

The specific gravity will be found in the following table : 


Locality. Weight gram. Sp, gr. Tem, water. 


Hemitrope crystals Kerabinsk 4808 2608  20°R. 
Hemitrope crystals Kerabinsk 12-711 26175 212 


Id. reddish-white Arendal 3692 ety uv 
y 


The specific gravity has been found before by 
Eggertz, that of Finbo. ............ 2612 


Eggertz, that of Broddbo. ..... ences 2019 
Nordenskiold, that of the red albite 
Mena MMMitO oie ce. atu, «» 2°609 


Ficinus, that of the albite of Penig. .. 2:50 


The result of an analysis of crystallized albite from Arendal, 
decomposed by means of carbonate of potash, is 


BUICAisisceee ss -+++- 68°46 which contains oxygen 34-43), 12 
Alama. 6:4. 0000s 19:30 901[ 3 
ee ere g binge ler O68 

Oxide of iron. ...... 0°28 

Magnesia 

DB Sistine oe pia ciipnt ». 11:27 taken as soda........ 288] 1 


Another analysis in which I had precipitated the alumina with 
carbonate of potash, gave the following result : 


DUE oreo aierave Oe alsiProrwtaree @idishe odd ide 68-60 
Alumina, with a little oxide of iron... 19:25 


An analysis with carbonate of barytes, gave 


54 M. Rose on Felspar, [JAN. 


mile bs 0) ads dees Cade elas on os ae: OOVOe 

- Alumina, with a little oxide of iron and 
Wintsiag. aeide valid oe veh suk feeds! 20! aor 
UGA ars wpnik-nte tlle eld dae sioteead ¢aean Onbe 


————_-- 


98°49 


If the composition of albite is calculated from the formula 
NS* + 3A8%, the following proportion of the constituent 
parts is found 


Silex vcs sete PS FIO G Fae Od AS eat 69°78 
Aluinina, AOS Ed etka Oo B89 OOnipraaey 
Moda Tei 2 ee EO ae Saree Pies 


Crystallized albite is found at Arendal in Norway, where it is 
almost always accompanied with epidote, according to what I 
have seen at the place itself, as well as in private collections. It 
is found also in the Schmirnerthal, in the Tyrol, with carbonate 
of lime in veins of carbonate of lime; at Rohrberg, near 
Zell, in veins with quartz, or in gneiss very rich in quartz, 
accompanied by rock crystal and carbonate of iron: it is found 
in the same circumstances at Gastein, in the country of Salz- 
bourg; at Bareges in the Pyrenees, and at Auris in Dauphiny, 
in veins with axinite, anatase, adularia, epidote, asbestus, 
with which the albite is sometimes perfectly mixed. As to 
the albite of Kerabinsk, in Siberia, the collection of minerals 
in the University of Berlin, contains only isolated hemitrope 
crystals, which are of a much larger size than the others. Some- 
times the plane M is one inch long, while the other hemitrope 
crystals are never more than a few lines. At Prudelberg, at 
Stonsdorf, near Hirschberg, in Silesia, albite is found with fel- 
spar in veins of granite; the crystals of felspar are flesh-co- 
loured, and sometimes covered with crystals perfectly white, or 
of the same colour as those of albite. The crystals of felspar of 
Baveno are also frequently accompanied by some small whitish 
crystals, which commonly are not felspar, but albite.* 

Observations.—The crystals of albite are easily distinguished 
by their hemitropes, and the re-entering angles formed by the 
planes P. If the crystals of felspar were grouped in the same 
way, the similar planes of the two crystals would be parallel, 
since in felspar the planes M and P are at right angle to each - 
other, and could never form re-entering angles; the analogous 
hemitrope crystals of felspar, such as those of Carlsbad, can 
only be formed as it has been demonstrated by M. Weiss, when 
two crystals are grouped, either with their right planes M, or 
with their left planes M. So that the faces P of cleavage are 
situated on opposite sides in the two erystals, while in albite 
the planes P of the two crystals are situated on the same side. 


® If the above-mentioned crystals of St. Gothard are albite. 


1824.] Albite, Labrador, and Anorthite. 55 


Albite offers, however, sometimes crystals which are grouped in 
a manner analogous to the hemitrope crystals of felspar. The 
are joined to each other by their planes M, and’ consequently 
have their planes P on different sides ; but in ‘this case the two 
crystals are attached by their other faces to other crystals in the 
common way ; so that the whole is only an hemitrope formed 
by two different hemitropes which are grouped in the same 
manner as the two simple crystals which form the hemitrope 
crystals of felspar of Carlsbad. | 

Although albite is found massive, it is always radiated, never 
in laminz, and that distinguishes it essentially from felspar. 
It may always be admitted, therefore, that the felspar which is 
met in this state is not felspar, but albite. The palmed felspar 
of Johann Georgenstadt in Saxony, distinguished by Werner, is 
among those of this kind the most known in Germany: how- 
ever, some doubts may be entertained concerning several speci- 
mens of various localities contained in the collection of minerals 
at Berlin. 

Besides the albite of Arendal, I have analyzed that of Salz- 
bourg. Some circumstances have prevented me terminating the 
analysis of it; however, I have obtained soda, and the same 
quantity of silex, as in the analysis of the albite of Arendal. 

The sulphate I had obtained, and which I had crystallized 
with a great deal of care, gave me crystals perfectly similar to 
those of sulphate of soda. When exposed to the atmosphere, 
they fall to powder, and treated by the solution of platina, by 
tartaric acid, and by sulphate of alumina, they exhibited the 
same properties as sulphate of soda. Having mixed a solution 
of these crystals with a solution of chloride of platinum in alco- 
hol, it remained perfectly limpid, and evaporated to dryness, and 
left a mass perfectly soluble in alcohol. A solution of these 
erystals into which I had put tartaric acid, retained its 
himpidity. In mixing this with sulphate of alumina and alcehol, 
I obtained regular octohedrons perfectly well crystallized, which 
I consider as sulphate of alumina and soda; because when 
opposed to the atmosphere, they were reduced to a fine powder, 
and are thus sufficiently distinguished of sulphate of alumina and 
potash, which mixed with alcohol was immediately precipitated 
in a state of powder. 

In analyzing albite with carbonate of barytes, I have found a 
loss of 2}: per cent. It is undoubtedly soda which suffers this loss ; 
this appears to me so much the more likely, for I obtained silex 
and alumina in the same proportions ds in analyzing albite with 
carbonate of potash, and the result was the same in calcu- 
lating the proportion of these two bodies from the same chemical 
formula. [ eould not repeat the analysis, because 1 had used 
all 1 had of the substance to determine the nature of the alkali 
contained in albite, and for the analysis with the carbonate of 
potash. 


56 AM, Rose.on Felspar, [Jan, 


‘Third Species.— Labrador. 


This substance is very seldom met in regular crystals. There 
is only one specimen in the collection of minerals at the Univer- 
sity of Berlin; and although it is possible to determine the form 
of it, which shows great analogy with felspar, the angles can- 
not be measured. ‘The modifications appear to be the same as 
those of felspar.. It cleaves easily in two directions, in one of 
which the face obtained by cleavage is perfectly brilliant; the 
difference between the degree of brilliancy of these two cleav- 
ages denotes a difference between labrador and_ felspar. 

oreover those two cleavages are not obviously at right angles 
to each other. I have found their inclination to be 934° and 864°. 
I could not measure more exactly the incidence of these two 
cleavages on account of the dulness of one of them, There isa 
third cleavage still more imperfect, and which corresponds with 
one of anorthite, but not with any of albite. 

Thin lamine of labrador are of a whitish-grey ; the fine reflec- 
tion of light which distinguishes this substance is given by one 
of the cleavages. 

The specific ‘gravity of a fragment of labrador (from Labrador, 
in America) weighing 10°576 grs. was found, using water at the 
temperature of 18° R. = 2°7025. 

e specific gravity of a fragment weighing 12:068 gr. from 
the same locality, using water at the temperature of 172° R, = 
2°695, 

According to Brisson, = 2692. 

According to Klaproth, = 2°690. 

Specific gravity of the labrador from Ingremanie, according 
to nights = 2°750. 

One hundred parts of labrador from Labrador, and an equal 
quantity of labrador from Ingremanie, contain, according to 
Klaproth, 

Labrador from Labrador. Labrador from Ingremanie. 
TGR» s stieia.s « ORONO. 
Alumina..... 26°50 ....sseees oe 0, 2400 
TARNG «nwo 5: ETFO ele oars civic ols ae inci aes 
Oxide ofiron. 1°25 ...ceceeeseees 5°25 
Oda. sescas LUD sepessoessas dy mae 
Water wsaneect ORL. seinesccpae nn dein. oe 


99-00 98°50 
Berzelius has calculated from these analyses the mineralogical 


formula 
WNS'+3CS8°+ 12 AS. 


Observations —Labrador and felspar present similar charac- 
_ters with the blowpipe; and for this reason Berzelius was induced 
to suppose that the mineral analyzed by Klaproth, under the 
name of labrador, was iridescent parenthine, with which it has 


1824,] Albite, Labrador, and Anorthite. 57 


great analogy of composition. However, an analysis undertaken 
by my brother, gave, excepting a greater quantity of alumina, 
almost the same results as that of Klaproth. This chemist has 
already demonstrated. that the iridescent felspar from Friedrich- 
warn, in Norway, cannot be ranked in this class; it is also dis- 
tinguished from it by the incidence of the two faces of cleavage 
which is equal to 90°.. The acids act upon this mineral in a 
different manner than upon felspar and albite ; for concentrated 
hydrochloric acid, according to Fuchs, entirely decomposes 
labrador, and has no action upon felspar or albite. 


fourth Species.—Anorthite. 


The primitive form of anorthite is a doubly oblique prism, 
fig. 5, 6, in which the planes M and T are inclined at an angle 
of 117° 28’; the planes M and P at an angle of 94° 12’, and the 
planes T and P at an angle of 111° 57’. The section perpendi- 
cular to the planes M and T is an oblique angled parallelogram, 
the obtuse angle of which of 117° 28’ is divided by the plane 
produced by two rows in breadth on the edge G into two angles, 
the one of 59° 30’ and the other of 57° 58’; the first of which 
has one of its sides in the plane T, and the other one of its sides 
in the plane M. The section perpendicular to the planes M and 
P is an oblique angled parallelogram, the obtuse angle of which 
equal to 94° 12’ is divided by a plane produced by a decrement 
by one row on the edge B of the primitive into two angles, the 
one of 46° 47’, and the other of 47° 25’; the first of which has 
one of its sides in the plane P, and the other one of its sides. in 
the plane M. The planes I have observed are; 

We ahs ao 5.2 2 
PMT .G.GHTBCAAAOA#A .0 sAE*(figs.7,8, 9). 


Pi aw tu ee ee oe ae a ee eee 


Incidences. 
BP OMIT ES ain) av.cs in colton eee Leu Re 
WON Mr ee wece oes ouinane vias 120 30 
Cs) pds Wg SS os eB BR kts B aways ae ry Sete 
Pen Zea CFR EROD Ss Sie viedo n Lae 1 
Ok ae Ee ea ae da are 1¢ } 
PUNO eC Siwc.vetlsio een tke ee 15U U3 
E OR e's' dividend sicbwal sooee 98 29 
i ODE pdciceoat Aveda op + 128% 22 
BT RO OEE Te heen See ee 145 12 
Pon facisd Cosh ae eMeeo 138 46 
PON O watiod ads iit es bo tition: Mal 60 
PP GAGs ae eed. Gimmie Oe wiecTs sake 94 53 
RGR See BEARS ORY (i) 184° 46 
Pa Pid LOOP RAR SP eee 51 °28 
1B RR dw cidi o's eles 6 RO 85 48* 


P0004 chee reBenkioret. 4 133 18* 


58 Mr. Rose on Felspar, Albite, Labrador, &c.  [JAn. 


P one. eooe eee eeweeseseeeenese 137° 22°: 
RT LA PRE I Nae Ee ARN 110 57 
BiGae .tweveva br dadl veosiin 125 38 
WEE Oval sennsalsind weld dees fea 
VOR EE oak 4G da Die tact lbh alain 122 45 
PERO eve: ak-'ps ssmebienentieydl AO 12 

DIB MK si ciek dee sulerlad WeRS ee ce 91 56 
PARE ce ntlicinnd cine teaniye 9 141 54 
ORG teins « sihav de Can Cutaberenus 98 37 
BY? GR pPtinene yairaisd neue seeoaeod thd Be 


Plane Angles of the Primitive Form. 


Those of plane P 121° 33’ and 58° 27’ 
M 116 15 63 45 
T 106 42 73 18 


Anorthite, as well as albite, although not quite so frequently, 
presents also hemitrope crystals, I have not given drawings of 
them, because they are formed exactly according to the same 
laws. This substance can be cleaved parallel to the planes P 
and M with equal facility. I have not been able to obtain a 
cleavage parallel to the plane T, and I have chosen it for one of 
the primitive planes in preference to the plane /, because it is 
generally much more brilliant. The fracture in other directions 
is conchoidal. The lustre of the cleavages is pearly, and that 
of the conchoidal fracture vitreous. 

Anorthite is found sometimes crystallized in small masses. 
The crystals are perfectly clear and transparent, but very small. 

The specific gravity of several fragments weighing 1°463 gr. 
by using water at the temperature of 14° R. has been found 
equal to 2°763. 

That of small crystals weighing 0°316 gr. mixed with a small 
quantity of pyroxene, by using water at 17° R. was found equal 
to 2°656. 

Concentrated hydrochloric acid entirely decomposes anorthite. - 
I have found 100 parts of anorthite, the specimens of which, as 
well as those of albite, J had obtained through the kindness of 
Mr. Weiss, from the collection of minerals in the University of 
Berlin, composed of 


Silex. . v's WX: «+++++ 44-49 which contains oxygen 22°38 7 11 
Alumina .2%. 004.6 34:46 16:096 16396 | 8 
Oxide of iron ...... 0:74 0:23 agate SD a sat 

Limes seu 0h. ot). « 15°68 440 | 2 
Magnesia.’......... 5°26 2°04 J 1 


Another analysis in which I had only 0-6 gr. to examine gave, 
however, similar results, and consequently the mineralogical 
formula is 


M8+2CS4+8AS 


1824.] MM. Levy’s Observations on the preceding Paper. 59 


when one part of 8 A 8 is replaced by FS. Anorthite has only 
been found hitherto in masses of carbonate of lime at Mount 
Somma, near Vesuvius, where it is accompanied only by green 
translucent pyroxene. 

Observations.—The mineralogical formula indicated above, 
appears to be the result of the analyses ; I cannot, however, 
warrant its exactness, because I could only operate upon very 
small quantities ; the first time with 0-628 gr.; the second time 
with 1-482 gr.: itis the result of this last analysis I have given. 
The formula would be analogous to other formule already known, 
if there was 9 AS, instead of 8 AS. Then it would be the 
same as that of meionite and paranthine, the formula of which is 
CS +3A 8%, with this difference, however, that one-third of 
CS in anorthite would be replaced by MS. Anorthite would 
then be referred to meionite, in the same manner as idocrase is 
to garnet, or, according to my brother’s analysis, pyroxene to 
wollastonite. 

I have provisionally given the name of anorthite to this mine- 
ral, derived from auvopdoc, which signifies without right angles ; 
because its crystalline form is principally distinguished from 
felspar, in not being at right angles to each other. Hauy, to 
whom the name of felspar did not seem proper, had suggested 
for this mineral the name of orthose, from two of its cleavages 
being at right angles to each other. 


ARTICLE XII. 


Observations on the preceding Paper, with an Account of a new 
Mineral. By M. Levy, MA. of the Academy of Paris, 


(To the Editor of the Annals of Philosophy.) 


SIR, Dec. 20, 1823. 


Since the notice you inserted in one of the preceding numbers 
of the Annals of Philosophy of the division { had made of the 
specimens commonly ranked under the name of felspar, into two 
distinct species, viz. felspar and cleavelandite, I have seen in the 
last number of the Annales de Chimie a paper by M. Rose, of 
Berlin, upon the same subject. An abstract of this paper is 
inserted in the present number of the Annals, and contains, in 
addition to the essential part of what I intended to publish, not 
only new analyses of both felspar and cleavelandite, and their 
specific gravities, but also the complete determination of two 
new species, viz. labrador and anorthite. In consequence of 
this, I shall limit what I proposed to send you, to a very few 
observations, which M. Rose’s paper does not render useless. 


60 ‘M. Levy’s Observations on the preceding Paper. [Jan. 
M. Rose has adopted, as appears from a determination of Weiss, 
an oblique rhombic prism for the primitive of felspar. I had 
assumed the same form, from the observation of the crystals of 
that substance 1 had an opportunity of examining in Mr, Tur- 
ner’s collection, as well as from the very figures given by Haiiy, 
and the measurements given both by him and Mr. W. Phillips. 
M. Rose has not stated the reasons which induced Weiss to alter 
the determination of Haiiy; and as I believe they are not 
generally known, since Mr. Brooke and Mr. W. Phillips, in their 
late publications, have adopted the primitive form of Haiiy, | 
shall briefly explain by what considerations I was led to the 
same result as Weiss.* 

On looking at the figures given by Haiiy in the last edition of 
his treatise on mineralogy, as well as on looking at any crystal 
of felspar, it will easily be seen that every one of them may be 
derived from an oblique rhombic prism, the lateral planes of 
which would be, for instance, the plane he has marked /, and 
the face opposite and parallel to T, and the base the plane P. If 
the primitive were not such an oblique rhombic prism as I have 
just described, one would expect to meet with a crystal contain- 
ing the face T without the face /, or the modification z without 
the modification z’, or s without s’, or n without n’, but the con- 
stant simultaneous occurrence of these groups of modifications 
perfectly symmetrical relative to the planes P, /, T, both in their 
positions and incidences, is certainly decisive. Moreover, in 
the form I have adopted, if a cleavage be found parallel to M, it 
must be at right angles to the base P, because M is equally 
inclined upon / and T, or because it is parallel to a plane through 
the oblique diagonals of the bases. This cleavage, as it is well 
known, exists in felspar, and is found perpendicular to P._ This 
angle of 90° would again be a very singular occurrence if the 
primitive were a doubly oblique prism. ‘The only argument in 
favour of Haiiy’s determination is, his assertion that there is a 
cleavage parallel to T, and none parallel to /, as should be 
the case, if /, as I have assumed, was one of the lateral primitive 
planes symmetrical to T. To this may be answered that even 
the cleavage parallel to T is in most cases very difficult to obtain, 
that this is not the only example of an oblique rhombic prism, 
in which one of the lateral planes is more easily obtained by 
cleavage than the other.t It is the case, for instance, in chro- 
mate of lead. Moreover, in some of the flesh-coloured speci- 
mens, I have succeeded in obtaining a cleavage parallel to /, by 
detaching first a thin lamina parallel to P. Finally, Hatiy men- 
tions the primitive he has adopted as one of the forms offered 
by nature : this form I have never seen ; and I doubt very much 
its existence, because it could not be derived from an oblique 
rhombic prism from which all the others are so obviously deduced. 


* See Annals of Philosophy for November. . 
+ See Brooke’s Familiar Introduction to Crystallography, p. 189. 


1824.] Mr. Levy’s Description of anew Mineral. 61 


The form M. Rose has taken for the primitive of cleavelandite 
differs only in its angles from that [had assumed. He gives for 
the incidence of T on M 117° 53’. I have constantly found it 
upon brilliant cleavage planes 119° 30’, or between 119° 30’ and 
120°, which makes a difference of 2° between our measure- 
ments; mine agrees with that obtained by Mr. Brooke, and I 
believe also by Mr. W. Phillips. This difference will of course 
change most of the angles calculated by M. Rose, but not so 
materially as to make it necessary to trouble you with the result 
of my own calculations. 

The flat crystals from St.Gothard are, as M. Rose had suspected, 
cleavelandite. It was indeed the observation of specimens of 
that locality which are not hemitrope, as most crystals of that 
substance are, that led meto the distinction of the two substances, 
and which gave me the best data for the determination of the 
primitive form. Mr. Turner’s collection contains a great variety 
of forms of that locality ; one of the most complicated I have 
represented in fig. 10. In some of the crystals, the planes I 


have marked d® and d’ are wanting, and then the crystal has 
precisely the same form as some of the varieties of felspar. In 
the same collection are found crystals which are not hemitrope, 
from the Tyrol and from Siberia. Those from this last locality 


are very large, and contain only the modifications p m ft and oF 
or o”, and the figure of the plane m is triangular. However, most 
of the crystals are hemitrope, but their form is generally much 
more complicated than those M. Rose has figured. He says in 
his paper this substance is never found laminar, but from North 
America, and from Silesia. I have seen specimens in large 
lamine, each of which is formed by the juxta-position of two 
laminz parallel to the face T of the primitive, so as to present, 
when cleaved parallel to P, the same re-entering angles offered 
by the hemitrope crystals of that substance. 


I shall feel obliged if you can spare room for a short descrip- 
tion of, [ believe, a very scarce and new mineral from Vesuvius. 
I have observed it upon a specimen Mr. Heuland purchased at 
the sale of Mr. Desse, to add to his private collection. This 
substance occurs in small brilliant colourless and translucent 
crystals. They are sufficiently hard to scratch rock crystal. 

r. Children, who kindly undertook to examine a small quan- 
tity of it, found it to be mostly composed of silex and mag- 
nesia. ‘The only form! have observed is represented by fig. 12, 
and the crystals cleave easily in the direction of the plane p. 
The angles I have measured with the reflecting goniometer led 
me to adopt for the primitive form of this substance, a right 
rhombic prism, fig. 11, the lateral planes of which corre~ 
spond to the planes marked m in fig. 12, and the base to the 
cleavage. The incidence of the two lateral planes of the primi- 


62 Analyses of Books. © . [Jan. 
tive is 128° 54’, and the ratio of one side of the base to the 
height nearly that of 4to 7. The other incidences are: 

(U’, p) = 126°. 6 

(b, #’)= 110 23. 


This substance is accompanied by pleonast and -olive-green 
pyroxene. 

I have chosen for it the name of forsterite, in honour of thé 
late Mr. Forster, who has so much contributed to the advance- 
ment of mineralogy by his extensive connections in that branch 
of Science in every part of the world, and by having laid the 
foundation of one of the finest private collections, now in the 
possession of Mr. Heuland. 


ArtTIcLeE XIII. 


ANALYSES oF Books. 


Philosophical Transactions of the Royal Society of London, for 
1823. Part II. 


Tuk following are the papers contained in this unusually volu- 
minous part of the Philosophical Transactions. 

XIII. On a new Phenomenon of Electromagnetism. By Sir 
Humphry Davy, Bart. Pres. RS. 

We have reprinted this communication in the present number 
of the Annals. 

_ XIV. On Fluid Chlorine. By M. Faraday, Chemical Assist- 
ant in the Royal Institution. Communicated by Sir H. Davy. 

In the next number of the Annals, we intend giving a full 
account of the contents of this paper, as well as of another, by 
the same chemist, on the Liquefaction of other Gases. 

XIV. On the Motions of the Eye, in Illustration of the Uses of 
the Muscles and Nerves of the Orbit. By Charles Bell, Esq. 
Communicated by Sir H. Davy. 

A brief abstract of this valuable paper will be found in the 
report of the proceedings of the Royal Society in the Annals 
for May, 1823; but we extract the section “ On the two condi- 
tions of the eye, its state of rest, and of activity,” on account of 
the peculiarly important nature of its contents. 

“The eye is subject to two conditions: a state of rest with 
entire oblivion of sensation, and a state of watchfulness, during 
which both the optic nerve and the nerve of voluntary motion are 
in activity. When the eye is at rest, as in sleep, or even when 
the eye-lids are shut, the sensation on the retina being then 
neglected, the voluntary muscles resign their office, and the 


1824.] Philosophical Transactions for 1823, Part II. 63 


involuntary muscles draw the pupil under the upper eye-lid. 
This is the condition of the organ during perfect repose. 

“On the other hand, there is an inseparable connexion be- 
tween the exercise of the sense of vision and the exercise of the 
voluntary muscles of the eye. When an object is seen, we 
enjoy two senses: there is an impression upon the retina ; but 
we receive also the idea of position or relation which it is not the 
office of the retina to give. It is by the consciousness of the 
degree of effort put upon the voluntary muscles, that we know 
the relative position of an object to ourselves. The relation 
existing between the office of the retina and of the voluntary 
muscles, may be illustrated in this manner. . 

“ Let the eyes be fixed upon an illuminated object until the 
retina be fatigued, and in some measure exhausted by the 
image, then closing the eyes, the figure of the object will con- 
tinue present to them: and it is quite clear that nothing can 
change the place of this impression on the retina. But notwith- 
standing that the impression on the retina cannot be changed, 
the idea thence arising may. For by an exertion of the volun- 
tary muscles of the eye-ball, the body seen will appear to change 
its place, and it will, to our feeling, assume different positions 
according to the muscle which is exercised. If we raise the 
pupil, we shall see the body elevated, or if we depress the pupil, 
we shall see the body placed below us; and all this takes place 
while the eye-lids are shut, and when no new impression is con- 
veyed to the retina. The state of the retina is here associated 
with a consciousness of muscular exertion ; and it shows that 
vision in its extended sense is a compound operation, the idea 
of position of an object having relation to the activity of the 
muscles. 

“We may also show, by varying this experiment, that an 
agitated state of the muscles, or a state of action where the 
muscles are at variance or confused, affects the idea of the 
image. Ifwe look on the liminous body so as to make this 
impression on the retina, and then cover the face so as to exclude 
the light, keeping the eye-lids open, and if we now squint, or 
distort the eyes, the image which was vividly impressed upon 
the retina instantly disappears as if it were wiped out. Does 
not this circumstance take place, because the condition of the 
muscles thus unnaturally produced, being incongruous with the 
exercise of the retina, disturbs its operation ? 

“If we move the eye by the voluntary muscles, while this 
impression continues on the retina, we shall have the notion of 
place or relation raised in the mind; but if the motion of the 
eye-ball be produced by any other cause, by the involuntary 
muscles, or by pressure from without, we shall have no corre- 
sponding change of sensation. 

“If we make the impression on the retina in the manner 
described, and shut the eyes, the image will not be elevated, 


64 Analyses‘of Books. —— [JAN. 


although the pupils be actually raised, as it is their condition to: 
be when the eyes are shut, because there is here no sense of 
voluntary exertion. If we sit at some distance from a lamp 
which has a cover of ground glass, and fix the eye on the centre 
of it, and then shut the eye and contemplate the phantom in the 
eye; and if, while the image continues to be present of a fine 
blue colour, we press the eye aside with the finger, we shall not: 
move that phantom or image, although the circle of light pro- 
duced by the pressure of the finger against the eye-ball moves 
with the motion of the finger. 

“‘ May not this be accounted for in this manner: the motion 
produced in the eye-ball not being performed by the appropriate 

"organs, the voluntary muscles, it conveys no sensation of change 
to the sensorium, and is not associated with the impression on 
the retina, so as to affect the idea excited in the mind? It is 
owing to the same cause that, when looking on the lamp, by 
pressing one eye, we can make two images, and we can make the 
one move over the other. But, if we have received the impression 
on the retina so as to leave the phantom visible when the eye-lids 
are shut, we cannot, by pressing one eye, produce any such 
effect. We cannot, by any degree of pressure, make that image 
appear to move, but the instant that the eye moves by its volun- 
tary muscles, the image changes its place; that is, we produce 
the two sensations necessary to raise this idea in the mind ; we 
have the sensation on the retina combined with the conscious 
ness or sensation of muscular activity. 

“These experiments and this explanation of the effect of the 
associated action of the voluntary muscles of the eye-ball, appear 
to me to remove an obscurity in which this subject has been left 
by the latest writers. In a most scientific account of the eye 
and of optics, lately published, it is said on this question, ‘ we 
know nothing more than that the mind residing, as it were, in 
every point of the retina, refers the impression made upon it, at 
each point, to a direction coinciding with the last portion of the 
ray which conveys the impression.’ The same author says, 
‘ Kepler justly ascribed erect vision from an inverted image to 
an operation of the mind, by which it traces the rays back to the 
pupil, and thus refers the lower part of the image to the upper 
side of the eye.’ What can be here meant by the mind follow- 
ing back the ray through the humours of the eye ? It might as 
well follow the ray out of the eye, and, like the spider, feel along 
the line. A much greater authority says we puzzle ourselves 
without necessity. ‘ We call that the lower end of an object 
which is next the ground.’ No one can doubt that the obscu- 
rity here is because the author has not given himself room to 
illustrate the subject by his known ingenuity and profoundness. 
But it appears to me, that the utmost ingenuity will be at a loss 
to devise an explanation of that power by which the eye becomes 
acquainted with the position and relation of objects, if the sense 


1824.] Proceedings of Philosophical Societies. 65 


of muscular activity be excluded, which accompanies the motion 
of the eye-ball. . 

“« Let us consider how minute and delicate the sense of mus- 
cular motion is by. which we balance the body, and by which 
we judge of the position of the limbs, whether during activity 
or rest. Let us consider how imperfect the sense of touch 
would be, and how little of what is actually known through the 
double office of muscles and nerves, would be attained by the 
nerve of touch alone, and we shall be prepared to give more 
importance to the recti muscles of the eye, in aid of, the 
sense of vision: to the offices performed by the frame around 
the eye-ball in aid of the instrument itself.” . 

A plate accompanies this communication, showing the mus- 
cles of the eye as seen in front, and in profile. © 


(To be continued.) 
ArTicLe XIV. 
Proceedings of Philosophical Societies. 


ROYAL SOCIETY. 


es | 

Tue first meeting of this Society for the present session took 
ei on the 20th of November last, when Major Gen. Sir G. 

urray and John Rennie, Esq. were admitted Fellows; and the 
Croonian Lecture was read, 

On the Anatomy of the Human Brain as compared with that 
of Fishes, Insects, and Worms; by Sir E. Home, Bart. 
V.P.R.S. 

This lecture was very short, and consisted, principally, of 
remarks illustrative of the microscopical drawings by Mr. Bauer, 
with which it was accompanied, some more particular observa~ 
tions being reserved for the explanation of them. Occasion 
was taken to award a high and just tribute to the microscopical 
investigations of Swammerdam, which were unequalled, by any, 
it was remarked, except those of Mr. Bauer. The ability of 
both observers was of such and so rare a nature, that, with 
respect to each, it had been ascribed to some particular con- 
struction of the microscope; and it had even been suspected 
that Swammerdam had a peculiar method of using the in- 
strument, which had died with him. 

A portion of very recent human brain, merely steeped in 
distilled water, was examined by Mr. Bauer, who perceived in 
it rows of globules proceding in straight lines from the cortical 
into the medullary part. A comparison was’ instituted of the 
human brain with the same organ im fishes, insects, and worms. 
In the tench, the brain has a central cavity, and its basis is 
nodulated. In the bee, that organ is larger in proportion than 

New Series, vou. vit. F 


66 Proceedings of Philosophical Societies, » (Jan. 


in the other insects which have been examined ; it is also large: 
in the moth and in the caterpillar. : 
The reading was commenced, likewise; of Some Observations 
on the Migration of Birds; by the late Dr. Edward Jentier, 
F,R.S.; communicated by his Nephew, Mr. H. C. Jenner. 
Nov. 27.—Dr. D. Cresswell and Prof. Barlow were admitted 
Fellows of the Society; and the reading of Dr. Jenner’s paper’ 
was concluded. di 
Dr. Jenner had intended to present this paper to the Royal 
Society himself, but was prevented from fully completing it, as 
to arrangement, by his extensive correspondence on the subject 
of vaccination. It commences with some general observations 
on the Migration of Birds, and particularly with respect to their 
capability of taking such great flights as migration must require, 
and which some writers have questioned. Dr. Jenner brings 
forward various facts, to show that there are no grounds for 
such doubt ; among which are the following: a hobby-hawk 
was seen in a vessel near Newfoundland ; and an owi, seemingly 
the common brown owl, flying above the Atlantic wave, with as 
much agility as if pursuing a mouse in the fields; cuckoos, 
snipes, and other birds, have likewise been seen in the Atlantic ; 
a flock of birds resembling linnets settled on the rigging of a ship, 
remained awhile chirrupping in concert, and then flew away ; 
geese have been caught in Newfoundland with their crops: full 
of maize, a species of corn which is not grown but at an ime 
mense distance from that island. The discussion of this branch 
of the subject is succeeded by some remarks on the faculties of 
discrimination and guidance which must be exercised by birds, 
in the long flights thus taken, and which, Dr. J. conceives, must 
be of some peculiar and unknown nature; pigeons, it is ob- 
served, which have been takenseveral hundred miles, completely 
secluded from the light, by being shut up in a box, will, when 
set at liberty, immediately return to the place whence they were 
taken. The periodical disappearance and return of birds has 
been ascribed to hybernation, but of this Dr. Jenner never wit- 
nessed an instance ; nor could he ever obtain any satisfactory 
evidence of it. When birds appear for the season, they are 
never in the emaciated and weakened state attended with loss 
of fat, seen in hybernating quadrupeds when they quit their 
retreats ; but, on the contrary, they are quite vigorous, and-as 
active as at anyperiod. With regard to the supposed immersion 
of birds in ponds and rivers for the winter, Dr. J. remarks, that 
their respiratory organs are very similar in structure to those of 
quadrupeds, and are no better adapted for performing their 
functions under water. He took a swift, about the 10th of 
August, or on the eve of its departure, and held it under water, 
when it died in two minutes. It has been conjectured, that 
repeated alternate immersions and emersions might have the 
effect of altering the corresponding action of the heart and 


Sn ee ee ee 


1824.] Royal Society. 67 


lungs; but though swifts and martins, it is observed, in reply 
to this conjecture, frequently splash in the water over which 
they are skimming, yet they never immerge themselves in it, and 
indeed if they were to do so, their wmgs would become so wet 
as to prevent their flymg. The common duck, when pursued 
aud forced to dive repeatedly, by a water-dog, arrives at the 
surface again much exhausted; as is likewise the case with 
grebes and auks, after repeated diving. Dr. Jenner had been 
inthe habit of receiving Newfoundland dogs from that country, 
and had ascertained that they never continued under water for 
more than thirty seconds, and even then seemed confused when 
they came up. It had been asserted that negro and other 
divers remained under water several minutes; but Dr. J. con- 
ceives this assertion to be grounded only on a vacue guess, 
and that the time was not measured by a stop-watch. i 

_The next division of the paper relates to the remarkable 
effect of instinct in birds, of their returning to build on the 
same spot for many successive seasons. The author took twelve 
swifts from their nesis in a barn, indelibly marked them all, by 
taking off two claws from one foot of each, and then set them 
at liberty. Some of them were caught again on the same spot, 
at the expiration of a year, and others after two years bail 
elapsed ; they were not attended to afterwards, but at the expi- 
ration of seven years from their original capture, one of these 
matked swifts was brought in by a cat. 

Dr. Jenner next proceeds to state, as the cause of the migration 
of birds, that the tumid and enlarged state of the testes in the 
male, and of the ovariain the female, at the seasonof their depar- 
ture, prompt the animals to seek those countries where they can 
obtain proper succours for their offspring;—that, in fact, the 
nestlings are the objects of this provision. .The parent. birds 
leave the countries they migrate from at a time when their own 
wants are completely supplied ; and they remain in those to which 
they migrate, nolonger than suffices forthe rearing of their young, 
Thus the swifts arrive in this country about the Sth or 6th of 
April, and depart hence about the 10th of August.—Dr. Jenner 
here observes, as a remarkable circumstance, that Ray, who 
attributed the migration of fishes to its true cause, that. of 
seeking proper situations for spawning, overlooked the cor- 
responding impulse as actuating birds.—The martins, leave 
this country successively, some continuing to rear a brood 
much later than others: many of these birds roost in the walls 
of Berkeley Castle ; and Dr. Jenner found, by dissecting anum- 
ber, taken at the same time, that the ovaria of the females were 
iu a variety of states ; in some the eggs being no bigger than 
hemp seed, while in others they were as large as peas; the 
testes of the males exhibited analogous degrees of tumidity. 

Swallows are seen flying over pools and waters in spring, 
in search of the gnats on which they are then obliged to 


¥ 2 


68 Proceedings of Philosophical Societies. (Jan. 


feed; and not because they have arisen from the waters. Their 
usual food, like that of swifts and martins, is a species of sca- 
rabeeus, as the author ascertained by dissection. 

Birds that rear several broods in the season, frequently leave 
the last brood to perish; thus a pair of swifts that had brought 
up three broods in one nest left the fourth to perish ; and the 
mother came back in the following year, threw outthe skeletons, 
and laid in the nest again. Many nests of late birds, of various 
species, are deserted in this manner by the parent animals; but 
the latter thus leave the country when it abounds with their own 
food. 

The young birds, it is remarked, cannot be directed in their 
0 a flights by the parents, but must be guided by some 
unknown principle: if it be admitted in the case of swifts, 
martins, and other birds associating together in flocks, that the 
young may be directed by the motions of their fellows, yet this 
cannot be the case with the nightingales ; nor with the cuckoos, 
who, though reared in the nests of many different birds, are re- 
gular migrators. The parent cuckoo has left the country before 
its peat are reared, always departing early in July. 

r. Jenner next gives some particulars relative to the enlarge- 
ment of the testes and ovaria in birds, supplementary to those 
which have been pointed out by Mr. John Hunter. In those birds 
who pair but for a short time the testes are small, while in those 
with whom the connubial compact is of long continuance, they 
are large. In the cuckoo, a polygamist, and who continues 
with the female but for a very short time, the testes are of the 
size of a vetch only ; but in the wren, whose attachment to his 
mate extends from spring to autumn, they are equal to a pea in 
magnitude ; thus much larger in the latter than in the former, in 
proportion to the size of the bird. A continued supply of gene- 
tative power is required in birds who pair for a long time, in 
case the brood should be destroyed—but in those like the cuckoo 
this provision is unnecessary. 

The winter birds of passage leave this country for precisely 
the same reason thatimpels the spring migrators to come hither; 
some of them, as the wild-duck and the wood-pigeon, which 
occasionally build here, are irregular in their migration; the 
most regular are the red-wing and the field-fare, of whose 
building in this country Dr. Jenner never met with an instance. 
The food of the former, he observes, is not haws, or the fruit of 
the white thorn, as has been stated, but worms and insects, 
which they gather from the ground, feeding in flocks; Dr. J. 
had seen them dying of famine when haws were abundant. A 
gentleman saw a flock of field-fares on the day before the thaw- 
ing of the great frost of 1794, and they seemed as wild and vi- 
gorous as if in season ; he shot one, which Dr. Jenner examined, 
and found to be in excellent condition, but there was no food in 
' the stomach, and the last which the animal had eaten was di- 


1824.] Royal Society. 69 


gested : now as the ground was covered with snow, and as the 
long frost had destroyed everything they could feed on, these 
field-fares must have returned here for a short time, in conse- 
quence of the inclemency of the weather abroad. Red-wings 
and field-fares always leave this country when they are in the 
best condition. The approach of severe frost is indicated by 
the arrival of water-birds, as that of thaw is by the coming of 
the spring migrators. Hirds often outstrip in their migrations 
the progress of the frost itself. 

Dr. Jenner considers that Dr. Darwin must be mistaken in 
what he says respecting cuckoos seen feeding their young. The 
birds in question must have been goat-suckers, which are very 
easily confounded with cuckoos by those who are not fully con- 
yersant with the characters of their plumage, &c. 

This very interesting paper concludes with a recapitulation of 
the principal facts contained in it, and of the author’s views 
ee them. 

ec. 1.—The anniversary meeting took place this day (St. 
Andrew’s Day falling on a Sunday), and was numerously attended. 

After stating the names of those Fellows whom the Society 
has had the misfortune to lose since the last anniversary, the 
President, Sir H. Davy, delivered a discourse, in which he no- 
ticed such of them as had by their communications to the 
Society, or by their philosophical labours, advanced the progress 
of science. In presenting the following sketch of the Presi- 
dent’s address, we wish it to be distinctly understood that we 
pretend to offer a mere outline ; it is quite impossible, in the 
space to which we are necessarily confined, to impart to the 
reader an idea of the high and eloquent eulogium which the 
President bestowed upon the memory and labours of someof the 
deceased Fellows.—Beginning with Dr.Hutton, he observed, that 
his labours of more than half a century had established his re- 
putation as one of the most able mathematicians of his country 
and age ; after alluding to the papers which had been published 
in the Transactions of the Society, he observed, that during the 
long period that he was Professor at Woolwich, he might be 
regarded as having eminently contributed to awaken and keep 
alive that spirit of improvement among the military students, 
which has so much contributed to the character of the British 
officer, and which has been attended with such beneficial results 
to the country. The merits of Dr. Hutton as an experimental 
philosopher, the President observed, were of no mean kind ; 
they were displayed in his paper on Gunnery, for which he re- 
ceived the Copleyan medal, in 1778: this paper contained an 
account of some difficult and delicate experiments on the force 
of gunpowder, from which conclusions were drawn connected 
with important practical results. Sir Bahay then observed, 
that Dr. Hutton’s greatest work was, perhaps, his calculation of 


the Density of the Earth, founded upon Dr, Maskelyne’s expe- 


70° Proceedings of Philosophical Societies. (Jan. 


riments on the effects of Schehallien on the Plumb-line. | This 
labour, €omprehending the most complicated arithmetical pro- 
cesses, the President observed, would for ever associate his name 
with one of the grandest and most important physical problems 
solved in the last century, and transmit it with honour ‘to 
posterity. tie 

' To'speak of Dr. Edward Jenner as a man’of science of our 
own particular school, the President observed, would be sayin 
little, for he had a higher claim to our deep regret and profound 
admiration as a benefactor to mankind in general —After ad- 
verting to the invention and effects of vaccination, Sir Hum- 
phry Davy remarked, that the originality of Dr. Jenner’s mind 
and the accuracy of his observation are shown in his first 
communication to the Society, on the Natural History of the 
Cuckoo; and in the pursuit of his great object, he met with 
obstacles which required no ordinary degree of perseverance, 
and of confidence in his own powers to overcome ; the fair way 
of judging of the merits of an inventor, said Sir Humphry, is 
by the operation of his discovery on civilized and social life ;— 
and in this respect Dr. Jenner stands almost alone. 

Of Dr. Baillie, the President observed, that whether consi- 
dered as a physician or as a man, his talents and his virtues 
were alike distinguished,—his works show the accuracy and 
coolness of his judgment; his minuteness in observation ; and 
his acuteness in referring effects to their true causes, amidst 
the complicated phenomena offered by diseased organs. No 
man was ever more free from any taint of vanity or affectation ; 
he encouraged and admired every kind of talent, and rejoiced 
in the success of his contemporaries ; and he maintained, even 
at court, the simplicity and dignity of his character. 
~ Col. Wm. Lambton, the President observed, was a veteran in 
the army of India : two papers of his are published in the Trans- 
actions of the Society, on the Admeasurement of an Are of the 
Meridian in Hindostan—a work of great labour, displaying 
minute accuracy and.extraordinary perseverance, and carried on in 
a climate unfavourable to bodily exertion or intellectual pursuit. 
This are extends in amplitude very nearly ten degrees; and 
Col. Lambton had the honour of haying laid down the largest 
single are ever measured upon the surface of the globe. 

The President, when noticing Archdeacon Wollaston, observed 
that the little which he had contributed to the Society’s Trans- 
actions occasioned regret that he had not been a more frequent 
contributor.—His papers, said Sir Humphry, on the Measure- 
ment of Heights, and on the Alteration of the Boiling Tempe- 
rature, offer a valuable resource in ascertaining the altitudes of 
mountains, and are remarkable for accuracy of method and 
distinctness of detail. . 

After making respectful mention of Dr. Cartwright and Mr. 
Jordan, the President proceeded to make some observations on 


1824.] . Royal Society. 71 
the award of the Copleyan medal, to John Pond, Esq, Astronomer 
Royal, for his yarious observations and communications pub- 
lished by the Royal Society; we can give a still fainter idea of 
this discourse, than of the tributes of praise to the deceased 
members : it was received by the Society ina manner which 
evinced their strong desire that it should be made a permanent 
record by the press. 

_ Having given an historical sketch of the labours of the 


Coe elo eer 


try were peculiarly necessary, on account of its maritime and 
colonial empire, the President observed, that astronomy had 
exerted a powerful effect in the general improvement of the 
human mind, by developing the true system of the universe. In 
consequence of the discoveries made in it, all the superstitious 
notions—all the prejudices respecting the heavenly bodies, 
which had such an effect upon the destinies of individuals and 
of kingdoms in ancient times, have disappeared ; and the science 
as it now exists is the noblest monument ever raised by man to 
the glory of his Maker; for its ultimate and refined develope- 
ments demonstrate combinations which could only he the result 
of infinite wisdom, intelligence, and power. 


72 Scientific Intelligence. (Jan. 


On presenting the medal to the Astronomer Royal, the Presi- 
dent addressed him nearly as follows :—I now present you this 
medal.—Consider it as a token of the respect of the Society, and 
of the confidence of the Council'in the great accuracy of your 
observations: receive it likewise as a memorial that future 
important labours in the same department of science are hoped 
for, nay, are expected from you. I am well aware that some 
of the greatest and most important objects of discovery, and 
those, perhaps, most obvious, have been attained by the labours 
of your predecessors. Yet Nature is inexhaustible; and the 
powers and resources of the human mind, and the refinements 
of art, have not as yet attained their limits. Who would have 
anticipated, half a ceutury ago, the discoveries of Herschel and 
Piazzi? 

Though pursuing a science that may be considered as in 
its maturity, you have advantages of a peculiar kind; more per- 
fect instruments than were ever yet employed ; more extensive 
assistance than any of your predecessors ; and upon these points 
the liberality and promptitude with which Government have 
entered into all the views of the Council of the Royal Society for 
the improvement of the Royal Observatory, cannot be too much 
admired. Continue to pursue your honourable career, and 
endeavour to be worthy of having your name transmitted to 
future generations with those of your illustrious predecessors. 
Of all the branches of science, astronomy is that from which this 
Society has gained most glory, and it never has lost, and I feel 
convinced never will lose, any opportunity of advancing its pro- 
gress, and honouring its successful and zealous cultivators. 


ARTICLE XY. 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS 
CONNECTED WITH SCIENCE. 


I. Supposed Origin of the Art of Smelting Iron. 


Tue following remarks explanatory of a passage in the Rev. J. 
Hodgson’s “ General Conclusions of an Inquiry into the Era when 
Brass was used for Purposes to which Iron is now applied,” inserted in 
the last number of the Annals, at p.407, were precluded from appear- 
ing in their proper place as a note to the paper, by circumstances 
attending their passage through the press. 

It would appear, from a paragraph in the former part of his paper 
(Arch. /El. vol. i. p. 40), that Mr. Hodgson conjectures the idea of 
producing metallic iron by the artificial application of fire to its ores, 
to have been suggested to mankind by the observation, that the stones 
containing malleable iron, or meteorites, descended upon the earth in 


1824.) Scientific Intelligence. 73 


an ignited state, or from fiery bodies in the atmosphere ; though the 
application of the terms aérolzte and meteoric stone to meteoric iron and 
stones indiscriminately, render his remarks somewhat ambiguous. 
There really exists, however, an indeterminate kind of transition, from 
the masses of meteoric iron entirely free from earthy or stony matter, 
to the meteoric stones in which that metal is merely disseminated in 
grains, Thus, placing the Brazilian or Cape iron, and the Benares or 
L’ Aigle stones at the extremities of the scale, the intermediate degrees 
will be formed by the Siberian iron, with its globules of (so called) 
meteoric olivine, the Elbogen iron in which globules of a similar sub- 
stance are imbedded, and the stones which fell near Tabor, in Bohemia, 
in 1753, containing nearly one-fourth of their weight of iron. A suf- 
ficient quantity of the metal to impart a knowledge of its usefulness 
might have been separated from such stones as the latter, without 
much difficulty ; and thus (allowing the validity of Mr. Hodgson’s con- 
jecture), mankind might have been led to the smelting of iron from its 
ores. It seems, indeed, that the Esquimaux inhabiting the western 
coast of Greenland, visited by Capt. Ross, actually edge their bone 
knives with small pieces of iron extracted from a meteoric stone, and 
flattened for the purpose. Mr. Hodgson is not the only writer who 
has attributed the first knowledge of metallic iron to the observation 
of native meteoric masses of that metal, for this idea has also been 
expressed by Mr. D. Mushet, in his article on Iron-making, in the 
Supplement to the Encyclopedia Britannica. The circumstance is 
somewhat remarkable, that the same extraordinary masses of iron, 
which, when first discovered, and even for a considerable subsequent 
period, were supposed by various writers to have resulted from ancient 
smelting opetations, should now be considered as having pointed out 
to mankind the means of obtaining that metal by smelting. 

Mr. Hodgson appears to have been misinformed with regard to the 
balls of iron-stone found in Sicily, which he alludesto: they certainly 
have no similarity zm substance “to the true a€rolites;”? aérolites 
have no peculiar oe but are extremely various and irregular in that 
respect; and the balls of iron-stone have no doubt received the appel- 
lation of thunderbolts for the same reasons, indirectly derived from a 
knowledge of meteorites, which induced different nations of antiquity 
to confer it on various other minerals, and even on certain organic 
remains, 


II. Composition of Ancient Bronze. 

The following particulars respecting ancient bronze are derived from 
two papers by the late Dr. E. D. Clarke, read before the Society of An- 
tiquaries a few years since, and published in their Archzologia ; but 
not hitherto transferred to any more general medium of scientific 
information. 

In Dr. Clarke’s ** Observations upon some Celtic Remains discovered 
near Sawston, seven miles from Cambridge,” Arch. vol. xviii. p. 340— 
343, he describes certain antiquities which had been found on the 
3d of August, 1816, accompanying a human skeleton, about three feet 
below the surface of the ground, on the top of a small eminence called 
Huckeridge Hill. ‘They consisted of two vessels of bronze, some 
fragments of the coarsest black terra cotta, an iron sword entirely con- 
verted into oxide, a massy bronze ring which had been the foot of the 
Jarger vessel, the iron umbo of a shield, a bronze broach or buckle, 


74 Scientific Intelligence. (Jan. 


and a'small iron fibula, . There was nothing Roman in their character; 
the form of the sword, in the Rey. Mr. Kerrich’s opinion, was not 
Roman ; the fragments of terra cotta resembled those found with Celtic 
remains ; and these circumstances, notwithstanding their being disco- 
vered near the Roman station upon the Gog Magog Hills, tended 
to show that they were not of Roman origin. The vessels’ consisting 
of an alloy of copper and tin seemed likewise, in Dr. Clarke's opinion, 
to refer these remains to an earlier period than the time of the Romans 
in Britain, 

Dr. Clarke found that the bronze of which the vessels were made, 
was composed of 88 parts of copper, and 12 of tin: he ascertained, 
also, that the bronze coins of Antoninus Pius and of Marcus Aurelius 
consisted of the same alloy. 

In his “ Account of some Antiquities found al Fulbourn in Cambridge- 
shire,’? Arch xix. 56—61, Dr. C. describes two swords, a spear-head, 
and two ferrules supposed to have been the feet of spears, which were 
found on Fulbourn Common early in J$17. They were all of bronze, 
the spear and swords formed on the Grecian model; a bronze sword 
resembling the latter had been taken out of the river Cam many years 
before, and swords of the same kind had been found in Ireland. ‘The 
alloy was hard and brittle; its fracture, earthy, white, and destitute of 
metallic Justre, but upon filing showed the splendour and colour of 
guld ; its specific gravity was 9200; it consisted, like the bronze of 
the other relics, of 88 copper and 12 tin. 

Dr. Clarke adverts, in the conclusion of this paper, to the “ uniform- 
ity characterising a]l the results which different chemists have obtained 
in the analysis of ancient bronze ; a degree of uniformity,” he conti- 
nues, “ hardly to be explained without supposing that there may have 
existed a native compound of the two metals thus united. In almost 
every instance the proportion of the copper to the tzn has been 88 to12. 
This was the result of the analysis made by Mr. Hatchett, of the bronze 
nails brought by Sir Wm. Gell from the tomb of Agamemnon, at 
Mycene ; the same result was also obtained in the analysis by Dr. 
Wollaston, of some arrow-heads of bronze found in the South of Russia; 
and I have found the same constituents similarly combined in various 
specimens of bronze from Grecian and from Celtic sepulchres; in the 
bronze lamps of ancient Egypt, and in the Jares, weapons, and other 
bronzes of thesame country. That in the analysis of bronze, found in 
countries widely separated, there should not be a more perceptible 
difference in the proportion of their chemical constituents, is aremark- 
able circumstance. The Gaulish axe found in France, by M. Dupont 
de Nemours, and which cut wood like a steel axe, might be considered 
as an exception; because it contained, according to the analysis of 
Vauquelin, 87 parts of copper combined with 9 parts of tin; but in 
this axe there were also present 3 parts of zron; perhaps an impurity 
of the tx ; which is rarely free from an admixture of other metals. 
The tin of the Fulbourn swords, when exposed to a violent heat, 
yielded an alliaceous smell denoting the presence of arsenic; and a 
very small portion of a black insoluble powder remained in the ztric 
acid after the solution of the copper. 

“To conclude, therefore, if we may be permitted to consider these 
bronze reliques as so many characteristical vestiges of a peculiar peo- 
ple, to whom the art was known of giving a maximum of density to 


1824.] Scientific Intelligence. 75 


copper and tin, by a chemical operation, we shall be at a loss, either to 
ascertain their origin,’ or to account for their wide dispersion. Such 
reliques, as it has been proved, are found alike in Egypt and in Greece, 
in Great Britain, and in Ireland. To this it may be added, that the 
most ancient bronze coins of India (of which I have lately analyzed 
some that were found near the Byzantium of Larice, upon the Baryga- 
zenus Sinus), consist of a similar alloy ; and I have reason to suspect 
that the bronze idols of Tahtary, and of China, will, upon a chemical 
examination, be found to contain the same ingredients,” 


Ill. Parhelia, &c. 


The following is an account of parhelia and other phenomena 
observed at Darlington, in the county of Durham, on the 30th of Oct. 
1823. 

The writer saw it first at ten minutes past twelve. 

Ina line with the sun, and equidistant from it, were two bright 
spots coloured like the rainbow, from one of which came a stream of 
light in a horizontal direction. These spots appeared to be the ter- 
mination of a bright semicircle, having the sun for its centre, and 
arching upwards. The most surprising part of the sight was another 
arc diverging contrarywise, having the same or a larger radius, and 
joining the other at the back, or outer side... The most beautiful part 
of the sight was another double arc, just like the one I have described, 
in or near the zenith; very bright, and having all the colours of the 
rainbow, ‘The phenomenon, varying only in the degree of brightness, 
continued for three-quarters of an hour, and one of the spots remained 
ten minutes longer. 

The sky was nearly or quite cloudless, and very misty; the wind 
due north. Light clouds soon made their appearance after the arcs 
disappeared. 

A letter from the same observer, dated Nov. 17, 1823, giyes further 
particulars, viz. 

The two parhelia appeared on the external margin of the prismatic 
semicircle, at the two extremities of its horizontal diameter. The 
brighter one lasted the longest. The colours were not very well 
defined ; yellow predominated. The arcs nearest the sun had the 
least of colour in them, being scarcely more than bright or luminous 
appearances ; the more distant ones had a good deal of colour. 

I also observed, which I think I did not before mention, about 90° 
from the sun, and about its altitude, a large faintly bright spot, and a 
light streak from it in a horizontal direction, both quite colourless; 
this was visible nearly as long as the rest of the phenomenon. 

It would be interesting to know over what extent of country the 
phenomenon presented the same appearance. In some parts it might, 
perhaps, appear more perfect. . 


IV. Effect of Heat in lessening the Cohesive Force of Iron. 


A bar of malleable iron, three feet in length, and one inch square, 
was heated to 212°, and the machine for measuring its flexure being in 
readiness, so that a weight of 300 bs. could be instantly let down upon 
the bar; while at the same time the observer adjusted the index to 
zero. ‘These operations having been effected in a close and warm 


76 Scientific Intelligence. (Jan. 


room, with as little loss of heat as possible, the windows were thrown 
open, the heating bath removed, and the effect of cooling observed. 

The flexure decreased as the bar cooled, and after it had remained 
two hours in order to be cooled down to the temperature of the room, 
which was 60°, the flexure had decreased three-fourths of one of the 
divisions of the scale ; and when the weight was raised from the bar, it 
returned through 14 divisions. Hence we may conclude that by an 
elevation of temperature equal to212° — 60° = 152 degrees, iron 
loses about a twentieth part of its cohesive force, or will bend one- 
twentieth more by the same load. This is equal to about a 3000th 
part for each degree.—(Tredgold on Cast Iron, 2d Edit. p. 104.) 


V. Correctness of Greenwich Observations. 
(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Blackmansstreet, Dec. 20, 182A. 


In the October number of the Annals, a notice was inserted by me, 
wherein it was stated, ‘a communication has, we understand, been 
received from Mr. Bessel, acknowledging that his catalogue of princi- 
pal stars requires a correction for instrumental flexure, thereby admit- 
ting the superiority of the Greenwich one.” It seems, however, that 
the accuracy of the report is by Messrs. Tilloch and Taylor contra- 
dicted ;* upon what grounds, it is immaterial to inquire: but as a 
charge of misrepresentation is insinuated, I shall merely state, that a 
letter was sent by Dr. ‘Tiarks (a German astronomer in the pay of the 
British Government), containing an extract of a letter (translated into 
English) which he had received from Mr. Bessel, couched in such a 
manner as to induce the gentleman to whom it was addressed, to trans- 
mit to Mr. Troughton a note, informing him of Mr. Bessel’s 
concession ; and which note was shown to me, as well as to many 
others, interested in these matters. Not, however, content with 
having done thus much, Dr. Tiarks subsequently called upon Mr. 
Troughton, and with much apparent satisfaction, personally communi- 
cated to him the same concession on the part of his friend ; and among 
other things said, ‘* Bessel had acknowledged that had he used Pond’s 
mode of observing sooner, he should have gotten his latitude cor- 
rectly.” And at this time there can be no doubt but that Dr. Tiarks 
considered himself justified in promulgating Mr. Bessel’s acknowledg- 
ment of the superior accuracy of the Greenwich catalogue. What new 
light may have since broken in upon this gentleman, | do not pretend 
to know; it is right, however, the readers of the Anzals should be 
apprised, that the communication was not made to them upon slight 
grounds. Mr. Bessel also should be informed, that whatever “ zdle 
reports”? (ifsuch they at present be) have gone abroad, are of German, 
not of British origin; and that they have been circulated by the indus- 
try of his own friend, and from a letter of his own writing. 

JAmEs Soptu. 


VI. British Museum and Edinburgh Review. 
The author of an article in the Edinburgh Review, on the British 


* Philosophical Magazine for Noveinber last. 


1824.] New Scientifie Books. 77 


Museum, would feel much obliged to the Editor of the Annals of Phi- 
losophy, if he would permit him, through the mediura of the Annals, 
to correct a few errors which have crept into the above article, and 
which might be considered as instances of bad faith or ignorance were 
they not acknowledged to proceed from the hurry of the moment, and 
the want of an opportunity of correcting the proof sheet. 

Page 382.—The price of the Elgin marbles is stated at 8000/.; but 
it should have been 6000/. 

_ Page 385.—Murex Carinatus is misprinted M. carineelus. 

Page 389.—The paragraph beginning “ The purchases made two or 
three years ago by Dr. Leach,” should have run thus:—‘‘ The pur- 
chases made several years ago for the Museumincluded some extremely 
rare and splendid trochili, or humming birds, some of which would 
bring three or four guineas a piece.” 

Page 390, line 18.—‘‘ This immense herbarum,” should have been, 
« His immense, &c.” 

Page 390.—The trustees are said to be 41 ; but they are now 43. 

Page 391.—They should have been stated at 21 official trustees, 
including the three principal Secretaries of State; 7 family trustees, of 
which 1 represents the family of Sloane, 2 that of Cotton, 2 that of 
Harley, 1 that of Townley, and 1 Lord Elgin. The elected trustees 
are 15, making in all 43. 

There are a few minor errors of trifling importance, because they 
do not affect the accuracy of the statements: but the author has the 
satisfaction of knowing that his strictures have produced a sensation in 
the quarter where he most desired it; and the next opening of the 
Museum will convince the public that his animadversions have pro- 
duced beneficial effects. He has been the cause of the destruction of 
numberless moths ; and some of the insect treasures of the Museum 
have been recently brought to light. He had but one object—to call 
public attention to a great abuse; and if his zeal for the cultivation of 
a favourite study has betrayed him into warmth of expression, he hopes 
that he has indulged in no unbecoming personalities. 

An OLD CoRRESPGNDENT, 


Articte XVI. 
NEW SCIENTIFIC BOOKS. 


PREPARING FOR PUBLICATION, 


M. de la Beche will shortly publish a Selection of the Geological 
Memwirs contained in the Annales des Mines, together with a Synop- 
tical Table of Equivalent Formations, and M. Bronguiart’s Table of 
the Classification of Mixed Rocks: in | vol.8vo. 

Mr. C. Chatfield has in the press a Compendious View of the History 
of the Darker Ages, with Genealogical Tables; to form | vol. 8vo. 

A Guide to the Mount’s Bay and the Land’s End, comprehending 
the Topography, Botany, Agriculture, Fisheries, Antiquities, Mining, 
Mineralogy, and Geology, of Western Cornwall: Second Edition. 
Ilustrated by Engravings on Copper and Wood. By a Physician. 
To form 1 pocket volume, 


78 New Patents. (JAN. 


ArtTicLte XVII. 
NEW PATENTS. 


Sir W. Congreve, of Cecil-street, bart.:Strand, for various improve- 
ments in fire-works.—Oct. 16. 

A. Buchanan, of Cathrine Cotton Works, Glasgow, merchant, for 
his improvement in the construction of weaving looms impelled by 
machinery.—Oct. 16. 

J. Ranking, Esq. New Bond-street, Westminster, for his newly 
invented means of securing valuable property in mail and other stage 
coages, travelling carriages, waggons, caravans, and other similar 
public and private vehicles, from robbery.—Nov. 1. 

G. Hawkes, Lucas-place, Commercial-road, Stepney Old Town, 
Middlesex, ship-builder, for his improvement in the construction of 
ship anchors.—Nov. |. 

G. Hawlkes, Lucas-place, Commercial-road, Stepney Old Town, 
Middlesex, ship-builder, for certain improvements on capstans.— 
Nov. 1. 

W. Burdy, Fulham, mathematical-instrument maker, for his. anti- 
evaporating cooler to facilitate and regulate the refrigerating of worts, 
or wash, in all seasons of the year, from any degree of heat between 
boiling and the temperature required for fermenting.—Nov. 1. 

T FE, Gimson, Tiverton, Devonshire, Gent. for various improvements 
in addition to machinery now in use for doubling and twisting cotton, 
silk, and other fibrous substances.— Nov. 6. 

T. Gowan, Fleet-street; London, truss-manufacturer, for certain 
improvements on trusses.— Nov. 11. 

J. Day, Esq. of Barnstaple, Devonshire, for certain improvements in 
percussion gun-locks applicable to various descriptions of fire-arms.— 
Nov. 13. 

J. Ward, Grove-road, Mile-End-road, Middlesex, iron-founder, for 
certain improvements in the construction of Jocks and other fastenings. 
—Nov. 13. 

S. Servill, of Brower’s Hill, Bisley, Gloucestershire, clothier, for his 
new mode or improvement for dressing of woollen or other cloths,— 
Nov. 18. 2 

R. Green, Lisle-street, St. Anne, Middlesex, sadlers’ ironmonger, 
for certain improvements in constructing gambadoes or mud-boots, 
and attaching spurs thereto, and part of which said improvements are 
also applicable to other boots.—Novy. 13, 

R. Stein, Tower Brewery, Tower-hill, brewer, for his improved con- 
struction ofa blast-furnace, and certain apparatus tc b&b» cedmeut. | 
therewith, which is adapted to burn or consume fuel in a more econe- 
mical and useful manner than has been hitherto practised.—Noy. 13. 

J. Gillman, Newgate-street, silk warehouseman, and J. H. Wilson, 
Manchester, silk and cotton manufacturer, for certain improvements 
in the manufacture of hats and bonnets.—Nov. 18. 

J. Heathcoat, Tiverton, Devonshire, lace-manufacturer, for a ma- 
chine for the manufacture of a platted substance composed either of 
silk, cotton, or other thread or yarn.—Nov. 20, ’ 


1824.] Mr, Howard’s Meteorological Journal. 79) 


ArtTicLeE XVIII. 


METEOROLOGICAL TABLE. 


<a 
Banromerer,| THERMOMETER, Daniell’s hyg. 
1823, Wind. | Max.| Min. | Max. | Min. | Evap. |Rain.| at noon. 
11thMon. 
Noy. 1|N »W/30'22/20'86]: 45 27 — 
QIN W/30-23/30°16] 46 25 —_ 
3\IN W 30°16129°83 45 o2 — 
AIS W /29°83/29°74) 4G 44 —_ 21 
5 E |30°03/29'74) 50 4A, — 19 
6 E |30:05|30:03| 58 AS — 44, 
TIN W/30°27|30'05| 55 | 50 — a7 
SIN W/30°50/30°27| » 56 38 — 
ON E/30°61130°50| 46 32 — 
10 E |30°68/30-61} 46 29 _ 
11] - E */30°68/30°57} 42 23 — 
| ied E_ |30°57|30°54|. 40 | = 
13) S 30°54'30°44| 43 23 _ 
14S W/30°44/30'35| 44 _ 32 — 
15|N W/30°49'30°36; 50 36 — 
16} N_— |30°50'30°49} 51 383 "51 
17;}N W/130°52/30°50; 42 37 _ = 
18|N E/30'51/30°33| 48 42 a 
19} E~ |30°33/30°18] 46 40 = 
20'S W /30°28/30°17) 51 40 —_ 
211 W |zo2s'so12| 48 | 45 | — 
2918 1130°12'30:07| 47 39 — 
23/8 .W130°17|30°12| 48 43 — 
2418 W |30°31|30°12) 50 45 —_ 
25|S W/|30°34/30°31] 50 Al _ 
26|N © W/30°33/30°30) 48 44 — 
27/S W/\30-30/30715|} 48 45 a 
2818S W/30°15/29'85| 49 45 —_— oO 
29 S 29°85|29°60) 52 44 — bs; 
30IS W/29 79)29°59| 57 50 65 | i 
30°68/29'59| 58 | 21 36 | i 72 


The observations in each line of the table apply to a period of twenty-four hours, 
beginning at 9 A. M. on the day indicated in the first column. A dash denotes that 
the result is included in the next following observation. 


80. Mr. Howard’s Meteorological Journal.’ [Jan. 1824. 


REMARKS. 


Eleventh Month.—1. Cloudy. 2. Fine: white frost in the morning, 3. White 
frost: foggy. 4. Cloudy. 5. Rainy. 6. Fine. 7%. Rainy. 8. Cloudy. 9. Fine. 
10. Very fine. 11. Fine. 12. Fine: hoar frost. 13. Ditto, : 14, Hoar frost : 
foggy : overcast: 15, Overcast. 16. Very fine, 17. Overcast: a little rain in the 
morning. 18,19. Overcast. 20, Fine. 21—24. Overcast. 25. Foggy merning: 
overcast, 26,27. Overcast. 28. Cloudy. 29. Rainy. 30. Cloudy. 


RESULTS. 


Winds: NE, 2; E, 6; S,1; SW,12; W,1; NW, 8 


Barometer: Mean height 
For the. months ss scociadsscsaesctencocacssccseunes, SUIS ICES. 
For the lunar period, ending the 25th.......+.-++.-.- 30°183 
For 15 days, ending the 13th (moon south) .. ......-. 30°145 
For 12 days, ending the 25th (moon north) .....+... 30°308 


Thermometer: Mean height 
For the months st feuccaciese anced sasieccnyawevenss Sanlu 
Por'the lafiar periods <.. 17... eas'<'ccesesseaniey uivesna: Aen 
For 30 days, the sun in Scorpio .......eeceereeeeces 42483 


Hivaporatione ss bwce se ccscescdceve aia/afo ciowe A cide bhinitinie dunirie gn wren + ORE 


Rain. COE OEP H ee EH HEHE EH EE HE EE SHH eeaHer erst OEOOR este eees 1-%2 


Laboratory, Straljord, Twelfth Month, 22, 1823. R. HOWARD. 


‘j 


Se 
pt 


ur 
ee 


Fig. 3. 


Fig.6. 


lig. 3. 


Lig. 6. 


Tino. 


“ngraved for the dnruls oF Vhito sophy— for Baldwin, Cradock % Joy, Feb .21, 1824. 


¥ 


ANNALS 


PHILOSOPHY. 


FEBRUARY, 1824, 


ARTICLE I. 


Experiments on the Stability of Floating Bodies. 
By Col. Beaufoy, FRS. (With a Plate.) 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Bushey Heath, Jan. 1, 1824. 
__ In the year 1798 a disquisition on the stability of ships by 
that celebrated and eminent mathematician the late Mr. Atwood, 
was read before the Royal Society, and published in the Trans- 
actions. As this work 1s allowed to be superior to any other on 
the same subject in the English language, it may not be unac- 
ceptable to those concerned in the planning or building of ves- 
sels, to have this gentleman’s theoretical deductions submitted 
to the test of experiment ; for however satisfactory mathematical 
reasoning may be to the scientific, the generality of readers are 
more fully convinced by experimental proof. 
I remain, dear Sir, yours very truly, 
Mark BeAuroy 


—in—— 


The apparatus with which these experiments were made is 
similar to the one described and illustrated by a plate in the 
Annals of Philosophy for March, 1816, and to which I request 
your readers will refer. Improvements, however, were made on 
the present occasion, by fixing two pieces of wood in a diagonal 
direction, one on each side of the mast, to prevent its bending 
by the inclining weight: and for greater security, their lower 
extremities were firmly tied to the transverse piece that con- 

New Series, vow. vit. G 


82 Col. Beaufoy on the [Fes. 


nected the sides of the model, and through which the mast was 
inserted. A second alteration consisted in a more accurate 
adjustment of the centre of gravity at any given point of the 
figure when loaded. Raising the ballast (bars of lead) at first 
nearly produced this effect, which was afterwards determined 
with greater nicety by pouring shot into a cup fixed upon the 
top of the mast. This contrivance so well answered the intended 
purpose, that the results of several trials were found not to vary 
from each other more than five-hundreths of an inch, 

Different formed bodies were used, measuring in breadth ten 
inches, and in length fourteen inches, or within a few hundredths 
of an inch of fourteen. The immersion in water, with the 
exception of the three last, was four inches, or two-fifths of the 
width. The total depths were various, those bodies whose sides 
projected outwards requiring greater depth than those with sides 
inclining inwards; and for this reason, the edge of the former 
when inclined becomes sooner level with the surface of the 
water. 

Fig. 1 has the sides parallel to the plane of the mast both 
above and beneath the water line. 

Fig. 2 has the sides projecting 15 degrees outward above the 
water line, and parallel to the masts under. 

Fig. 3 has the sides inclining inwards 15 degrees above the 
water line, and parallel to the plane of the masts under. 

Fig. 4 has the sides projecting outwards, and at equal incli- 
nations (15 degrees both above and beneath the waterline). 

Fig. 5 has the sides inclining zmwards and at equal inclina- 
tions (15 degrees) to the plane of the masts above and below the 
water line. . 

Fig, 6 has the sides coincident with the surface of a cylinder, 
the vertical sections being equal circles. 

Fig. 7 has the vertical sections terminated by the arcs of a 
parabola. 

Figs. 8, 9, 10, refer to the experiments made on the poss 
vertical section (or midship bend) of an 18 gun brig, the Leopard 
of 50 guns, and the Howe of 120 guns. 

In fig. 1 (Plate XX VI), B A is the surface of the water when 
the vessels float upright. C H the water line when they incline 
30 degrees. E refers equally to the centres of gravity of the 
displaced fluid when the, figure floats horizontally, and to the 
models in the first set of experiments. Gis the centre of gravit 
of the model in the second set of experiments ; the distance EG 
being 1:3 inches, or =13, of the breadth B A; E R, and Gr, are 
the lever on which the water acts to re-establish the vessel in a 
vertical position, M is the meta centre, or point below which 
the vessel’s centre of gravity ought always to be situated to 
prevent its oversetting. 


The displaced water, as well as the weights applied to incline 


. 


1824.) Stability of Floating Bodies. 83 


the vessel, were calculated in ounces, drachms, and scruples, 
and afterwards reduced to the decimal parts of an ounce, three 
scruples in this case being equal to one drachm. 

Example 1.—Model 1.—Experiment 1.—The total depth of 
the model being 7-1 inches, the height of the centre of gravity 
is subtracted in each experiment, and the length of the mast 
(measuring from the centre of gravity of the model to the apex), 
20°96 inches being afterwards added, gives the length of lever 
at which the weights are applied to produce the various inclina- 
tions of 5° 10°, 15°, 20°, 25°, and 30°, Ther. The centre of 
gravity in Exper. 1 being situated two inches above the bottom 
of the model, and coinciding with the centre of gravity of the 
displaced fluid, the weight 2°2239 oz. being applied to the mast 
will incline it 5°. It is obvious that to restore the vessel to its 
original vertical position, the momentum of the water must be 
equal to that of the inclining power. If, therefore, the momen- 
tum of the effort to incline the vessel (that is to say, the weight 
applied, multiplied by the length of the mast) be divided by the 
weight of the displaced water, the quotient will be the length of 
lever E R on which the water acts. 

Experiment 1.—Model 1, inclined 5°.—The inclining weight 
is 22239 ounces, the length of lever 26-06 inches, and weight 
of the displaced water 324-52 ounces, then ki Mo ot cena oS a rl8 
or ER. By proceeding in a similar manner, the length of lever 
is obtained for 10°, 15°, 20°, 25°, and 30°. It should be men- 
tioned, that after the vessel had been inclined on one side, it 
was turned and inclined on the other, by which means if the 
mast was not perpendicular, or there was any inaccuracy in the 
form of the model or manner of placing the ballast, it was imme- 
diately perceived, and the error corrected in taking the mean of 
the two experiments. The difference, however, seldom amounted 
to two drachms, and in general was much less. 

The result of the second set of experiments proved the accu- 
racy of the first, the altitude of the point M being nearly the 
same in both cases, as may be seen on reference to the annexed 
tables. 

Column J] shows the angles of inclination. Columns 2 and 6; 
the weights that produced that inclination. Columns 3 and 7, 
the length of lever E R and Gr. Columns 4 and 8, the lever 
ER and Gr, calculated by Mr. Atwood’s theorem. Columns 
5 and 9, the height of the point, M above the point E, and 
found in the following manner :—As the sine of the inclination 
: ERorGr:: radius : EM orGM. When the centres of 
mi of figs. | and 7 coincide with the centres of gravity of 

e displaced fluid, their stability, allowing for the attendant 
inaccuracy of experiments, will be the same as shown by the 
subjoined calculations. 

G2 


84 Col. Beaufoy on the [Fes. 
5 O18 | 


x 32452 = 581026 x 21597 = 56 
10 0:36 x 32452 = 117]0°53 x 21597 = 115 
15 0°55 x 32452 = 17810°81 x 215°97 = 175 
20 0°75 x 32452 = 243] 1:11 x 21597 = 240 
25 097 x 32452 = 315/145 x 21597 = 313 
30 1:22 x 32452 = 396{ 1°83 x 21597 = 395 


Figs. 8, 9, 10, are the greatest vertical sections of three men 


The object in making these experiments was to determine 
how each the meta centres of these parts of the ships are 
elevated above the load water line. Each figure was submitted 
to two experiments, for determining the height of the meta 
centre above the centre of gravity of the displaced fluid. These 
two were then added together, and the draught of water sub- 
tracted. For instance, the 18 gun brig 3:22 inches, the mean 
height of the meta centre (see Table VIII and Exper. 1) above 
the point E, being added to 2-24 inches. The centre of gravity 
gives 5:46 inches, from which deduct 3:60 the draught of water, 
and the remainder 1°86 will be the quantity sought. The beam 
of a man of war of this size is 30 feet, and 134. of 30 is 5°58 
feet, which is the height of the brig’s meta centre above the 
water when inclined between 15° and 20°. (See Table VIII.) 
The mean height of the Leopard’s meta centre above the 
centre of gravity of the water is 2°58, to which add 2°38, and 
from the total subtract 4:13, the remainder -§3. is the distance 


100 
of the meta centre above the line of floatation, or -83, parts of 
the breadth. The beam or greater breadth of this 50 gun ship 
is 391 feet, ~68, of 394, is 2°49 feet, the meta centre’s height, 
which point may bé considered as stationary. 

The mean height of the meta centre of the Howe above the 
centre of gravity of the displaced water is 2°26 inches, to which 
add 2°43, and deduct 4:27 (the draught of water). The remainder 
#2, parts of an inch is the meta centre’s altitude above the 
water, or +4, of the width. The greatest breadth of the 120 gun 
ship is 54 feet 5 inches, or 54-417; =4, of 54-417 is 2-27 feet, 
the Howe’s meta centre above the load water line. The meta 
centre being stationary, proves that the midship bends of the 
Howard and Leopard are in great measure circular. 

The centre of gravity of the displaced water of the men of 
war was determined mechanically, and the columns in the tables 
headed Theor. are not filled up, it being impossible to give any 
general rule for finding the centre of gravity of bodies formed 
by different curves or mixed lines. 

Although the theory of stability is perfect, yet the calculations 
are attended with considerable trouble, especially in complex 
forms, such as the hulls of ships, which require the labour of 
months. Under these circumstances is not the mechanical 


1824.) Stability of Floating Bodies. 85 


method adopted in these experiments of finding the meta centre 
by first suspending the model on pivots, and then inclining it 
in water by weight, the preferable mode of proceeding? I have 
reason to believe that with proper attention, and provided the 
pivots turn on friction rollers, the centre of gravity could be 
ascertained within the hundredth part of an inch. 

A most essential point in ship building is the framing and 
putting together of the materials. This is now so well performed 
through the eminent skill and superior abilities of Sir Robert 
Seppings, as to render it doubtful whether this branch of naval 
mechanism admits of further extension. These observations, 
however, will not apply to another subject of naval science. 
Indeed it seems scarcely credible that in the first maritime 
nation in the world, one whose very existence depends upon its 
shipping, and upon the building of whose men of war millions 
and hundreds of millions have been expended from the time of 
Henry VIII. to the present day, no series of experiments on the 
resistance of fluids should have been undertaken by authority. . 
Should this unaccountable neglect be palliated by the trite 
remark, that that which is found to answer in smooth water is 
inapplicable to rough, it may be answered, that Emerson in his 
octavo book of Mechanics, p. 113, speaking of a watch keeping 
time at sea, declares that “ to suppose any regular motion can 
subsist among ten thousand irregular motions, and in ten thou- 
sand different directions, is a most glaring absurdity,” yet not- 
withstanding the prediction of this celebrated writer, chronome- 
ters are found to be of most essential use, and as such taken on 
board most ships of value. Vessels propelled by steam now 
cross from Falmouth to Spain and back, yet not many years 
have elapsed since this mode of navigation was declared utterly 
impracticable. 

he expence of making « complete set of experiments proba- 
bly would not exceed the value of the main mast of a single line 
of battle ship ; and a more conyenient and eligible situation for 
conducting such experiments cannot be found than the King’s 
Dock Yard at Woolwich. Such an undertaking is absolutely 
necessary for discovering the solid of the least resistance, and 
for the improvement of the bulls of vessels; and when the 
immense importance is considered of so easy and indispensable 
an elucidation of this interesting but ill understood branch of 
prysics, it is hoped that the naval administration of my Lord 
[elville, which has already done so much for the promotion of 
science, will not consider the resistance of fluids as unworthy of 
notice. Every member of the community must participate in a 
wish that his Lordship may be pleased to issue directions for 
rosecuting an inquiry, of which the success cannot be doubted, 
if the investigation be committed to the skill, science, and zeal, 
which at present distinguish the Navy Office. 


86 _ Col. Beaufoy on the (Fes. 


TABLE I. 
Model 1. 
Weight of water displaced 324-52 ounces, a 
Exp. I. Exp. 2. 
Lever 26°06 inches. Lever 24°76 inches. 
Centre of gravity 2 inches. Centre of gravity 3°3 inches. 


Deg. | Oz ER | Theor. | MC Oz. Gr. |Theor.| MC 


—e 


5 2°2239 | O18 0-15 2:05 0.8333 0-06 0:07 | 2:03 
10 44635 | 0:36 0°37 2-06 1-7569 0-13 O-14 | 2:07 
15 6°8437 | 0°55 0°56 2°12 2-7717 0-21 0/22 | 2°12 
20 9-2942 | 0-75 0-16 2:18 39583 0°30 0-31 | 2:18 
25 | 12-089 0:97 0:97 2°30 5:4202 OAL 0-42 | 2°28 
30 | 15°156 1°22 1°22 2:43 71-2464 0°55 0°56 | 2-Al 


——$—= | | | | 


1 2 3 4 5 6 1 8 ) 


Tasxe Il. 
manne ugha. eel Feectaglles i]. Pqulenee alta bepress pee) eee 
Model 2. 
Weight of water displaced 324°52 ounces. 
Exp. 1. Exp. 2. 
Lever 26°66 inches. Lever 25°36 inches. 
Centre of gravity 2 inches. Centre of gravity 3°3 inches. 
Deg. Oz. ER | Theor. | MC Oz. Gr. |Theor.| MC 


5 22135 | O18 0-18 2:09 0°S437 0:06 0:07 | 2:06 
10 4°5000 | 0:37 0-41 2:12 18437 0°18 O18 | 2:13 
15 70208 | 0:58 0°59 2°23 3°0156 0°23 0:25 | 2°21 
20 9°1187 0-80 0°82 2°33 4°5156 0°35 0°37 | 2°33 
25 | 12-932 1-06 1-08 2:51 64219 0°50 0°53 | 2:49 
30 | 16-661 1:37 1°38 2°74 9:0625 O71 0°73 | 2°72 


1 2 3 4 5 6 7 8 a 
Taste III. 
waeieeede A yh peels. edges ol Dole eee ee ee eee 
Model 3. 
Weight of water displaced 324-52 ounces. 
Exp. 1. Exp. 2. 
Lever 26:10 inches. Lever 24°80 inches, 
Centre of gravity 2 inches. Centre of gravity 3°3 inches. 
Deg. Oz. | ER | Theor. MC Oz. Gr. |Theor.| MC 


5 2°1929 | O18 0°18 2°02 0*8177 | 0-06 0:06 | 2:02 
10 4:3073 | 0°35 0°35 1:99 15677 | 0-12 O13 | 1:99 
15 6°4062 | 0-52 0°53 1:99 2°3335 | 0:18 0:20 | 1:99 
20 85312 | 0°67 O71 2°01 31667 | 0:24 0°26 | 2°01 
25 | 10-797 0-87 0-89 2°05 41198 | 0-31 0°34 | 2:04 
30. | 13-203 1-06 1:08 2°12 52604 | 0-40 0°43 | 2:10 


-_—_—oooo- 


1 2 3 4 ay 6 7 8 9 


1824.] Stability of Floating Bodies. 87 


Tasie IV. 
Model 4, 
Weight of water displaced 359'14 ounces. 
Exp. |. Exp. 2. 
. Lever 26°71 inches, Lever 25°41 inches. 


Centre of gravity 1-93 inch. Centre of gravity 3°23 inches. 


Deg. | Oz. ER | Theor. | MC Oz. Gr. |Theor,| MC 
5 2°1937 | 0-16 0-17 3°80 0:6094 | 0°04 0°06 | 3-73 
10 4°5625 | 0:34 0°35 3°88 15260 | O-ll O12 | 3°55 
15 7°3229 | 0:54 0-56 4:03 2°8177 | 0-20 0:23 | 4:00 
20 | 10-458 0-78 OTT 4°20 4°5469 | 0°32 0°33 | 4:17 
25 | 14-427 1-07 1-09 4-AT T0104 | 0:50 0:54 | 4°40 
30 | 19-260 1°43 1-43 4719 | 10-417 0-74 0:78 | 4°70 


ei) 3 a | 5 6 1 et iy 
TaBLe V. 
Model 5. 
Weight of water displaced 289-96 ounces, 
Exp. 1. Exp. 2. 
Lever 26°03 inches. Lever 24-73 inches. 
Centre of gravity 2-06 inches. Centre of gravity 3°36 inches. 
Deg. | Oz. ER | Theor. | MC Oz. Gr. |Theor.| M C 


| — 
5 2°1302 | 0-19 0-20 | 219 0°9375 0-08 0°08 | 2°22 
10 41823 | 0:37 0:37 2°16 1-7448 0-15 Old | 2°16 
15 6:0937 | 0°55 0°57 2-11 2°4896 0-21 0°23 | 2°12 
20 80104 | 0-72 0-74 2°10 3°2083 0°27 0-29 | 2:10 
25 9:9583 | 0-89 0-91 211 3-9896 0°34 0°36 | 2:10 
30 | 11-875 1-07 1-09 2:13 4-7812 O-41 0-44 {| 2°12 


Ss ee 4 5 6 7 8 | 9 
TasBLe VI, 
Model 6. 
Weight of water displaced 240°74 ounces. 
Exp. 1. Exp. 2. 
Lever 25-73 inches. Lever 24°33 inches. 

Centre of gravity 2°33 inches, Centre of gravity 3°63 inches, 
—————_——__ — — —— Leeann 
Deg. Oz | ER | Theor. MC Oz. Gr, |Theor.| MC 


5 QiT19 | 0-23 0°24 2-66 1°1667 0-12 Ol | 2°65 
10 4'3177 | 0°46 0:48 2°66 2°3229 0:23 0-26 | 2°65 
15 64271 | 0°69 0-72 2°65 34114 0-34 O-3T | 2°66 
20 8-4687 | 0:90 0°96 2°65 44896 0-45 O51 | 2-63 
25 | 10-547 1°12 1-18 2°66 5°5208 0°56 0°63 | 2-62 
30 | 12°583 134 1-40 2°69 6:5A1LT 0-66 O15 | 2°62 
FS 


1 2 3 4 5 6 1 8 9. 
FSS 


—_—— | —__——. 


88 .. Col, Beaufoy on the [Fes, 
TasiE VII. 


Model 7, 
Weight of water displaced 215°97 ounces. 
Exp. 1. Exp, 2. 
Lever 27:08 inches. Lever 25°78 inches. 
Centre of gravity 2°4 inches. Centre of gravity 3°7 inches. 
Deg, Oz, ER Theor. MC Oz, Gr. |Theor.|} MC 


| | | SO | | 


1 2 3 4 5 6 7 8 9 
Tape VIII. 
18 Gun Brig. 
Weight of water displaced 186:96 ouaces. 
Exp. 1. | Exp. 2. 
Lever 25°35 inches. Lever 24:05 inches. 

Centre of gravity 2°24 inches. Centre of gravity 3:54 inches. 
Deg. Oz. ER “1 Theor. MC Oz. Gr. |Theor.| M C 
5 2:1146 |} 0:29 a 3°29 1°3626 0:19 3°31 
10 41979 | O57 3°28 2°6667 0°34 3°27 
15 61823 | 0°84 3°24 3°9271 0°50 3:25 
20 8:0521 1:09 3:19 5°0417 0°65 3°20 
25 9°8958 | 1:34 3°17 6-0989 0-78 317 
30 | 11°635 1°58 3°15 71146 0:91 3°13 
ie oe 3 Mean | 3:22 6 vi Mean | 3:22 

ay gail lai 8 9 

Tage IX. 
Leopard of 50 guns. 
Weight of water displaced 271-71 ounces, 
Exp. |. Exp. 2. 
Lever 26°15 inches. Lever 24°85 inches, 

Centre of gravity 2-38 inches. Centre of gravity 3°68 inches. 
Deg. Oz. ER Theor, MC Oz. Gr. Theor. | MC 
5 | 21562} 0-21 238 | 10260 | 0-09 | 2:38 
10 4:2500 | O41 2°36 2:0000 0-18 2°35 
15 6:3750 | 0-61 2°37 3:0417 0°28 2:37 
20 84583 O'8k 2°38 4:0573 0:37 2°38 
25 | 10°536 1:01 2°40 5:0573 0-46 2:39 
30 | 12°510 1:20 2-41 5°9375 0-54 2°39 

tas | 2 3 Mean 2°38 6 7 Mean |°2:38 ~ 
4 5 8 9 


Fa a ee a a Re a A NR 2 BR A RSE SAC SR 


7824.) Stability of Floating Bodies. 89 


TABLE X. 
Howe of 120 guns. 
Weight of water displaced 285°97 ounces, 
Exp. 1. Exp. 2. 
Lever 26°13 inches. Lever 24°83 Inchos. 

Centre of gravity 2:43 inches. Centre of gravity 3°73 inches. 
Oz, ER Theor. MC Oz. Gr. |Theor.| MC 
2°1458 | 0.90 2°25 0:9635 0-08 2°26 
42760 | 0:39 2°25 1:9062 0:16 2°25 
6°3802 0:58 2°25 2-8281 0-24 2°25 
8°4062 | 0-77 2°24 3°7552 0°33 2°25 
10°495 0:96 2°27 46458 0:40 2°25 
12-500 115 2°29 5°5669 0:48 2:27 
2 3 Mean | 2-26 6 T Mean | 2°26 

4 | 5 8 9 


ArtTic.e II, 


On the Liquefaction of Chlorine and other Gases. By M. Fara- 
day, Chemical Assistant in the Royal Institution.* 


I roox advantage of the late cold weather (Feb. and March, 
1823), to procure crystals of hydrate of chlorine for the purpose 
of analysis. The results are contained in a short paper in the 
Quarterly Journal of Science, vol. xv. Its composition is very 
nearly 27°7 chlorine, 72-3 water, or 1 proportional of chlorine, 
and 10 of water. 

The President of the Royal Society having honoured me by 
looking at these conclusions, suggested, that an exposure of the 
substance to heat under pressure, would probably lead to inte- 
resting results : the following experiments were commenced at 
his request. Some hydrate of chlorine was prepared, and being 
dried as well as could be by pressure in bibulous paper, was 
introduced into a sealed glass tube, the upper end of which was 
then hermetically closed. Being placed in water at 60°, it 
underwent no change; but when put into water at 100°, the 
substance fused, the tube became filled with a bright yellow 
atmosphere, and, on examination, was found to contain two fluid 
substances: the one, about three-fourths of the whole, was of a 


* Abstracted from two papers in the Phil. Trans, for 1823, Part II. 


90 Mr. Faraday on the {Fes. 


faint yellow colour, having very much the appearance of water ; 
the remaining fourth was a heavy bright yellow fluid, lying at 
the bottom of the former, without any apparent tendency to mix 
with it. As the tube cooled, the yellow atmosphere condensed 
into more of the yellow fluid, which floated in a film on the pale 
fluid, looking very like chloride of nitrogen; and at 70° the pale 
portion congealed, although even at 32° the yellow portion did 
not solidify. Heated up to 100° the yellow fluid appeared to 
boil, and again produced the bright coloured atmosphere. 

By putting the hydrate into a bent tube, afterwards hermeti- 
cally sealed, I found it easy, after decomposing it by a heat of 
100°, to distil the yellow fluid to one end of the tube, and so 
separate it from the remaining portion. In this way a more 
complete decomposition of the hydrate was effected, and when 
the whole was allowed to cool, neither of the fluids solidified at 
temperatures above 34°, and the yellow portion not even at 0°. 
When the two were mixed together, they gradually combined at 
temperatures below 60°, and formed the same solid substances 
as that first introduced. If, when the fluids were separated, the 
tube was cut in the middle, the parts flew asunder as if with an 
explosion, the whole of the yellow portion disappeared, and 
there was a powerful atmosphere of chlorine produced ; the pale 
portion on the contrary remained, and when examined, proved 
to be a weak solution of chlorine in water, with a little muriatic 
acid, probably from the impurity of the hydrate used. When 
that end of the tube in which the yellow fluid lay was broken 
under a jar of water, there was an immediate production of 
chlorine gas. 

I at first thought that muriatic acid and euchlorine had been 
formed; then, that two new hydrates of chlorine had been pro- 
duced; but at last I suspected that the chlorine had been 
entirely separated from the water by the heat, and condensed 
into a dry fluid by the mere pressure of its own abundant vapour. 
If that were true, it followed, that chlorine gas, when com- 
pressed, should be condensed into the same fluid, and, as the 
atmosphere in the tube in which the fluid lay was not very yel- 
low at 50° or 60°, it seemed probable that the pressure required 
was not beyond what could readily be obtained by a one 
syringe. A long tube was therefore furnished with a cap an 
stop-cock, then exhausted of air and filled with chlorine, and 
being held vertically with the syringe upwards, air was forced 
in, which thrust the chlorine to the bottom of the tube, and gave 
a pressure of about four atmospheres. Being now cooled, there 
was an immediate deposit in films, which appeared to be hydrate, 
formed by water contained in the gas and vessels, but some of 
the yellow fluid was also produced. As this however might 
also contain a portion of the water present, a perfectly dry tube 
and apparatus were taken, and the chlorine left for some time 


1824.] Liquefaction of Chiorine and other Gases. 91 


over a bath of sulphuric acid before it was introduced. Upon 
throwing in air and giving pressure, there was now no solid film 
formed, but the clear yellow fluid was deposited, aud more 
abundantly still upon cooling. After remaining some time it 
disappeared, having gradually mixed with the atmosphere above 
it, but every repetition of the experiment produced the same 
results. 

Presuming that I had now a right to consider the yellow fluid 
as pure chlorine in the liquid state, I proceeded to examine its 
properties, as well as I could when obtained by heat from the 
hydrate. However obtained, it always appears very limpid and 
fluid, and excessively volatile at common pressure. A portion 
was cooled in its tube to 0°: it remained fluid. The tube was 
then opened, when a part immediately flew off, leaving the rest 
so cooled by the evaporation as to remain a fluid under the atmo- 
spheric pressure. ‘The temperature could not have been higher 
than — 40° in this case ; as Sir Humphry Davy has shown that 
dry chlorine does not condense at that temperature under com- 
mon pressure. Another tube was opened at a temperature of 
50°; a part of the chlorine volatilised, and cooled the tube so 
much as to condense the atmospheric vapour on it as ice. 

_ A tube having the water at one end and the chlorine at the 
other was weighed, and then cut in two; the chlorine imme- 
diately flew off and the loss being ascertained was found to be 
1:6 grain: the water left was examined and found to contaiti 
some chlorine: its weight was ascertained to be 5:4 grains. 
These proportions, however, must not be considered as indica- 
tive of the true composition of hydrate of chlorine; for, from 
the mildness of the weather during the time when these experi- 
ments were made, it was impossible to collect the crystals of 
hydrate, press, and transfer them, without losing much chlorine ; 
and it is also impossible to separate the chlorine and water in 
the tube perfectly, or keep them separate, as the atmosphere 
within will combine with the water, and gradually reform the 
hydrate. 

iieias cutting the tube, another tube had been prepared 
exactly like it in form and size, and a portion of water introduced 
into it, as near as the eye could judge, of the same bulk as the 
fluid chlorine : this water was found to weigh 1:2 grain ; a result, 
which, if it may be trusted, would give the specific gravity of 
fluid chlorine as 1°33 ; and from its appearance in, and on water, 
this cannot be far wrong. 

The refractive power of fluid chlorine is rather less than that 
of water. The pressure of its vapour at 60° is nearly equal to 
four atmospheres. 


92 Mr. Faraday on the {Fes. 


{Note on the Condensation of Muriatic Acid Gas into the liquid 
' Form. By Sir H. Davy, Bart. Pres. RS. . 


In desiring Mr. Faraday to expose the hydrate of chlorine to 
heat in a closed glass tube, it occurred to me, that one of three 
things would happen ; that it would become fluid as a hydrate ; 
or that a decomposition of water would occur, and euchlorine and 
muriatic acid be formed ; or that the chlorine would separate in 
a condensed state. This last result having been obtained, it 
evidently led to other researches of the same kind. I shall hope, 
on a future occasion, to detail some general views on the subject 
of these researches. I shall now merely mention, that by seal- 
ing muriate of ammonia and sulphuric acid in a strong glass tube, 
and causing them to act upon each other, I have procured liquid 
muriatic acid: and by substituting carbonate for muriate of 
ammonia, I have no doubt that carbonic acid may be obtained, 
though in the only trial I have made. the tube burst. I have 
requested Mr. Faraday to pursue these experiments, and to 
extend them to all the gases which are of considerable density, 
or to any extent soluble in water ; and I hope soon to be able to 
lay an account of his results, with some applications of them that 
I propose to make, before the Society. 

I cannot conclude this note without observing, that the gene- 
ration of elastic substances in close vessels, either with or with- 
out heat, offers much more powerful means of approximating 
their molecules than those dependent upon the application of 
cold, whether natural or artificial: for, as gases diminish only 
about 1-480 in volume for every — degree of Fahrenheit’s scale, 
beginning at ordinary temperatures, a very slight condensation 
only can be produced by the most powerful freezing mixtures, 
not half as much as would result from the application ofa strong 
flame to one part of a glass tube, the other part being of ordi- 
nary temperature: and when attempts are made to condense 
gases into fluids by sudden mechanical compression, the heat, 
instantly generated, presents a formidable obstacle to the success 
of the experiment ; whereas, in the compression resulting from 
their slow generation in close vessels, if the process be conducted 
with common precautions, there is no source of difficulty or dan- 
ger; and it may be easily assisted by artificial cold in cases 
when gases approach near to that point of compression and tem- 
perature at which they become vapours.] 


__ The refractive power of liquid muriatic acid is greater than 
that of nitrous oxide, but less than that of water; it is nearly 
equal to that of carbonic acid. The pressure of its vapour at the 
temperature of 50° is equal to about 40 atmospheres. 


1824.} — Liquefaction of Chlorine and other Gases. 93 


Sulphurous Acid. 


Mercury and concentrated sulphuric acid were sealed up in a 
bent tube, and, being brought to one end, heat was carefully 
applied, while the other end was preserved cool by wet bibulous 
paper. Sulphurous acid gas was produced where the heat acted, 
and was condensed by the sulphuric acid above; but, when the 
latter had become saturated, the sulphurous acid passed to the 
cold end of the tube, and was condensed into a liquid. When 
the whole tube was cold, if the sulphurous acid were returned 
on to the mixture of sulphuric acid and sulphate of mercury, a 
portion was re-absorbed, but the rest remained on it without 
mixing. 

Liquid sulphurous acid is very limpid and colourless, and 
highly fluid. Its refractive power, obtained by comparing it in 
water and other media, with water contained in a similar tube, 
appeared to be nearly equal to that of water. It does not soli- 
dify or become adhesive at a temperature of 0° F. Whena tube 
containing it was opened, the contents did not rush out as with 
explosion, but a portion of the liquid evaporated rapidly, cooling 
another portion so much as to leave it in the fluid state at com- 
mon barometric pressure. It was however rapidly dissipated, 
not producing visible fumes, but producing the odour of pure 
sulphurous acid, and leaving the tube quite dry. A portion of 
the vapour of the fluid received over a mercurial bath, and exa- 
mined, proved to be sulphurous acid gas. A piece of ice drop- 
ped into the fluid instantly made it boil, from the heat communi- 
cated by it. 

To prove in an unexceptionable manner that the fluid was pure 
sulphurous acid, some sulphurous acid gas was carefully pre- 
pared over mercury, and a long tube perfectly dry, and closed at 
one end, being exhausted, was filled with it; more sulphurous 
acid was then thrown in by a condensing syringe, till there were 
three or four atmospheres ; the tube remained perfectly clear and 
dry, but on cooling one end to 0°, the fluid sulphurous acid con- 
densed, and in all its characters was like that prepared by the 
former process. 

A small gage was attached to a tube in which sulphurous acid 
was afterwards formed, and at a temperature of 45° F. the pres- 
sure within the tube was equal to three atmospheres, there being 
a portion of liquid sulphurous acid present : but as the common 
air had not been excluded when the tube was sealed, nearly one 
atmosphere must be due to its presence, so that sulphurous acid 
vapour exerts a pressure of about two atmospheres at 45° F. Its 
specific gravity was nearly 1-42.* 


* T am indebted to Mr. Davies Gilbert, who examined with much attention the 
results of these experiments, for the suggestion of the means adopted to obtain the spe- 
cific gravity of some of these fluids. A number of small glass bulbs were blown and 
hermetically sealed ; they were then thrown intoalcohol, water, sulphuric acid, or mix~ 


94 Mr. Faraday on the . [Fes 


Sulphuretted Hydrogen. 


A tube being bent, and sealed at the shorter end, strong 
muriatic acid was poured in through a small funnel, so as nearly 
to fill the short leg without soiling the long one. A piece of 
platinum foil was then crumpled up and pushed in, and upon 
that were put fragments of sulphuret of iron, until the tube was 
nearly full. In this way action was prevented until the tube 
was sealed, If it once commences, it is almost impossible to 
close the tube in a manner sufficiently strong, because of the 
pressing out of the gas. When closed, the muriatic acid was 
made to run on to the sulphuret of iron, and then left for a day 
or two. At the end ofthat time, much protomuriate of iron had 
formed, and on placing the clean end of the tube in a mixture of 
ice and salt, warming the other end if necessary by a little water, 
sulphuretted hydrogen in the liquid state distilled over. 

The liquid sulphuretted hydrogen was colourless, limpid, and 
excessively fluid. Ether, when compared with it in similar 
tubes, appeared tenacious and oily. It did not mix with the 
rest of the fluid in the tube, which was no doubt saturated, but 
remained standing on it. When a tube containing it was opened, 
the liquid immediately rushed into vapour ; and this being done 
under water, and the vapour collected and examined, it proved 
to be sulphuretted hydrogen gas. As the temperature of a tube 
containing some of it rose from 0° to 45°, part of the fluid rose 
in vapour, and its bulk diminished; but there was no_ other 
change: it did not seem more adhesive at 0° than at 45°. Its 
refractive power appeared to be rather greater than that of 
water ; it decidedly surpassed that of sulphurous acid. A small 
gage being introduced into a tube in which liquid sulphuretted 
hydrogen was afterwards produced, it was found that the pres- 
sure of its vapour was nearly equal to 17 atmospheres at the 
temperature of 50°, 

The gages used were made by drawing out some tubes at the 
blowpipe table until they were capillary, and of a trumpet form ; 
they were graduated by bringing a small portion of mercury 
successively into their different parts; they were then sealed at 
the fine end, and a portion of mercury placed in the broad end ; 
and in this state they were placed in the tubes, so that none of 
the substances used, or produced, could get to the mercury, or 


tures of these, and when any one was found of the same specific gravity as the fluid in. 
which it was immersed, the specific gravity of the fluid was taken: thus a number of 
hydrometrical bulbs were obtained ; these were introduced into the tubes in which the 

substances were to be liberated ; and ultimately, the dry liquids obtained, in contact 
with them. It was then observed whether they floated or not, and a second set of expe-. 
riments were made with bulbs lighter or heavier as required, until a near approximation 

was obtained. Many of the tubes burst in the experiments, and in others difficulties 

occurred from the accidental fouling of the bulb by the contents of the tube. One source 

of error may be mentioned in addition. to those which are obvious, namely, the alteration’ 
of the bulk of the bulb by its submission to the pressure required to keep the substance 

in the fluid state. 


1824.) Liquefaction of Chlorine and other Gases. 85 


pass by it to the inside of the gage. In estimating the number 
of atmospheres, one has always been subtracted for the air left 
in the tube. 

The specific gravity of sulphuretted hydrogen appeared to 


be 0°9 
Carbonic Acid. 


The materials used in the production of carbonic acid, were 
carbonate of ammonia and concentrated sulphuric acid; the 
manipulation was like that described for sulphuretted hydrogen, 
Much stronger tubes are however required for carbonic acid than 
for any of the former substances, and there is none which has 
produced so many or more powerful explosions, Tubes which 
have held fluid carbonic acid well for two or three weeks toge- 
ther, have, upon some increase in the warmth of the weather, 
spontaneously exploded with great violence; and the precau- 
tions of glass masks, goggles, &c, which are at all times neces- 
sary in pursuing these experiments, are particularly so with car- 
bonie acid. 

Carbonic acid is a limpid colourless body, extremely fluid, 
and floating upon the other contents of the tube. Jt distils 
readily and rapidly at the difference of temperature between 32° 
and 0°. Its refractive power is much less than that of water. 
No diminution of temperature to which I have been able to sub- 
mit it, has altered its appearance. In endeavouring to open the 
tubes at one end, they have uniformly burst into fragments, with 
powerful explosions. By inclosing a gage in a tube in which 
fluid carbonic acid was afterwards produced, it was found that 
its vapour exerted a pressure of 36 atmospheres at a temperature 
of 32°. 

Euchlorine. 


Fluid euchlorine was obtained by inclosing chlorate of potash 
and sulphuric acid in a tube, and leaving them to act on each 
other for 24 hours. In that time there had been much action, 
the mixture was of a dark reddish brown, and the atmosphere of 
a bright yellow colour. The mixture was then heated up to 
100°, and the unoccupied end of the tube cooled to 0°; by degrees 
the mixture lost its dark colour, and a very fluid ethereal looking 
substance condensed. It was not miscible with a small portion 
of the sulphuric acid which lay beneath it ; but when returned 
on to the mass of salt and acid, it was gradually absorbed, 
rendering the mixture of a much deeper colour even than itself, 

Euchlorine thus obtained is a very fluid transparent sub- 
stance, of a deep yellow colour. A tube containing a portion of 
it in the clean — was opened at the opposite ensaraty ; there 
was a rush of euchlorine vapour, but the salt plugge up the 
aperture ; while clearing this away, the whole tube burst with a 
violent explosion, except the small end in a cloth in my hand, 


96 Mr. Faraday on the = [Fes. 
where the euchlorine previously lay, but the fluid had all disap- 


peared. ' 
Nitrous Oxide. 


Some nitrate of ammonia, previously made as dry as could be 
by partial decomposition, by heat in the air, was sealed up in a 
bent tube, and then heated in one end, the other being preserved 
cool. By repeating the distillation once or twice in this way, it 
was found, on after-examination, that very little of the salt 
remained undecomposed. The process requires care. I have 
had many explosions occur with very strong tubes, and at consi- 
derable risk. 

When the tube is cooled, it is found to contain two fluids, and 
a very compressed atmosphere. The heavier fluid on examina- 
tion proved to be water, with a little acid and nitrous oxide in 
solution; the other was nitrous oxide. It appears in a very 
liquid, limpid, colourless state ; and so volatile that the warmth 
of the hand generally makes it disappear in vapour. The appli- 
cation of ice and salt condenses abundance of it into the liquid 
state again. It boils readily by the ditference of temperature 
between 50° and 0°. It does not appear to have any tendency 
to solidify at — 10°. Its refractive power is very much less 
than that of water, and less than any fluid that has yet been 
obtained in these experiments, or than any known fluid. A 
tube being opened in the air, the nitrous oxide immediately burst 
into vapour. Another tube opened under water, and the vapour 
collected and examined, it proved to be nitrous oxide gas. A 
gage being introduced into a tube, in which liquid nitrous oxide 
was afterwards produced, gave the pressure of its vapour as equal 
to above 50 atmospheres at 45°. 

Cyanogen. 

Some pure ‘cyanuret of mercury was heated until perfectly 
dry. A portion was then inclosed in a green glass tube, in the 
same manner as in former instances, and being collected to one 
end, was decomposed by heat, while the other end was cooled. 
The cyanogen soon appeared as a liquid: it was limpid, colour- 
less, and very fluid ; not altering its state at the temperature of 
0°. Its refractive power is rather less, perhaps, than that of 
water. A tube containing it being opened in the air, the expan- 
sion within did not appear to be very great; and the liquid 
passed with comparative slowness into the state of vapour, pro- 
ducing great cold. The vapour, being collected over mercury, 
proved to be pure cyanogen. 

A tube was sealed up with cyanuret of mercury at one end, 
and a drop of water at the other; the fluid cyanogen was then 
produced in contact with the water. It did not mix, at least in 
any considerable quantity, with that fluid, but floated on it, 
being lighter, though apparently not so much so as ether would 


a 7 


1824.} Liquefaction of Chlorine and other Gases. 97 


be. In the course of some days, action had taken place, the 
water had become black, and changes, probably such as are 
known to take place in an aqueous solution of cyanogen, 
occurred. ‘The pressure of the vapour of cyanogen appeared by 
the gage to be 3:6 or 3°7 atmospheres at 45°. Its specific 
gravity was nearly 09. aX 
st Ammonia. 

‘In searching after liquid ammonia, it became. necessary, 
though difficult, to find some dry source of that substance; and 
I at last resorted to a compound. of it, which I had occasion to 
notice some years since with chloride of silver.* When dry 
chloride of silver is put into ammoniacal gas, as dry as it can be 
made, it absorbs a large quantity of it: 100 grains condensing 
above 130 cubical inches of the gas; but the compound thus 
formed is decomposed by a temperature of 100° F. or upwards. 
A portion of this compound was sealed up in a bent tube and 
heated in one leg, while the other was cooled by ice or water. 
The compound thus heated under pressure fused at a compara- 
tively low temperature, and boiled up, giving off ammoniacal gas, 
which condensed at the opposite end into a liquid. 

Liquid ammonia thus obtained was colourless, transparent, 
and very fluid. Its refractive power surpassed that of any other 
of the fluids described, and that also of water itself. From the 
way in which it was obtained, it was evidently as free from water 
as ammonia in any state could be. When the chloride of silver 
is allowed to cool, the ammonia immediately returns to it, com- 
bining with it, and producing the original compound, , During 
this action a curious combination of effects takes place: as the 

“chloride absorbs the ammonia, heat is produced, the tempera- 
ture rising up nearly to 100°; while a few inches off, at the 
opposite end of the tube, considerable cold is produced by the 
evaporation of the fluid. When the whole is retained at the 
' temperature of 60°, the ammonia boils: till it is dissipated and 
re-combined. The pressure of the vapour of ammonia is equal 
to about 6-5 atmospheres at 50°. » Its specific gravity was 0°76. 

Attempts have been made to obtain hydrogen, oxygen, 
fluoboracic, fluosilicic, and phosphuretted: hydrogen gases 
in the liquid state; but though all of them have been sub- 
jected to great pressure, they have as yet resisted conden- 
sation. 


ArticLe IT]. 
New Locality of the Skorodite. By W. Phillips, FLS. MGS. &e. 


Tue crystals forming the subject of this notice were lately 
received in a letter addressed to me from ‘ Calenick, near 
Truro,” and signed “ J. Michell,” as having been “ obtained 


: * Quarterly Journal of Seience, yol. vy, p. 74. 
New Series, you, vil. H 


98 Mr. W. Phillips on Skorodite. - [Fes, 


from a mine in the neighbourhood of St. Austell,” in Cornwall. 
By the gentleman who transmitted them, they are imagined to 
be a variety of the arseniate of iron; but he laments that their 
scarcity had prevented his ascertaining their composition, and 
requests the insertion of a notice respecting them in the Annals 
of Philosophy. 

The largest of these crystals does not exceed in size the head 
of an ordinary pin, but many of them are so complete as to leave 
it a matter of doubt whether they ever were attached to a 
matrix ; a few, however, are deposited on some small fragments 
of quartz. In form they very closely resemble that of the skoro- 
dite, given in the third edition of my Elementary Introduction 
to Mineralogy ; the planes dg and dz’, are, however, wanting in 
the second of the following figures, which represents the form of 
the crystals lately received from Cornwall; while almost every 
one of them exhibits the planes c ¢, which are not observable in 
the crystals of the skorodite, or in those of the martial arseniate 
of copper. 

Externally these crystals are of the dark 
bottle-green colour, very common to some of P 
the prismatic varieties of the arseniate of cop- 

er; but this is not in fact the true colour of the 
substance itself, which, on holding the crystals, 
or thin fragments of them between the eye and 
the light, is found by the assistance ofa glass 
to be of the pale blue, so common to the mar- 
tial arseniate of copper. The dark-green 
colour arises from the mechanical intermixture 
of a multitude of very minute specks, of that 
colour, visible on the surface, and also by 
transmitted light. 


INT ayn NB ys is et ais as chal is rege) oe spe 
UG fe yaa: obeha's witaalinat dle ae 
EOP AD. clscmavyrsryinipna He 1A Weir ale 
GAO AU caianis, amin wie « OLDE BO 
INR ALL in. 5 cg ee baleen iste 112 36 
CATR Rn. ‘wc gy otal oka ua eure 

The first figure represents a right rhombic prism, the primary form of the martial 
arseniate of copper, the skorodite, and also of the crystals which form the subject of this 
notice: the planes dl, dl, of the latter, generally present several reflections less than one 
degree apart, indicating each to be aseries of planes. 

The foregoing measurements by the reflective goniometer, as 
well as the form of these crystals, tend to show that they are only 
a variety of the martial arseniate of copper, which commonly is 

rismatic, the planes of the prism being the primary planes 
M M’, sometimes associated with the planes f and /, and the 

rism is commonly terminated by one quadrangular pyramid 
formed by the planes dd’; but in these crystals, and also in the 
skorodite, the planes M M’ are reduced to small triangles, 
owing to the presence of both pyramids. 


The martial arseniate of copper, and its variety the skorodite, 


1824.} Mr. R. Phillips’s Chemical Examination of Skorodite. 99 


yield to mechanical division parallel to the planes M M’, and 
also to the plane / of the preceding figure ; the latter being 
parallel to the lesser diagonal of the prism ; a fragment found 
among the crystals received from Cornwall, exhibits the latter 
cleavage with a tolerably brilliant surface ; the former I have not 
succeeded in obtaining, owing, perhaps, to the minuteness of the 
crystals rendering it difficult to operate upon them, and to the 
intermixture of the green particles. 

On subjecting these crystals to the action of the blowpipe, 
copious arsenical fumes are given off, without altering the exter- 
nal form, which, however, is rendered of an ochreous colour. 


Chemical Examination of the Skorodite. By R. Phillips, FRS. 


A few crystals of the skorodite were dissolved in nitric acid, 
the solution was decomposed by potash, and after having satu- 
rated the alkali with acetic acid, nitrate of silver was added, 
which immediately gave the well-known red precipitate indicat- 
ing the presence of arsenic acid. 

The precipitate separated by potash from solution in nitric 
acid appeared to consist of peroxide of iron; but in order to 
ascertain whether it contained oxide of copper, it was put into 
ammonia ; this however exhibited, no appearance of having dis- 
solved any of the oxide im question. I subsequently dissolved 
some of the skorodite in nitric acid, and tried whether polished 
iron would detect the presence of copper, but the attempt was 
equally unsuccessful as the first. In order to be perfectly satis- 
fied that the substance contained no copper, I requested Mr. 
Children to submit it to examination ; the results of his experi- 
ments confirmed those which | had obtained, and proved that 
no copper was present. 

Through the kindness of Mr. Heuland, I was enabled to sub- 
mit some crystals of foreign skorodite to examination, and these, 
as well as some with which my brother supplied me, were totally 
destitute of copper, and appeared to consist entirely of arsenic 
acid and oxide of iron. 

On account of the similarity of crystalline form and measure- 
ments in the skorodite and the martial arseniate of copper, analyzed 
by M. Chenevix, | was desirous of subjecting the latter toa fresh 
examination ; in so doing I had very satisfactory evidence that 
it contained a considerable portion of oxide of copper. The 
analysis of M. Chenevix gives: 


Arsenic acid .........0000. Bf Ogk Lah i Ls Bae,’ 
Omaevat ix0idiedsis Su hileaih Ua W7°5 
Oxide of copper), ely aeheme’ oF a WeGle 92-5 
Wieker iit sigs til. Veith ie Saw nd BR 12-0 
Silicd 4k ue. WA vee ya ee abh eral 30 

98:5 


100 Mr. Smithson on (Fes. 


Supposing that the iron and copper exist in the mineral in the 
state of peroxide, and that the weights of their atoms are to each 
other respectively as 40 to 80, it will be impossible to reduce the 
martial arseniate of copper to a probable definite compound ; for 
it will appear by calculation that the nearest approximation is 
5 atoms of oxide of iron and 2 atoms of oxide of copper} it 
seems, therefore, more likely that the skorodite is a peculiar 
arseniate of iron, differing not only in form, but in composition, 
from the cubic arseniate of iron; and it will follow, if this be 
admitted, that the martial arseniate of copper is a mixture and 
not a compound of arseniate of iron and arseniate of copper: 
this supposition will, perhaps, be considered the more probable 
when it is remembered that the cubic arseniate of iron contains 
9 per cent. of oxide of copper. It is also to be observed, that 
M. Chenevix inclines to the opinion that it is a mixture of the 
two arseniates ; and lastly, there appears to be no reason why 
there should not exist several varieties of arseniate ofiron, which 
is well known to be the case with arseniate of copper. 


Articie IV, 
On some Compounds of Fluorine. By J. Smithson, Esq. FRS. 


(To the Editor of the Annals of Philosophy.) 


SIR, Jan, 2, 1824, 


WHEN numberless persons are seen, in every direction, pur- 
suing a subject with the utmost ardour, it is natural to conclude 
that their labours have accomplished all that was within their 
reach to perform. 

It must, therefore, in mineralogy be supposed, that those sub- 
stances whose abundance has placed them in every hand, have 
been fully scrutinized, and are thoroughly understood ; and that 
if now to extend the boundaries of the science it is not indis- 
pensable to explore new regions of the earth, and procure mat- 
ters hitherto unpossessed, it is yet only to objects the most rare, 
the most difficult of acquisition, that inquiry can be applied with 
any hope of new results. 

A want of due conviction that the materials of the globe and 
the products of the laboratory are the same, that what nature 
affords spontaneously to men, and what the art of the chemist 
prepares, differ no ways but in the sources from whence they are 
derived, has given to the industry of the collector of mineral 
bodies an erroneous direction. 

What is essential to a knowledge of chemical beings has been 
left in neglect ; accidents of small import, often of none, have 


-1824.] some Compounds of Fluorine. 101 


fixed attention—have engrossed it ; and a fertile field of disco- 
very has thus remained where otherwise it would have been 
exhausted. 

Fluor spar has decorated mineral cabinets from probably the 
earliest period of their existence ; every tint with which chance 
can paint it; each casual diversity of form and appearance under 
which it may present itself have been long familiar, and its true 
nature continues a problem; and its decomposition by fire was 
yet to be learned. 

Fluor Spar. 


If a very minute fragment of fluor spar is fastened by means 
of clay* to the end of a platina wire nearly as fine as a hair, 
which is the size I now employ even with fluxes, it will be per- 
ceived on the first contact of the fire te melt with great facility, 
As the fusion is prolonged, the fusibility will decrease ; protube- 
rances will rise over the surface of the ball; it will put on what 
is designated by the term of the cauliflower form; and finally 
become entirely refractory. On detaching it from the wire, it 
will prove hollow. This little capsula being taken up again by 
its side, and its edge presented to the flame, thin and porous as 
this edge is, it will withstand its utmost violence. 

Such an alteration of qualities proclaims an equal one of 
nature. I had no doubt that the calcium had absorbed oxygen, 
and parted with fluorine; that the mass had ceased to be fluor 
spar, and was become quicklime. On placing it in a drop of 
water my conjecture was confirmed; a solution took place by 
which test papers were altered ; a cremor calcis soon appeared ; 
and on allowing the mixture to become spontaneously dry, a 
white powder remained, which acids dissolved with effervescence. 

That the fluoric element was gone admitted not of doubt. To 
pursue it in its escape ; to coerce it, and render Bese to the 
senses, could not be required to establish the fact. It may, 
however, be done. 

The open tube described by M. Berzelius in his valuable work 
on the blowpipe, is adapted to the purpose by an addition to it. 
A small plate of platina foil, on a curved plate of baked clay, is 
introduced a little way into one of its ends; and secured by 


Ln RELAYS MESO NAMES mee 

bringing with the point of the flame the glass into contact with 
it. The body to be tried is fixed to this plate by means of moist 
clay ; and may then be subjected for any time to any degree of 
heat. 

Thus tried, fluor spar quickly obscured the glass by a thick 
crust of siliceous matter; and coloured yellow a bit of paper 
tinged with logwood. 


* Annals for December. 


102 Mr. Smithson on [Fes. 


M. Berzelius assigns fernambuc wood for the test of fluoric 
acid. Bergman says that this wood affords a red infusion 
which alkalies turn blue.* None such could be procured, but it 
was found that logwood might be substituted for it. The paper 
tinged with this, like that mentioned by M. Berzelius, is made 
yellow by fluoric acid and oxalic acid; but it did not seem to be 
so by sulphuric or muriatic acids, nor by phosphoric acid. 


Topaz. 


In extremely minute particles, topaz subjected to the fire at 
the end of a very slender wire soon becomes opaque and white; 
but I perceived no marks of fusion. 

This change is fee ee occasioned by the loss of its 

fluoric part. One of the times I was at Berlin, M. Klaproth gave 
me, as his reason for not publishing the analysis of topaz, that 
in the porcelain furnace it sustained a great loss of weight, the 
cause of which he had not then been able to ascertain. 
_ Topaz ground to impalpable powder, and blended with car- 
bonate of lime, melted with ease. Some of this mixture fused 
on the platina plate at the mouth of the tube, made an abundant 
deposit of silica over its interior surface ; and the bit of logwood 
paper at the end of it had its blue colour altered to yellow. 

{n the trial in this way of substances of difficult fusion, an 
apparatus of the following construction is more favourable than 
the one above described. ~ 


a. A bottle cork. 
b. A slice of the same fixed with three pins. 


c. A wire. 
* Analysis of Mineral Waters. 


1824.] some Compounds of Fluorine. 103 


d. A cylinder of platina foil introduced into the mouth of the 
glass tube, to prevent its being softened and closed by the 
flame. 

e. A platina wire, at the end of which is cemented with clay 
the subject of trial. 

I formerly suggested that topaz might be a compound of sili 
cate of alumina, and of fluate of alumina.* [I am now con- 
vinced that no oxygen exists in it; but that it is a combination 
of the fluorides of silicium and aluminum. 

This system produces a considerable alteration in the propor- 
tions of its elements. 

The mean of the six analyses quoted by M. Hatiy, in the 
second edition of his Mineralogy, is 


Pihieal <0 14s dukes. t4 ooeckows osha dO 


Whamima bois adls (ote ods dag phe’ 


Fluoric acid. ........ tidal sands 20m dtu 
f 98-0 
Deducting the oxygen from the metals, we have 

RiliGiutel | .\a)eis)2 sass er are i ie 18-0 
Pilowmimiwnas iss ss Jos auiadw ord pasado abn ale 
Pluoringway ox. cevaeva'e chia erparbea wales hing ere 

98°0 

Kryoltte. 


It has been observed to diminish in fusibility during fusion,+ 
and it was in every respect probable, from what had been seen 
with the foregoing bodies, that it would be decomposed in the 
fire. After being kept some time melted, it afforded an alkaline 
solution, which, by exposure to the air, became carbonate of 
soda, efloresced, effervesced with nitric acid, and produced 
he of nitrate of soda. 

used on the platina plate at the mouth of the tube, a copious 
deposit of silex collected in the tube ; and the bit of logwood 
paper became very yellow. 

Kryolite heated in sulphuric acid on glass destroyed its 
polish. 


1, These experiments render it highly probable that fluorine 
will be expelled from every compound of it by the agency of fire ; 
and consequently that we ate now in possession of a general 
method of discovering its presence in bodies. In cases where 
a matter is infusible, and parts with it with great difficulty, as in 


* Philosophical Transactions for 1811. 
+ Haiiy’s Mineralogy. 


104 My. Smithson on [Fes 


that of topaz, it may be required to reduce it to fine powder, or 
to act upon it by some admixture with which it melts, for the 
sake of promoting division, and multiplying surfaces. 

- Hereby is supplied what may have seemed to be an omission 
in the paper onacids.* Although it was not such, since fluorine 
is not an acid; and fluoric acid may never occur in a mineral 
substance ; as it can probably exist in combination only with 
ammonia; all its other supposed compounds being doubtless 
fluorides. | 

2. The theory of these decompositions may be acquired by 
experiment ; and light obtained on the nature of the compounds, 

{f fluor spar, for instance, is a combination of oxide of calcium 
and fluoric acid, and this is expelled from the oxide merely by 
the force of fire, the decomposition of it will take place in closed 
vessels without the presence of oxygen or of water ; fluoric acid 
will be obtained; and the weight of this acid and the lime will 
be equal together to that of the original spar. 

If the spar is metallic calcium and fluorine, and when heated 
in oxygen absorbs this, and parts with fluorine, it is fluorine 
which will be collected in the vessels, and its weight and that of 
the lime will together exceed that of the spar by the oxygen of 
the lime. res 

If itis water which is the agent of decomposition, fluoric acid 
will be collected ; but here the excess of weight will not only 
equal the oxygen absorbed by the lime, but also the hydrogen 
which has acidified the fluorine ; and this increased weight of 
the fluoric acid will prove that hydrogen is an element of it. 

It appears to have been fluoric acid which in the above related 
experiments passed into the tubes ; but the inflammable. matter 
of the flame would probably have rendered emitted fluorine such, 
It becomes of high importance to ascertain whether igmted fluor 
spar is decomposed by passing water over it, and if so what are 
the products. It is not convenient to myself at present to make 
the experiment: I therefore resign it to others. 

How far the difficulty which the action of fluorine on the ves- 
sels in which it is contained, as opposed to its examination, 
would be obviated by employing vessels of its compounds, as of 
fluor spar, or of chloride of silver; or whether it acts on all 
oxides as it does on silica, experiments have not informed me. 

3. The vegetation of matters before the blowpipe is attributed 
by a great chemist to “ a new state of equilibrium induced b 
heat between the constituent parts of bodies,”+ but the pheno- 
mena do not accord with the explanation. 

Was such the cause of the acquired infusibility, it would ma- 
nifest itself through the whole mass as soon as fusion had 
enabled the new arrangement. Itis, on the contrary, confined 
to the surface ; the interior portion continues fluid; but where- 


»* Annals for May. 
+ De Emploi du Chalumeau, p. 94. 


1824,] some Compounds of Fluorine. 105 


eyer any of this bursts the shell, and issues forth, it is instantly 
fixed in immovable solidity ; and when the process has attained 
its final state, a hollow globule remains. 

Why is the change of quality limited to the surface ; how has 
been produced the central cavity; what has forced away the 
matter which occupied it? A new element has been received 
from without, one which existed in the matter nas been parted 
with ina state of vapour. This double action may probably be 
inferred wherever a matter presents this species of vegetation. 

Some metallic bodies, as tin, lead, sulphuretted tin, arsenic- 
ated nickel, &c. present another species of vegetation, caused by 
the absorption of oxygen, and the production over their surface 
of amatter more bulky than the metal from which it is produced, 
and infusible at the heat to whichit is exposed. Here no inter- 
nal void forms. 

The mode of fusion of epidote had led me to suspect. the 
existence of fluorine in it; but on trial with the second appara- 
tus, represented above, I could not perceive a trace of it, A 
more accurate observation of its fusion has shown me that it 
does not, as generally supposed, form the cauliflower. It 
appears to do so only where so large a mass is exposed to the fire 
that but points of its surface are fused in succession. Ifa very 
minute bit is employed, it is clearly seen to puff up like borax, 
stilbite, &c.; and then, like them, become less fusible; from the 
separation, doubtless, of a vapourized element on which its 
greater fusibility had depended. The smallest particle of fluor 
spar shows no such inflation. 

We see here three several cases of intumescence in the fire; 
one where a gas is absorbed; one where a gas, or vapour, is 
disengaged ; one where the two effects are concomitant, 

There may be persons who, measuring the importance of the 
subject by the magnitude of the objects, will cast a supercilious 
look on this discussion ; but the particle and the planet are sub+ 
ject to the same laws ; and what 1s learned upon the one will be 
known of the other. 


ARTICLE V. 


On the Composition of the Ancient Ruby Glass, 
By Mr, J. T. Cooper. 


Ak (To the Editor of the Annals of Philosophy.) 


sIR, Jan, 11, 1824, 
» Tue chief difference between the ancient and modern ruby 
glass, | have understood from those who are in the habit of using 
the latter in large quantities, consists in the hardness, or infusi- 


106 On the Composition of the Ancient Ruby Glass. [Fr. 
bility of thé basis on which it is flashed, that which is now manu- 
factured being of flint, while the former is of the hardest crown 
glass ; also the difficulty of obtaining it of any size, and free from 
cloudiness or opacity: to ascertain the composition of the 
ancient glass, | made the following experiments. 

A quantity of the glass was sent me by Mr. Charles Muss, and 
such pieces were selected for examination as were free from 
decomposition, and of the deepest colour: these were powdered 
in a stone mortar, and afterwards mixed with four times 
their weight of carbonate of potash ; the mixture was heated to 
fusion in a hessian crucible, and the fused mass poured out while 
fluid. This was aftérwards powdered and digested in muriatic 
acid, which dissolved nearly the whole, what remained appear- 
ing to be mostly silex. The acid solution was slowly evaporated 
nearly to dryness, and distilled water poured on the mass, 
to wash it. To the filtered solution ammonia was added 
in excess, which threw down an abundant precipitate of 
oxide of iron, the supernatant fluid acquiring a deep blue tinge, 
which, upon examination, proved to contain only copper. 
The filter that contained the silex stood for some hours near a 
window, and the surface of the silex gradually assumed a deeper 
colour, approximating at last to a deep brown. Suspecting it to 
contain muriate of silver, I washed it with a solution of ammonia. 
On adding muriatic acid to the filtered solution, a copious preci- 
pitate of chloride of silver ensued. 

The precipitate of iron, and the ammoniacal solution containing 
the copper, were carefully examined for other substances, and 
particularly for manganese, which I know has been suspected to 
enter into the composition of this coloured glass, but 1 was not 
able to detect the smallest portion. The only substance I found, 
except those I have mentioned, was a slight trace of lime. 
From the above, it is evident the composition of this glass may 
be stated to be 

Silex, 

Oxide of copper, 
Oxide of iron, 
Oxide of silver, 
Lime. 


_ It is difficult to decide whether the oxide of iron enters into 
the composition of the coloured portion of the glass, or into 
the bases or substance of it, or both. I detached some small 
fragments of the uncoloured portion, and made a separate exa- 
mination of them, and they proved to contain abundance of iron, 
It is also difficult to determine what alkali has been used as 
a flux for the siliceous matter. The quantity of lime I obtained 
was certainly much too small to produce the effect, but I have 
some reason to suspect the alkali to be soda. . 

To endeavour to determine the exact proportions of the above 


1824.] Mr. Baily on the ensuing Opposition of Mars, 107 
colouring ingredients, which I consider to be the oxide of cop- 
per and the oxide of silver, would be useless. The colouring 
matter which forms only a film of at most 1-200th ofan inch in 
thickness upon a substance of glass varying from 1-30th to 1-10th 
ofaninch, is quite sufficient reason for desisting. Lattempted some 
time since to grind the uncoloured portion away; and in another 
instance, to detach it by fluoric acid, but in each of these 
attempts I was unsuccessful. That class of your readers to 
whom this communication may be of any service, if not fully 
aware of the proportions of the colouring oxides, may easily 
obtain them by a few experiments. 


— 


ARTICLE VI. 


On the ensuing Opposition of Mars. By F. Baily, Esq. FRS. 
VP. Ast. Soc. (Read before the Astronomical Society of 
London, Jan. 9, 1824.)* 


AT a time when we have two new and excellent observatories 
established in the southern hemisphere, where the celestial phe- 
nomena are watched and observed with the greatest diligence 
and zeal, it becomes the more important and necessary that 
corresponding observations of a certain class of those pheno- 
mena, of not very frequent occurrence, should also be made in 
the northern hemisphere, by such persons as are fortunately pos- 
sessed of the requisite means for this purpose. Without this 
co-operation, the labours of those industrious observers will lose 
much of their value, and the advantageous opportunity of eluci- 
dating an important branch of physical astronomy will be 
wholly lost to the public. 

The ensuing opposition of Mars, on the 24th of March, is one 
of this class : a phenomenon which occurs once only in a period 
of about 780 days. It is well known that corresponding obser- 
vations of this planet, in the two hemispheres, as compared with 
stars situated near its path, about the period of its opposition, 
will serve to determine its parallax. And the parallax of Mars 
being known, that of the sun may thence be deduced. This was 
the plan adopted by Lacaille, when he was at the Cape of Good 
Hope, in the year 1751; since which period, the method has 
fallen into disuse for want of an’ observatory in the southern 
peoisphere, with instruments fit to be compared with those in 

urope. 

The present period seems extremely favourable (for the reasons 
above mentioned) for the revival of this method. Atthe time of 


* See our report of the proceedings of this Society in the present Number,— Edit. 


108 Mr. Baily on the ensuing Opposition of Mars. [Fus. 


the last opposition in 1822, I ventured to draw the public atten- 
tion to the subject, by pointing out certain stars, near which the 
planet would pass ; and with the positions of which it might be 
compared. Several valuable observations were made both in the 
southern and in the northern hemisphere, which are published 
in various periodical works; and which being thus recorded, 
may be referred to with advantage, by those who devote them- 
selves to this branch of physical astronomy. 

At the present opposition, there are but few stars, and those of 
inferior magnitude, with which Mars can be advantageously 
compared. For ten days preceding and subsequent to the date 
of its opposition, Mars will not approach near to any star given 
in the large catalogues of Bradley or Piazzi, There are, however, 
five stars given in the catalogues of Lalande, inserted in the 
Connaissance des Tems for the years VIII. and XIII. with which 
the comparisons may be made. The mean places of these stars, 
on Jan. | of the present year, are given in the following little 
table ; together with the dates when Mars will be in conjunction 
‘with them. 


Con. des tems. | Mag. AR. D. Mars, 


—_ — _—— ——_ 


“An. XIII. |7, 8{12" 10 0*|2° 18’ 44”N/ April 1 
XI.| 8 {0 14 29/1 52 2 |March29 


Nile | SOO! TET So. "aF 27 
We LF Cee. Tee 25 
XIII. |6, 7} 0° 29 56]0 6 44 19 


When Mars approaches either of these stars, the observer 
should, with a micrometer, measure their distance, in a direct 
line, or take the differences, in right ascension and declination, 
between the planet and the star; the place and the correct time 
of observation being noted down. 

Accurate observations of this kind are of great importance in 
astronomy ; and as nothing tends so much to further such objects 
as a previous announcement of the phenomena about to take 
place, I trust I need not make any apology for drawing the atten- 
tion of the members of this Society to so teresting a subject. 

The diameter of Mars, on the day of opposition, will 
be 13-91”. 


109 


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*m00 SBunrdg 9yy YY ur suoTeAUO, ti ul ne que sod ‘sor jur_— sSurads “sSuridg ay Jo samen 


-oid yuesa1g "eym9}tO) -vroduiay, [oui jo yidoq 
| See ee a ee 


112 


1824.] M. Keferstein’s Table of the Salt Springs in Germany. 113 
The different formations yield the following proportions of salt: 
1, Granite and slate formation : 


Dania Or eal 24/Den. <. oe conn tices eine MOB 
Moutiers. @eeeveaeveseeees 400 


825 
2. Porphyry and coal formation. 


Lasts of salt at Munster on the Stein .. 270 
Theodorshall. ........ 880 


—— 


| 1150 
3. “ Rothe sandstein formation” (red dead lier). 


Lasts of salt at Mossbach ........... . 100 
Wersshbaoks™ ors. AFG 
Deinkboaki pas ios « offeg nee 


—_——. 


175 


4. Zechstein, or alpenkalkstein formation (new magnesian 
limestone). 


Lasts of salt at Sat tere 6d pean, eeou 
Friedrichshall........ 3750 
Offtuaianilibsies.. 
Hall, in Wurtemberg... ve 2450 
Sulz on the Necker. .. 200 
Ludwigshall. ....4.4. 3750 
Uys a ee — 
Reichenhall. ........15,500 
Dromeber eosin. ne 7200 


34,850 

5. Bunter sandstein formation (new red sandstone). 
Lasts - salt at Durrenberg.......... 6500 
Co See as 1450 

taeeeren FP... tee 1500 


Teuditz and Kotschau.. 480 
Roeseas) o,f iso eve. 1940 
Salzgitter bes de A / 850 
Salzdettfurth, .,...¢....170 - 


Salzderhelden ..... one ere 
IDE EE sc. das cave dae 420 
Bodenfelde .......... 300 


Schoningen, ........ 280 
Salzdahlum .......... 209 
New Series, vou. vit. I 


114. M. Keferstein’s. Table of the Salt Springs in Germany, [Frs. 


, 


’ Lasts of salt at Carlshaven .......+0. 300 
Allendorf. ...... ~-+. 4100 
Schmalkalden........ 300 
IAM CIOt uae vsccc sos 3200 
Salzhansen ss ....0..0. 112 
Weissenheim ........ 85 
Budingen), in. anes 75 
Homburg... .......... 100 
Soden. ...dde es tte eve 100? 
MISSIN PEN are os silanes 500 
MOE. ins oan tals CsaR gs Veer 600 
PIAIIBSEHAE ST <6 vases + 500 
Salzungenl. .s.05. «0.00 3000 
Glucksbrunn. ........ 250 

26,567 


5. Jungere aie: between the bunter sandstein and the ter- 
tiary formations. 
(a.) From the muschelkalk. 


Lasts of salt at Halle, in Saxony.... 6300 


Schonebeck........ 15000 
Suisse. ede 800 
Bindénawr itis os de ei 25 
‘Julius Halls ssi eee 14 
b. Gryphiten kalk in Germany. 
Lasts of salt at Rolching...... setters 33 
CIB ian ben's Soh aU 330 
eT Le ee 700 
Hoathentelde 4, «sanwene 1200 
BECO GNRER Sins a yeas, «be 
Grossen Reiden ,..... 180 
Map eta je6ls: ia oibimee tess 45 
Salzhemmendorf...... 1400 
Salz liebe... ose e's 500 
4508 


c. Gryphiten kalk in Alsace. 
Lasts of salt at Dieuze and Mojensie. 10,000 
7 


Chateau Salins ...... 
‘‘Lons le Saunier. .... 720 
SAMS scare oc" SAE 3030 


Vic. eoeosoeereveeee ont} 


1824.] Mr. Smithson on some Egyptian Colours. 115 
d. Green sand and chalk. 


Lasts of salt at Konigsborn near Unna. 3027 
pe MU EEL ss Ete cre ngae ce. SOO 

Sassendorf, near Soest. 640 

Westerkatten ........ 500 
Salzkatten........... 600 


5667 
48,934 
6. Tertiary formations. 
' a. Sand formation (London clay). 
Lasts of salt at Colberg. ...... fife « exe, LOUD 
Greifswalde........ os, pou 
Oldest’ isi ae a eieareiayst 1200 


Sulz, in Mécklenburg.. 440 
‘i Sulz,in Hanover, , ea ox 200 


b. Mergel sandstein (gres a lignites according to Hum- 
' boldt), from which arise the salt springs in Hungary, 
Gallicia, and the territory of Siebenburg, which yield, 


in lasts of salt, above. ........0.e0ec cece un a a ick olds 225,000 
Lasts of salt from the granite and slate formation. .... 828 
Lasts from the porphyry and coal formation. ........ 1180 


lies between the bunter sandstein and the zechstein. . 61,592 


emdthechalle vices oonhy itl ye these Srels . leareieobitr. 48,874 
Lasts from the tertiary formations, viz. the plastic clay 
(braunkohlen format.) and London clay (sand format.) 228,540 


a en ee ES 


Articie VIII, 


An Examination of some Egyptian Colours. 


By James Smithson, Esq. FRS. 
(To the Editor of the Annals of Philosophy.) 


SIR, Jan. 2, 1824. 
More than commonly incurious must he be who would not 
find delight in stemming the stream of ages ; returning to times 
long past, and beholding the then state of things and men. 
In the arts of an ancient people much may be seen concerning 
them : the progress they had made in knowledge of various kinds ; 
12 


116 Mr. Smithson on some Egyptian Colours, [Fres. 


their habits; their ideas on many subjects. And products of 
skill may likewise occur, either wholly unknown to us, or supe- 
rior to those which now supply them. 

I received from Mr, Curtin, who travelled in Egypt with Mr. 
Belzoni, a small fragment of the tomb of King Psammis. It was 
sculptured in basso relievo which were painted. 

The colours were white, red, black, and blue. 

I have heard the white of Egyptian paintings extolled for its 
brilliancy and preservation, I found the present to be neither 
lead nor gypsum ; but carbonate of lime. Chlorides of barium 
caused no turbidness in its solution. An entire sarcophagus of 
arragonite proves that the ancient Egyptians were in possession 
of an abundant store of this matter, remarkable often for its 
perfect whiteness. Was it the material of their white paint ? 

The red was oxide of iron. By heating, it became black, and 
returned on cooling to its original hue. Inacase where so much 
foreign admixture was present, since the layer of red was much 
too thin to allow of its being isolated, I considered this as a bet- 
ter proof of red oxide of iron than obtaining prussian blue. 

The black was pounded wood charcoal. After the carbonate 
of lime with which it was mixed had been removed by an acid, 
the texture of the larger particles was perfectly discernible with 
a strong lens ;. and in the fire it burned entirely away. 

The blue is what most deserves attention. It was a smalt, or 
glass powder, so like our own, though a little paler, as to be 
mistaken for it by judges to whom I showed it; but its tinging 
matter was not cobalt, but copper. Melted with borax and tin, 
the red oxide of copper immediately appeared. 

Many years ago I examined the blue glass with which was 
painted a small figure of Isis, brought to me from Egypt by a 
relation of mine, and found its colouring matter to be copper. 

I am informed that a fine blue glass cannot at present be 
obtained by means of copper. What its advantages would be 
above that from cobalt, it is for artists to decide.’ 

Intent upon the blue smalt, it unfortunately did not occur to 
me to examine, till | had washed nearly the whole of it away to 
waste, what was the glutinous matter which had been so true to 
its office for no less a period than 3,500 years; for the colours 
were as firm on the stone as they can ever have been. 

A small quantity of it recovered from the water did not seem 
to form a jelly on concentrating its solution; or to produce a 
precipitate with galls. I imagined its vegetable nature ascer- 
tained by its ashes restoring the colour of reddened turnsol 
paper, till I found those of glue do the same. 

he employment of powder of charcoal for a black would seem 
to imply an unacquaintance with lamp-black, and, perhaps, with 
bone black, and that of copper to colour glass blue, a deficiency 
of cobalt. And if the glutinous matter should prove, on a future 
examination, to be vegetable, our glue being then possessed may, 
perhaps, be deemed questionable. 


1824,] On the Crystalline Forms of Artificial Salts, 117 


ArticLte IX. 


On the Crystalline Forms of Artificial Salts. 
By H.J. Brooke, Esq. FRS. 


(Continued from p, 22.) 


Sulphate of Nickel and Copper. 


TuE primary form of this salt is an oblique rhombic prism, with 
an imperfect cleavage parallel to its lateral planes. 


Pen B1or Wi a 100° 15’ 
BPPORE Saree on wae eld 117 30 J 


I received these crystals from Mr. R. 
Phillips, and having dissolved some of 
them in distilled water for the purpose of 
obtaining others with more perfect planes, 
I found that the first crystals deposited 
from the solution were sulphate of cop- 
per; the next, sulphate of nickel and <eN, 
copper similar to those which had been 
dissolved: these were removed, and were succeeded by a crop 
of the same crystals intermingled with a few others of the 
rhombic sulphate of nickel; and crystals of both these salts con- 
tinued to be deposited together until the fluid was nearly all eva- 

orated. . 

“ There were not any crystals of sulphate of copper deposited 
from this solution after the double salt began to crystallize, but 
the solution at Mr..P.’s, from which the crystals I received had 
been obtained, had subsequently produced crystals of sulphate 
of copper. It would appear from these circumstances that the 
double salt would only be produced in uncombined portions of 
both of the single ones. 


Sulphate of Ammonia and Magnesia. 
The primary form of this salt is an oblique rhombic prism. 


P on M, or M’. ...... 104° 45’ 


Pome, ore’ sscseeeese 154 40 
Pron gs iii. s. «e+. 135 40 
POR eis MB 30 
i WU REPO bMS 109 30 
Mion eb ied ee 125 15 


_. The crystals of this and the following I 
haye received from Mr, R, Phillips. 


118 Mr. W. Phillips on Cleavelandite.. [Fes. 


Sulphate of Copper and Potash. 


The primary form is an oblique rhombic prism, and differing so 
little from the preceding in measurement, that the same figure 
may be used for both. The crystals do not appear to possess 
any distinct cleavage. 


Poon O, Or iM... cts dckmmene ve Lee OU 
Pune OLE ts se e4 alee Ndr Me fase 154 20 
P'On Cini Sabie igh 50s Sa ene ino 20 
PP ne wii side ay alee ou ote Sim ad rs ee 
T0008 Fe Sh at mana ol o.clbide bil ncaa ie ee 


ARTICLE X, 


On the Occurrence of Cleavelandite in the older Rocks generally. 
By W. Phillips, FLS. &c. 


Tue discovery of cleayelandite as an ingredient in several 
rocks of various and distant parts of England and Scotland, as 
detailed in the Annals of November last, induced me to pursue. 
the subject further, from the notion that if this mineral should be 
found only in particular descriptions of rocks, its presence, or 
the contrary, might tend to throw some light on the difficult and 
intricate inquiries connected with the comparatively relative ages 
of the older rocks in general. 

With this view I have examined rocks of different countries, 
and although the examination has been limited to two or three 
hours each evening for three or four weeks, it appears to me that 
sufficient evidence has been obtained to evince the probability 
that the presence of this mineral is almost universal in the older 
rocks, and thatit will frequently be found accompanying felspar 
in them, 

Of the rocks of Cornwall, the only one noticed in my former come 
munication was a porphyritic granite from Carnbrae; I have since 
found it intermingled with felspar, quartz, and mica, as the paste 
of a porphyritic granite from Huel Gorland Mine, near St. Die, and 
also in another from near the Land’s End ; in both the cleave- 
landite is white and opaque, and the felspar translucent or trans- 
parent. In a granite from Dartmoor, in Devonshire, consisting 
chiefly of nearly opaque red felspar intermingled with hornblende 
and quartz, the cleavelandite is translucent and slightly reddish, 
and it bears but a small proportion to the felspar. It occurs 
sparingly intermingled with felspar in the sienite of the Malvern 
Hills. have not succeeded in finding this substance as an 
ingredient of any one of the numerous specimens in my posses- 


1824.)} Mr. W. Phillips on Cleavelandite. 119 


sion from the porphyry or elvan dykes of Cornwall; the imbed- _ 
ded crystals being all felspar. 

This mineral appears to be the only substance connected with 
hypersthene, in the hypersthene rock of Sky, for [ have not been 
able to detect any felspar in the several specimens of that rock 
presented to me by Dr. Mac Culloch. I have detected it in 
contact with felspar in some fragments of granites from Tiree, 
presented to me for the purpose of examination by Capt. Vetch, 
as were also others from the Shetland Isles, Fula and Faira, in 
which also the cleavelandite occurs. To the same gentleman 1 
am likewise indebted for a mass consisting of nearly white 
lamellar felspar and green cleavelandite in about equal propor- 
tions, simply adhering, not intermixed; as well as for an isolated 
fragment about an inch and a half square, of the latter mineral of 
a dark colour, having greatly the aspect of felspar, its cleavage 
planes being more than usually bright. Both these specimens 
are from Tiree. 

The presentation to me of a box of rock specimens from 
Mont Blane and its neighbourhood, by Charles Hampden Tur- 
ner, Esq. with a catalogue “ fourni par Joseph Marie Des- 
champs, a Servoz, Canton de Chamouni,” afforded a favourable 
opportunity for their examination, especially as a large part of 
them, indeed all in which I found the cleavelandite, are noted 
in the catalogue as the “ protogine granites of Jurine.” In the 
specimen of the very summit rock of Mont Blanc, cleavelandite 
forms a considerable proportion, in connexion with steatite, talc, 
quartz, chlorite, and felspar; the cleavelandite being white, 
nearly opaque, and often considerably granular: it occurs even 
still more largely in the beautiful porphyritic granite of Pormenaz 
about two miles W or NW of Servoz, and in which the imbedded 
substance is a felspar of a delicate rose colour; the paste con- 
sists of cleavelandite, quartz, felspar, hornblende, and chlorite, 
and the aggregate is of a green colour. The rock of Vosa con- 
sists of dark lamellar felspar, imbedded chiefly in yellow and 
white cleavelandite including yellow mica. That of La Filla 
consists of nearly white and opaque cleavelandite, mica, chlo- 
rite, quartz, and felspar, and that of Brevent of the same sub- 
stances. The rock of Des Trapettes consists chiefly of white 
cleavelandite and white mica (it is elastic), containing spots of 
yellow mica; neither quartz nor chlorite is perceptible in. it ; 
and much of the cleavelandite has a granular aspect when 
viewed in a direction contrary to that of the cleavage planes ; 
two surfaces of this specimen are, however, coated by chlorite. 

The only specimen of a rock in my possession from North 
America, is one consisting chiefly of black mica, with which 
transparent cleavelandite is intermixed ; garnets are imbedded 
in it: this rock is from the banks of the Schuylkill, five miles W 
of Philadelphia. 


120 Mr. W. Phillips on Cleavelandite. [Fes. 


In all the instances above enumerated, and in many more in 
which I have failed to discover the cleavelandite, it will be 
understoodthat the means relied on for its detection were sim- 
ply those of cleaving from the rock minute fragments, and sub- 
mitting them to the reflective goniometer—a test it may be 
assumed, sufficiently satisfactory, to render it needless to 
have recourse to the labours of the chemist, where the 
planes produced by cleavage are sufficiently bright, especially 
since the angles at which the planes of the cleavelandite meet 
each other are perfectly well ascertained, and essentially differ 
from those of felspar, with which this mineral was always con- 
founded, until the error was lately detected by the nearly simul- 
taneous labours of Lévy and Rose, and thereby furnishing 
evidence (if indeed any were wanting) to the real value of the 
mineralogical niceties belonging to cleavage and measurement, 
and their essential importance to every one who would become 
acquainted with the older rocks, which it may be said it is now 
the fashion to neglect for the more inviting and less laborious 
investigations requisite for the easier comprehension of the 
newer. L 

It is scarcely needful to say, that whenever felspar is men- 
tioned as an ingredient of the before mentioned rocks, its pre- 
sence was always ascertained by the goniometer. 

In several of the rocks of Mont Blanc and the neighbouring 
mountains, it is however extremely difficult, if not impossible, to 
decide whether one of their ingredients be felspar or cleavelan- 
dite, without the assistance of the chemist, since the substance 
in question is often either considerably granular, or approaches 
the compact: sometimes, however, when that is the case, it 
becomes manifest by a studious search that this appearance only 
‘belongs to the cross fracture of the mineral, and that it does pos- 
sess cleavages sufficiently distinct for the use of the goniometer ; 
and in all cases where this has happened to me, the mineral has 
proved to be cleavelandite, not felspar : in the specimen from the 
Aiguille du Tour, which consists of a white granular substance 
having some appearance of cleavage, and which is rendered 
somewhat schistose by irregular layers of green chlorite, it is 
impossible to decide on the nature of the white substance, 
because the indications of cleavage are not sufficiently decisive 
for the goniometer, but the examination of many rocks from the 
neighbourhood leads to the conclusion that this substance is in 
reality cleavelandite. 

If we regard the elements of the several substances constitut- 
ing the rocks in which both felspar and cleavelandite occur, as 
having been in a state either of aqueous solution or of igneous 
fusion ; that is to say, in a state in which the two alkalies enter- 
ing separately into the composition of these two minerals, were 
at liberty to exert their affinities for other bodies, it seems very 


1824.] Col. Beaufoy’s Astronomical Observations. 121 


remarkable that they should each constitute separate minerals 
in connexion with very nearly equal proportions of the same 
earths—and as it occurred to me as being within the verge of 
probability that these two alkalies might, by coalescing and 
uniting themselves to the same or other earths, form another 
compound body which would probably in that case have for its 
primary form, one in which the planes would meet) at angles 
different to those either of felspar or cleavelandite, I have been 
anxious to detect any such difference if it exists, but without 
success ; for in every instance the angle obtained belonged to 
the primary form either of the one or the other of the above-~ 
mentioned mineral. 

It may be added that although these minerals are sometimes 
sufficiently distinct in the same specimen, there is no one cha- 
racter belonging to either which adequately distinguishes it from 
the other at first sight ; the most important feature is, that in 
general the cleavage planes of felspar are more brilliant than 
those of cleavelandite ; and hence it will be difficult hereafter to 
describe a rock in which one of these minerals appears to be an 
ingredient, without first having recourse either to the chemist or 
the goniometer, in order to prove that it is not the other. 


ARTICLE XI. 


Astronomical Observations, 1823. 
By Col. Beaufoy, FRS. 


Bushey Heath, near Stanmore. , 
Latitude 51° 37’ 44°3” North, Longitude West in time 1’ 20:93”, 


Dec. 30. Emersion of Jupiter’s eee. 11h 33’ 34” Mean Time at Bushey. 


BAUIRILG old ett ec ole cm -/a e212 0 11 34 55 Mean Time at Greenwich. 
Jan. 6. Emersion of Jupiter’s first 5 9 12 AT Mean Time at Bushey. 

RAtCMILGS sas -asbis -'< wine prenys 9 14 08 Mean Time at Greenwich. 
Jan. 11. Emersion of Jupiter’s first j 16 38 37 Mean Time at Bushey. 

RAVEN a one aralsisicis 0 eo v4.0 16 39 58 Mean Time at Greenwich. 


Jan, 12, Occultation of a small star by BEVIS A ies 
the moon. Immersion.... 2 72 52 56 Siderial Time. 


Jan. 12. Emersion of Jupiter’s third 8 24 20 Mean Time at Bushey. 


MAIC ds cane gists sisve dices - 8 25 Al Mean Time at Greenwich. 
Jan. 13. Emersion of Jupiter’s first § 11 08 14 Mean Time at Bushey. 
satellite . ........0--e00e-- 0 LI O09 34 Mean Time at Greenwich. 


N. B, Jupiter’s Limb was tremulous and ill defined. 


122 Mr. Moyle on an Improvement inthe Clinometer. [Fesi 


ArTicLte XII. 
“On an Improvement of the Clinometer. By M. P. Moyle, Esq. ' 
(To the Editor of the Annals of Philosophy.) 


SIR, Helsion, Jan. 1, 1824. 


I HAVE made an addition to the clinometer now generally in 
use, which I flatter myself is an improvement; at least its utility 
is more particularly felt in this neighbourhood by the superintend- 
ants of mines in calculating the dip or underlie ofa lode. — Its 
former construction pointed out only the angle from the horizon, 
of any stratum, &c. I have now added another quadrant, on 
which is delineated the number of feet and inches a lode will 
underlie at certain angles in a fathom, perpendicular depth. The 
following is an outline of the instrument. 


I find the underlie of a lode of one foot in a fathom will be 
indicated by an angle of 803° from the horizon, six feet in a 
fathom at the angle of 45°, and so on. 

. I am, Sir, your humble servant, 


M. P. Moy te. 


1824.] Mr. Gray’s Reply to the Editor. 123 


ArTIcLE XIII. 


ly to the Review of Mr. Gray’s Elements of Pharmacy. 
anne By Mr. 8. F’ Gray. 


(To the Editor of the Annals of Philosophy.) 


SIR, 18; Burton-street, Burton Crescent, Dec, 23, 1823. 


I see leave to thank you for the commendation you have 
given to my Elements of Pharmacy, in saying that it is calcu- 
lated to convey a considerable portion of information; but I 
must at the same time desire your attention to a few points in 
the sequel of your review. 

The arrangement is partly taken from Stahl, partly from Biot; 
and is such as best suited my purpose of training the student to 
scepticism, or, at least, indifference in theoretical points. 

The definition to which you object is that of Black, with the 
addition of the last clause, which I was induced to add, because 
chemists, from the analogy of electricity to galvanism, attempt 
to explain the phenomena of the former power, although it is not 
produced by alteration of temperature, or mixture of bodies, but 
by mere mechanical means, and therefore will not come within 
the limits: of the original definition of Dr. Black. Heat and cold 
are used in the definition in their popular sense, as two contrary 
powers, not only because the philosophical ideas of temperature 
and caloric had not yet been mentioned ; but also because the 
existence of a frigorific principle having been started, and its 
partisans not yet extinct, the popular expression, which involves 
no theory, best suited the cautious character of a sceptic. 

The first error which you say you shall notice occurs in p. 95, 
and after quoting the passage, you say, “ it proves incontestably 
that Mr. Gray is ignorant of the composition of sulphuric acid, 
for he has once in words, and three times by symbols, misstated 
its nature.” But I believe you will upon reflection agree with 
my statement, that su/phuric acid consists of a charge of sulphur 
united with three of oxygen. I acknowledge that I have cer- 
tainly erred in respect to oil of vitriol; but having written ten for 
one in the first instance, the subsequent repetitions were mere 
slips of the pen. How easily these occur your own use of the 
words sulphuric acid for oil of vitriol in this passage shows, 
and we shall see more proofs hereafter. As it was only intended 
in this place to explain the mode of using the symbols, the slip 
is here of no consequence, and indeed it turns out better adapted 
for that purpose than the truth would have done, as introducing 
an example of a coefficient sign. In the history of oil of vitriol, 
p- 138, the composition is stated right. 

In commenting on my. exposition of Berzelius’s laws of com- 


124 Mr. Gray’s Reply to the Editor. [Fes, 


bination, you object to my mentioning the speculations of that 
chemist on the existence of oxygen in ammonia, in an element- 
ary treatise. This is mere matter of opinion. Mr. Brande indeed 
does not make any mention of the supposed compound nature 
of nitrogen ; but both Mr. Henry (8th edit. vol. i, p. 243) and 
Dr. Thomas Thomson (6th edit. vol. i. p. 214) not only notice 
the suspicion of azotic gas, and ammoniacal gas containing oxy- 
_gen, but the one notices the ammonium of Sir H. Davy, and the 
other the nitricum of Berzelius. So that I have just cause to be 
astonished ‘at your saying, “If the student after reading this 
ini were to look into the chemical works of Thomson, 
enry, or Brande, he would find no mention either of oxygen 
or nitricum existing in ammonia.” 

My idea of the composition of the liquor plumbi acetatis 
agrees with the statements of Dr. Thomas Thomson, Mr. Henry, 
Mr. Brande, and Mr. Anthony Todd Thomson. I am again 
astonished at your saying, that “ in p. 81 no rules are given for 
describing those salts that contain an excess of base.” I know 
not how to account for this, unless by supposing a whole para- 
graph has dropped out of your copy at press, as single letters 
sometimes do; for the third paragraph in that page, consisting 
of no less than 14 lines, expressly relates to the mode of naming 
(not. indeed describing, as you have by another slip worded it) 
salts when an acid combines in different proportions with the 
same base, and. five modes of nomenclature are related; and 
in the last paragraph of p. 94, the subject is resumed. 

You then proceed to say (for I must now quote your words at 
length), ‘‘ On the same ground we object to the following state- 
ment: Moist iodine added to phosphorus yields a sour colour- 
less gas, which is rapidly absorbed by water, and must be 
collected in a quicksilver apparatus ; a gallon of this gas weighs 
about 311 grains. Here the changes are either I° + P into I? 
+ P'; or 1 + P+ H' into 1H + P', and the new acid is 
called the iodic or hydroiodic.” ‘ The pupil would naturally 
suppose that Mr. Gray considers the iodic or hydroiodic acids 
(properly hydriodic) as similar; but he ought to have known 
that iodic acid consists of oxygen and iodine, and the hydriodic 
acid of hydrogen and iodine; it is the latter only which is 
formed, excepting a quantity of phosphorous acid, of which no 
notice is taken, noris the decomposition of the water even hinted 
at, although the formation of the hydriodic acid depends upon 
it. (P. 160.)” 

__ These are your precise words. I pass over any inquiry as to 
the ground upon which you object to what I have said; although 
I am not able to discover any connexion between this passage 
and that immediately preceding it, respecting the subsalts; but 
proceed to your assertion, that I have taken no notice of the 
phosphorous acid which is formed. This shows how easily slips 
of the pen may be made, and may abate your astonishment at a 


1824.) Mr. Gray’s Reply to the Editor. 125 
slip of my own; for here after you had twice copied from my 
book the symbol for phosphorous acid, P', as being a product 
of this experiment, you assert, within the compass of only six 
lines, that I have taken no notice of its production. Nor is this 
all, for you go on to say I have not even hinted at the decompo- 
sition of the water. Is it possible that the Editor of the Annals 
of Philosophy can be unable to read a chemical theorem 
expressed in symbols? Upon no other ground can this censure, 
and the one hitherto passed of my not knowing the difference 
between iodic and hydroiodic (for so I shall continue to spell it) 
acids, be explained. The two formule I have given in symbols 
express two theories of this experiment. The first I’, P chang- 
ing into 1’, P' expressing that of Berzelius, in which iodine, I’, 
is considered as a superoxide of iodinum containing three 
charges of oxygen, which, being acted upon by phosphorus, P, 
a simple body transfers one charge of its oxygen to the phos- 
phorus, forming phosphorous acid, P', while the iodine having 
of course only two charges of oxygen left united with it, is 
changed into the iodic acid, I*, of Berzelius, not of Gay-Lussac : 
in this theory, the wateris passive. The other formula I, P, H', 
changing into I H, P' expresses the theory of Gay-Lussac, 
Here iodine, I, and phosphorus, P, are both considered as sim- 

e bodies, and the water, H', is active in the experiment, and is 
indeed decomposed, its hydrogen, H, uniting with the iodine 
and forming hydroiodic acid, I H, while its oxygen + being thus 
set free unites with the phosphorus and forms phosphorous acid, 
P'. By this developement of the symbolic formule, how little 
cause there was for your censure is evident. As these experi- 
ments on iodine are of no use in pharmacy, I should not have 
mentioned them at all, leaving them to the pure chemists to 
detail ; but that there existed a wide difference between the 
views which Berzelius and Gay-Lussac have taken of the subject. 
It was this slight connexion between them and the professed 
object of my work, which caused me to express these incidental 
matters in symbols, partly as an exercise to the student, and 
partly because Berzelius’s opinions on iodine, as detailed in the 
Annals of Philosophy, have not been noticed in any of our ele- 
mentary treatises on chemistry, and I was anxious that they 
might be brought forward. 

As to the use of the term hydrviodic acid, instead of hydrio- 
dic, it may surely be justified by this single observation. The 
union of hydrogen with chlorine produces, according to Gay- 
Lussac’s nomenclature, the hydrochloric acid ; with sulphur, the 
hydrosulphuric acid ;—with tellurium, the hydrotelluric acid ;— 
with cyanogen, the hydrocyanic acid ;—with phthore, the hydro- 

thoric acid; so strict analogy requires that the union of 

ydrogen and iodine should produce the hydroiodie acid, and 
‘our own language is not so rich in vowels that we can afford to 


126 Mr. Gray’s Reply to the Editor. [Frs. 
reject those which are offered to our enjoyment. [have indeed 
little doubt but that the term hydriodic was an accidental error 
of Gay-Lussac, or of his printer, and has heen perpetuated like 
the etiolation of Fourcroy in his Systéme, instead of etoilation ; 
or the laplysia of Linnzus in his Systema Naturz, 12th edition, 
instead of aplysia; which have been so often repeated, that they 
are become standard errors, and bid fair to supplant the true 
orthography, and disgoncert the etymologists. 

Your observations respecting arsenious acid are partly just; 
the directions respecting testing for arsenic are, I confess, 
imperfect and incorrect ; but it was not my. intention to enter 
upon the subject of forensic medicine ; and { have always taught 
my own pupils that nothing short of the production of true 
metallic arsenic will justify a medical practitioner to condemn a 
supposed poisoner in cases which are in any way dubious. 
Fortunately as arsenic is cheap, and almost always used by igno- 
rant persons, they administer it in such quantities that dubious 
cases seldom occur. I cannot, however, possibly conceive how 
you could make the following assertion :—“ Nor is the direct 
evidence by metallization in any way alluded to,” unless by again 
supposing that another whole paragraph has, by some strange 
fatality, dropped out at press from your copy ; for the very next 
paragraph, in p. 151, to the one you quote, treats of the metalli- 
zation of white arsenic by the addition of a subcarbonate of 
potasse and charcoal dust. 

Again passing over for a moment one of your observations, I 
proceed to the concluding paragraph, which is indeed the cause 
of my troubling you with this notice of your review. Man is 
always subject to error, and therefore the mention of a few 
errors in my Elements, which I am conscious must, like every 
work hitherto published, or that ever will be published, contain 
a few, and I hope but a few, would not have been any other way 
noticed by me, but by silently amending them in any future 
work. But Il am charged with dividing chemists into rational 
and irrational, and placing Sir Humphry Davy among the irra- 
tional chemists. Now I think I may fairly challenge you to 
produce the word zrrational from any part of the book. A cau- 
tious habit of distinction, that I have acquired, and of the want 
of which in the generality of publishing chemists I have several 
times complained, has led me to distinguish between pure che- 
mists, pharmaceutical chemists, and I believe technical chemists, 
not as words of reproach, but of distinction. So I have men- 
tioned publishing chemists to distinguish them. from mere 
‘amateurs, or those who either labour only for themselves, or 
those who are too modest to appear before the tribunal of the 

ublic. And again in point of theory, every: professor, and 
indeed almost every chemist, has some peculiar doctrines of his. 
own; but they may, and accordingly have been by me, divided 


1824.] Mr. Gray’s Reply tothe Editor. 127 


into two classes, according to the greater or less use they make 
of analogical reasoning in their theories. Formerly from the 
want of a sufficient number. of facts, analogical reasoning was 
the sole basis of chemical theory as may be seen in Beccher; 
by degrees direct evidence has been obtained on certain points, 
but not yet on all. Berzelius and some others, among which, 
did not my habitual indifferentism hinder me, I should rank, are 
of opinion, that the analogical reasoning of our forefathers 
should be retained so long as the facts which come to light can 
possibly be explained by their hypotheses, and even in case this 
can no longer be done, we should make as little change as possi- 
ble. These are the chemists I have denominated rationals, not 
from any superiority‘in understanding which they may claim, 
but from their greater use of analogical reasoning than is 
allowed by the opposite class ; analogical and rational being 
constantly used in science as synonymous; and the latter word 
being best adapted to be used as a substantive. The peculiar 
dogma of. the other school is to reject all analogical reasoning, 
and consider every body which has not yet been separated into 
others as simple. ‘'o these chemists, which include the generality 
of modern professors and authors, 1 have given not the name of 
irrationals as you state, and which I expressly avoided lest I 
should unintentionally offend, but that of Epicureans ; because 
Rouelle, who may be considered as the father of the sect, is said 
to have inscribed on the walls of his lecture room, a saying 
ascribed to Epicurus ; That we can know only what we perceive 
by our senses. . 

No man has a higher respect for Sir Humphry Davy, as a 
chemist, than myself. Of his two precursors in the same path, 
Homberg and Scheele, it is only the latter that can enter into 
any competition with him; and if the Pomeranian exceeds in the 
number of new substances he has discovered, the Englishman 
has by far the advantage in the greater practical advantages to 
be derived from his labours. 

. As to my opinion, however, of Lavoisier, which I have defer- 
red to this place, it is unaltered by your remarks. He indeed 
turned chemistry upside down, and he has shown us that the 
smc of chemistry may be explained by thus reversing its 

ormer theory, but theories are such tottering things that I do 
not consider this as any great feat. I still deny that chemistry 
is deeply indebted to him, in any other way than that the total 
change he proposed, coinciding with the political circumstances 
of the times, was brought into more notice than it would other- 
wise have obtained, and thus it became necessary for the culti- 
vators of chemistry either to defend the old doctrines, or 
advocate the new: and in this manner indeed he has indirectly 
been. of the greatest service to it. How often are his experi- 
ments referred to? Seldom:—lI might say never. Are they 
considered as examples of the most scrupulous accuracy like 


128 - Mr. R. Phillips’s Remarks [{Fes. 


those of Cavendish? Far from it. That you may not suppose 
this is only my own prejudiced opinion, U refer you to the 
opinion expressed by Dr. Thomas Thomson im his catalogue of 
Lavoisier’s writings, in the second volume of the Annals of 
Philosophy. I remain, Sir, yours respectfully, 

. SamueEt F, Gray. 


ARTICLE XIV. 
Remarks upon the preceding Answer. By R. Phillips, FRS, &c. 


(To Mr. Gray.) 
SIR, 


In the observations which I shall offer on your reply, I shall 
confine myself as much as possible to matters of fact. I must, 
however, confess, that I was completely in error respecting your 
motive for adopting the arrangement which I criticised. Had 
known that you were assembling gum arabic, horns, henbane 
leaves and eggs, as “ farinaceous bodies,” for the purpose of 
exhibiting an absurdity, I should have congratulated you on the 
success of your exertions ; but I think you should have ren- 
dered your motive evident ; for the reader may imagine that you 
are so unhappily circumstanced as really to suppose that eggs 
are farinaceous, and oyster shells combustible. 

I. know not from whence you have copied the definition of 
chemistry which you attribute to Dr. Black; there are two defi- 
nitions given ia his lectures, and both so unlike that which you 
ascribe to him, that neither contains the word “ cold.” 

You admit that you have four times misstated the composition 
of sulphuric acid, by assigning it ten atoms of water instead of 
one atom; but you say, that in p..138 it is stated nght. On 
referring, I find that it “is supposed to consist of S* + water.” 
Now, according to the theory of “slips,” of which you have 
made so much use, I would ask, whether the pupil having four 
times learned that oil of vitriol contains 10 atoms of water, he 
would not be likely to conclude that at p. 138 the coefficient had 
slipped out, rather than thatit had three times previously s/ippedin? 
According, however, to Berzelius S* + water, would express a 
compound of three atoms of sulphur + one atom of water; so 
that I deny you having rightly stated the composition of sul- 
phuric acid. 

l again assert that neither Thomson, Henry, nor Brande, men- 
tions the existence of oxygen or nitricum in ammonia. It is not 
necessary to quote at length: Dr. Thomson (System, vol. i. p. 
225) says, itis “a compound of three atoms of hydrogen and 
one atom of azote.” Dr. Henry (Elements, vol. i. p. 401) also 


182 4.] upon the preceding Answer. 129 


represents it as “ constituted of three atoms of hydrogen = 3+ 1 
atom of nitrogen=14 ;” and Mr. Brande, of “ 13 of nitrogen and 
3 of hydrogen.” (Manual, vol. i. p.364.) That Goulard’s extract of 
lead is a sub-binacetate and not a subtritacetate is an assertion 
which I again repeat. You will observe that three authors out 
of four whom you quote in support of your opinion, infer the 
composition of this acetate of lead, not from analysis, but from 
an experiment of Berzelius ; the fourth authority, Mr. A. T. 
Thomson, is so far from asserting this compound to be a subtrit- 
acetate, that he quotes the very analysis upon which I founded 
my conclusion of its nature. Mr. Thomson says (London Dis- 
pensatory, p.693), “‘ According to the experiments of Dr. Bos- 
tock, the constituents of 100 parts of the saturated solution are 
23-1 of oxide, 5 acetic acid, and 71°9 of water, which,” he adds, 
“ agree with the statement of Thenard, who found that the salt, 
when crystallized, consists of 17 parts of acid, 78 of oxide of 
lead, and 5 of water, in 100 parts.” Now it will appear, that 
the quantities of acid and oxide by Dr. B.’s analysis, are to each 
other in the proportion of 50 acid and 231 oxide; and in The- 
nard’s analysis as 50 to 230, very nearly. According to Dr. 
Thomson, Dr. Henry, and Mr. Brande, acetate of lead is com- 
posed of 50 acid + 112 oxide; and you will, perhaps, admit that, 
supposing Goulard’s extract to bea sub-binacetate, it must consist. 
of 5U acid + 224 oxide ; but ifa subtritacetate of 50 acid + 336, 
oxide ; the question, therefore, depends upon whether 231 or 
336 are nearer to 224, and I think J may safely leave it to you to 
decide. 

I must again insist that at p. 81 of your Elements, no rules are 

iven for describing those salts that contain an excess of base. 

The 14 lines to which you allude have not slipped out of my 
copy ; but if these 14 lines ever contained a syllable respecting 
sub-bisalts or sub-trisalts, such syllable has indeed disappeared. 
In p. 94, to which you refer me for a continuation of the subject, 
all that is contained respecting it is, that to express the number 
of charges, the terms employed are, ‘ subsesquiphosphate, sub- 
bisulphate, for salts with excess of base.” Not a word occurs 
respecting subtrisalts, those which occasioned the remark that I 
made. I admit that in p. 151 of the Elements of Pharmacy, 
there is a paragraph which treats of the metallization of white 
arsenic by the addition of “ asubcarbonate of potasse and charcoal 
dust ;” but [ deny that it has any connexion whatever with the 
subject of detecting arsenic. It is stated without reference to 
it, and just as you would mention the reduction of any other 
oxide: indeed totally imperfect as the method which you had 
previously stated is, it is given without any reservation, and as 
possessing such a degree of certainty as would render all addi- 
tional proceedings useless, 

When I asserted that you had not noticed the decomposition 
of water, and the formation of phosphorous acid, which occur 

New Series, vou. vii. K 


130 Remarks on the preceding Answer. [Fes. 


during the action of moist icdine upon phosphorus, I alluded 
merely to your verbal statements ; and I will readily confess 1o 
you that I did not understand a chemical theorem expressed in 
such symbols as you employ. 

In the first place, in giving your symbolic statement of Berze- 
hus’s theory, you tepresent his superoxidum iodicum by I°, but 


o 


he by 1; your symbol means 3 atoms of iodicum, not iodicum 


combined with 3 atoms of oxygen; P is Berzelius’s representa- 
tive of phosphorous acid, consisting of phosphorus + 3 atoms of 
oxygen; your symbol of P', if it have any meaning, is that of 
1 atom of phosphorus. Again, you represent the “ iodic acid 
of Berzelius ” by I*, which, according to him, means 2 atoms of 


iodicum ; his symbol is I. 

I observe also, that you suppose the phosphorous acid of Ber- 
zelius to contain only | atom of oxygen, whereas he states it to 
contain 3 atoms. On this subject | may remark, that you have 
performed a feat on paper which Berzelius himself would be glad 
to see reduced to experiment ; if you find that his phosphorous 
acid is formed without the decomposition of the water, you 
are of course able to present him with his imaginary iodicum in 
an isolated state; for it must have surrendered its 3 atoms of 
oxygen to the phosphorus. 

The hydriodic acid of Gay-Lussac, which you allow to be 
formed in this experiment, is not the iodic acid of Berzelius ; he 


terms it iodas hydricus,* and represents it by Aq L and not 


by I, as he would do if it were mere iodic acid, and still less by 
I?, as you have done, which, as I have already observed, means 
2 atoms of iodicum. 

In explaining Gay-Lussac’s theory, you have employed H' to 
express an atom of water ; whereas in your “right ” statement of 
the composition of sulphuric acid, you employ the word at full 
length, thus ; “ S°* + water;”’ Berzelius, however, adopts Aq, 
and if H' have any meaning at all, it designates one atom of 
hydrogen. In order to represent the oxygen of the atom of 
water, you separate the coefficient thus, +; while Berzelius 
represents it by O, and 2 atoms of oxygen by O*, but +2 would 
be rather an odd expression for the same meaning. 

T have now done with your symbols, and nearly with my 
remarks. If the errors you have committed have produced any 
effect upon me, itis that of confirming my utter dislike of symbolic 
notation, When explaining the motives that induced you to adopt 
an arrangemené which to me appeared of a most extraordinary 
description, you have attributed to it the advantage of train- 
ing the student to scepticism or indifference in theoretical points ; 


* Essai sur la Théorie des Proportions Chimiques, Table, p. 118. ~ 


) 


4) 


1824.] Dr. Traill on the Detection of Arsenic. 131 


and you almost congratulate yourself upon the errors committed 
with respect to sulphuric acid, as better adapted for your pur- 
pose than the truth would have been; what happy advantage 
you may discover in the utter confusion in which you have in- 
volved the Berzelian symbols, I cannot imagine ; and although 
your student may, in the commencement of his career, acquire 
scepticism or indiffzrence in theoretical points, he must, I think, 
terminate it in the belief that you do not possess “ that cautious 
habit of distinction ” which it is your boast to have attained. 
Yours, &c. R. Puiuuirs, 


ARTICLE XV. 


On the Detection of small Quantities of Arsenic. 
By T.S. Traill, MD. &c. 


(To the Editor of the Annals of Philosophy.) 
* DEAR SIR, Liverpool Royal Institution, Jan. 16, 1824, 


Your very interesting paper in the last number of the Annals, 
on the tests of arsenic, followed by an application to examine the 
contents of a stomach in which I discovered that deleterious 
substance, has drawn my thoughts to a subject which has often 
engaged my attention, from having been repeatedly called on to 
determine the nature of substances found in the alimentary canal 
of persons who have died under suspicious circumstances. 

Your remarks on the application of the usual liquid tests are 
extremely just, and, in my opinion, leave nothing further to be 
desired on the subject ; but 1 have long been aware of the erro- 
neous Opinion entertained by authors of reputation, respecting 
the inutility of attempting to reduce to the metallic state, portions 
of white arsenic considerably less than a grain. Even by the 
common process, | have often succeeded in reducing to a per- 
fect metallic film much less than half a grain of the arsenious 
acid ; although it was the opinion of the celebrated Black, that 
one grain, and of Dr. Bostock that three-quarters of a grain, are 
the smallest quantities from which we can hope distinct results 
by this process. 1 may here notice the importance of attempt- 
ing the reduction in all cases of suspected poison; for it has 
several times happened, that 1 have been able to show the pre- 
sence of arsenic in cases where it has been supposed absent, 
because the white powder gave no alliaceous smell when thrown 
on alive coal. This method of operating should be abandoned ; 
because the carbonic acid and sulphureous vapour from the coal 
disguise the peculiar odour of the arsenic; and much of the 
powder is probably raised in vapour without reduction, and con- 

sequently without giving out the ade smell, 
K 


132 Dr. Traill on the Detection of Arsenic. [Fes, 


The trouble and delay of preparing a coated tube induced me 
long ago to attempt the reduction in a thin glass tube, with the 
naked fire, or with the blowpipe ; and the facility thus obtained 
made the reduction much less irksome. But your happy sug- 
gestion of the spirit-lamp has rendered the process still more 
easy—even elegant; and has enabled me to produce unequivocal 
metallization of arsenic from portions of the white powder far 
more minute than what has been mentioned—a circumstance of 
no small moment, as it affords the most unexceptionable test of 
what may affect the life of a human being. 

The following simple apparatus is all that is requisite ; and 
after many trials, I give the process about to be described the 
preference. 

Take a thin glass tube 21 inches long, and about 0:4 inch 
wide, closed at one end, with a slightly dilated mouth; like the 
common test tubes of the blowpipe apparatus. A piece of cop- 
per wire, loosely twisted round its upper end, serves to attach it 
to any convenient support, at an angle of about 30° or 40°; while 
the flame of a spirit-lamp is applied to the closed end of the tube 
containing the mixture to be reduced. 

I employ either the black flux, or a little subcarbonate of soda 
or potash mixed with charcoal powder. Either of these should 
be at least equal to thrice the weight of the substance to be 
ascertained ; but a small excess of them is safer than the oppo- 
site extreme. Where the quantity is not very minute, it is 
unnecessary to grind the whole ingredients together, but mixing 
them on a piece of glass, or of writing paper, with the point of a 
knife, before they are introduced into the tube, will be sufficient. 
The tube should be dry and clean; and its orifice may be 
slightly stopped with paper. Where the quantities are very 
minute, I usually grind them in an agate mortar; but as every 
such manual operation, however simple, is embarrassing to those 
little habituated to experiment, I consider it very useful to sim- 
plify the whole process by omitting this operation, and substitut- 
ing an addition of charcoal powder, after the mixture is intro- 
duced into the tube. The flame of a spirit-lamp will speedily 
raise the closed end of the tube to a dull red heat; and in less 
than two minutes, a shining metallic crust will invest the upper 
side of the inclined tube, about half an inch from the flame. 
When the tube is cold, 1 shake out the loose materials from 
the bottom, and then scrape off the metallic crust from its sides 
with a knife. This saves the tube for further use, a matter of 
some consequence in the country. By this process I have 
reduced less than one-eighth, and even than one-tenth of a grain 
of arsenious acid, or, as it is sometimes called, the white oxide, 
to the metallic state. The metallic crust afforded by one-tenth 
ofa grain, was perfectly distinct to the naked eye, and very con- 
spicuous when a lens was employed. The scrapings of the tube 
in this case glistened strongly, with a metallic lustre, on the 


1824.) Mr. Biggs on the Expansion of Gases. 133 


clean blade of the knife ; and when six different portions of this 
substance were projected on a poker, heated to a dull red, each 
gave a distinctly visible white smoke, and decided alliaceous 
odour; although each portion could only have contained about 
1-78th of a grain of the metal. 

I may add, that if a clean knife be held in the fumes, a portion 
of a white powder will be condensed on the blade, even from the 
most minute portions of arsenic which I have thus volatilized. 

I am, dear Sir, very truly yours, 
THomas Srewanrt TRAILL 


ARTICLE XVI. 
_ On the Expansion of Gases. By Mr. Matthew Biggs. 
(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Jan, 15, 1824, 

A GENTLEMAN signing himself X. has, in the Philosophical 
Magazine for December, given some algebraic formule for cal- 
culating the expansion of gaseous fluids under increasing tem- 
perature, which, he says, prove the accuracy of certain rules for 
the same purpose, which | referred to in a paper you were good 
enough to insert for me in the Annals of Philosophy for Decem- 
ber, and the inaccuracy of some which I proposed to substitute 
for them. It is so evident that he is wrong, that I had not 
intended to take any notice of what he says, but having been 
told that some answer ought to be made, I may just observe, that 
any person who will take the trouble of working the same sum 
by his method, at one operation and at several, may satisfy him- 
self that no dependance whatever is to be placed upon it ; thus, 
let 100 volumes of gas at 32° be raised to 212°, 

100 (480 + 180) “ 
480 = 1375, 

This is correct according to Gay-Lussac and others. 

Now let 100 volumes of gas at 32° be raised to 212° by four 
several additions of 45°, 


100 (480 + 45) 


wo = 109°375, 
sO Ct) = 119-6289, 

aa ee) = 130-8441, 
130°8441 Aoi pt) ae 143-1107, 


upwards of 51 volumes more than the truth ; and if the elevation 


—s 


134 Mr. Levy on anew Mineral Substance [Fes. 


of temperature be supposed to take place by additions of single 
degrees, it is clear that the error must be immense. -@ 
The gentleman is pleased to observe at the close of his paper, 
that he has shown the failure of my attempt to correct the rules 
which have been given for making the above calculation, and 
that the one which I have proposed is not perfectly accurate. 
How he has proved this, I am ata loss to discover; but, Iima- 
gine that whether my results are accurate or not, his will form 
no standard by which to judge of them. 
I am, Sir, yours respectfully, 
MatrueEw Bicecs. 


ArticLteE XVII. 


Account of a new Mineral Substance. By M. Levy, Esq. MA. 
in the University of Paris. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Jan, 20, 1824. 


Ar the suggestion of Mr. Heuland, I propose to give the name 
of Bucklandite (in honour of the celebrated Professor of Oxford), 
to a mineral substance, the crystallographical characters of 
which I find to differ from any hitherto described. 

T have observed this new mineral upon a specimen belonging 
to Mr. Turner’s collection ; it was placed with the pyroxenes, to 
which substance it has a great resemblance of form and external 


Fig. 2. 


characters. It occurs in small crystals represented by figs. 2 
and 3; their colour is brown, nearly black, and they are opaque. 
Thcy easily scratch glass, and appear to me to be much harder ~ 


than pyroxene. I could not find any cleavage parallel to the 
natural planes of the crystals, nor in any other direction. The 


1824.] Mr, Levy on a new Mineral Substance. 135 


specific gravity and atialysis I cannot give without spoiling the 
specimen, because a sufficient quantity of the substance could 
not be detached for the purpose of experiment. 

From figs. 2 and 3, it is obvious that the forms of the crystals 
which they represent may be derived from an oblique rhombic 
prism, and that by assuming the faces I have marked m as the 
lateral planes of the primitive, and that marked P as the base, 
all the others will be the result of simple laws of decrements. An 
oblique rhombic prism may, therefore, be assumed as the primi- 
tive form of this substance; but to the same class of prisms 
belongs also the primitive form of pyroxene; it remains, there- 
fore, to examine whether those two primitive forms are connected 
by any simple mode of derivation ; and first, in order to give 
greater weight to the result of this investigation, it is necessary to 
mention thatalthough most of the crystals have theirfaces covered 
with a greyish earthy substance, which render them unfit to be 
measured by the reflecting goniometer, it is, however, possible 
to measure some of the incidences by that means, by rubbing off 
previously the earthy matter which covers the planes. 

If the crystal represented by fig. 2, is derived from the primi- 
tive of pyroxene, the faces marked p and hf! must be either the 
results of decrements upon the angles a and o of the primitive, 
or the one being the result of such adecrement, the other must 
be the base of the primitive, or the face which replaces the edge 
h, and is the result of a decrement by one row upon that edge. 
Now let 2 be the law of decrements, which would produce upon 
the angle a of the primitive of pyroxene a face corresponding to 
one of the two faces p and h', fig. 2, and m' the law which would 
produce the other upon the angle o, let 4 be the lateral edge of 
the primitive of pyroxene 1, being the oblique diagonal of the 
base. Let « represent the angle of the base of the primitive of 
“omenee with the edge h, and let 6 equal the angle of the two 

aces p and h', fig. 2; that is to say, equal to (a", 0”). Thenthe 
following formula will easily be found : 

h sin. « (n + n!) 
nn + (n—n') cos. a—1 

Now, if in this formula the numerical values of h, «, 8, corre- 
sponding to the particular case we are considering, are substi- 
tuted, it will be found that no simple values of x and n' can 
satisfy the equation, nor could any simple value be obtained for 
the one if the other was supposed to be equal to nothing, or 
infinity ; that is to say, if one of the faces p orh', fig. 2, was 
supposed to be parallel to the edge A of the primitive of pyrox- 
ene, or to the base of the same form. It appears, therefore, that 
this substance does not belong to pyroxene; the only other mi- 
neral to which it bears some analogy is amphibole, but this last 
substance cleaves always very easily parallel to the lateral planes 
of the primitive, and besides it might be proved that their forms 
are incompatible inthe same way asit has been done for pyroxene. 


Tate. (a, p') = tang, 6 = 


136 Corrections in Right Ascension of [Fes. 

From the measurements I have taken, which very nearly agree 
with those Mr. W. Phillips was so kind as to take upon a small 
crystal I gave him of this substance, [ am led to take for the prir 
mitive form, an oblique rhombic prism in which the two lateral 
planes are inclined to each other at an angle of 70° 40’, the base 
upon either of the lateral planes at an angle of 103°56’, and in 
which. the ratio of one side of the base to the lateral edge is 
nearly 100 to 97. 

The other incidences are, 


(m, h') = 125° 20) (p, e') = 121° 30’ (p, 6°) = 95° 40° 

(p, h) = 114° 55) (p, at) = 99° 41’ (m, b°) = 160° 24” 

These crystals are accompanied by large green opaque crystals 
of scapolite, lamellary black hornblend, and flesh-coloured lami- 


nary carbonate of lime. The specimen comes from the mine 
Neskiel, near Arendal, in Norway. 


ArTIcLE XVIII. 


Corrections in Right Ascension of 37 Stars of the Greenwich 

. Catalogue, together with an Inquiry how far it would be advi- 
sable that the Daily Corrections in R.A.and North Polar Dist- 
ance of the 46 Zero Stars should be computed Annually at the 
Public Expence. By James South, FRS. 


(Concluded from p. 45.) 


_» Havine in the former part of this paper asserted, that the 
corrections in right ascension of the principal fixed stars, can- 
not be obtained piece-meal without considerable trouble, and 
occasional error, we will now see how far the procuring correc- 
tions in polar distance, is subject to similar inconveniences ; in 
doing this, we will accompany the practical astronomer, first 
into the observatory, secondly into the computing room. =~ 

The instrument commonly employed for determining polar 
distances, is a telescope attached firmly to a graduated circle, 
-and by means of micrometer microscopes placed opposite various 
parts of its divided limb, the errors of eccentricity, division, and 
partial expansion, are either destroyed, or rendered almost insen- 
sible. The observations are generally conducted in the meri- 
dian, and are extremely simple, consisting only in the accurate 
bisection of the star, by the horizontal wire, situate in the focus 
of the object glass ; this done, the different microscopes are read 
off, and the mean gives the observed polar distance of the 
star. , 

To this, however, corrections must be applied; generally for 


1824.) Thirty-Seven Principal Stars. 137 


refraction, and always for aberration, lunar nutation, solar nuta- 
tion, and variation, ere the index error of the instrument can be 
found, by a single zero star; and in proportion as many, or few 
of these stars are observed, will the index error be well, or ill 
determined ; and the importance of its being accurately ascer- 
tained cannot, perhaps, be rendered more evident than by stat- 
ing, that index error is to observations with the circle, what the 
clock’s error is, to observations with the transit instrument. But 
lest I should be suspected of exaggerating the difficulties of pro- 
curing, either the corrections in right ascension, or those of 


polar distance, I will here present the reader with a specimen of 
each. 


Greenwich Observations for 1821, Nov. 27. 


a Lyre. 


Observed right ascension. ......+. 18" 30’ 46:33” 
Observed polar distance,......... 51° 21’ 33-9” 


Barometer......cccceceecssesess 29°54 inches. 
Thermometer. ...ccccsccscescsse 46° 


Correction for Right Ascension. 


Equation for aberration, precession, and solar inequality of 
precession. 


By Maskelyne’s Table 17, column « Lyre, Nov. 26 = +0°38” 


Dec. 6=+40°30 
Therefore diff. for 10 days ...... =—0°08” 
Bnd ditt, for P'dey’ os sis ese ss = —0:008 


The equation, therefore, for Nov. 27 will be + 0°38” — 0-008” 
= + 0372”. 


Equation for Nutation. 


By reference to the Nautical Almanac, and by the help of a 
little calculation, the place of the moon’s node on Nov. 27, is 
10° 29° 35’. 


By Maskelyne’s Table 18, column « Lyre 10° 20¢= 
1l 0 = +030 
Therefore diff. for 10 degrees.... = —0°11” 


And diff. for 25 minutes ........ = —0°005 
Now — 0:11” — 0-005” = — 0°105”. 


Equation, therefore, for 10°94 35’ = + 0:41” — 0°105” = 
+ 0°305” ; and + 0°372” + 0°305” = + 0°677” = the cor- 
rection required.’ 


138 Corrections in Right Ascension of (Fes. 
18" 30’ 52:92” 


Mean RA of « Lyre Jan. 1821 ...... = 

Correction tor NOV, 22... sm sleigin «aaa + (55 + 0°68 
Apparent right ascension. .......... “= 18 30 53°60 
Observed right ascension. ...... ogi. = 18 BO 400 
Clock’s error. baie eronlvanatia fy phe vba 7°27 


‘Correction for North Polar Distance. 
Equation for refraction. 
Greenwich observ. 1812, p. 251, log. mean refraction. = 1-11261 
1811, p. VJ. + log. of bar. 29°54, 
and therm. 46° =...... eoesces 0-00347 
Log. of true reframe x huis cas ates seleles Pe 
True refraction = 13:05”. 


Equation for Aberration. 


Sun’s longitude by Nautical Almanac for Nov. 27 = 8° 4° 58’ 
Gr. obs. 1813, p. 260, column « Lyre to be added 6 


Sun’s long. at the time of the transit of « Lyre. Ep 5 nae 
Annual number for aberration obs. 1812, p.251 = 6 5 26 


Diff. taken so that it may be less than 6 signs... = 1 29 33 


Log. COSINE 2... ese esse eee e esse ceeeessr ee = II03T 

Gr. obs. 1812, p. 251 + log. max. of aberration. = 12523 

' Log. of aberration. .......... Se rine: Cr = (9560 
Aberration = — 9:04”. The sign is negative, because the 


difference between the sun’s longitude and the annual number for 
aberration is less than 3 signs. This sign is to be applied to 
reduce the mean N,. P. D. to the apparent. . 


Equation for Lunar Nutation. 


Right ascension of a Lyre inspace........6. = 9 7° 44’ 
Longitude of the moon’s node .......ee0045- = 10 29 35 
Right ascension — long. moon’s node....... = 10 8 9 
Right ascension + long. moon’s node ...... =) Bayada 
Greenw. obs. £ 8°34” sin. (AR — long. )‘node) = — 6:56” | 
1812, p. 240. L120 sin. (AR + long. )*node) = — 1:10 
Lunar nutation = — 7:66”. This sign is to be applied to 


reduce the apparent to the mean N. P. D. 


Equation for Solar Nutation. 


Gr. obs. 1813, p. 260, col. a Lyra equation for Nov. 26= —0:22” 
Dec. = —0°37 


wie 


ce ee oe ee 


—- 
ie 


ee ee 


1824.] Thirty-Seven Principal Stars. 139. 


Hence diff. for 10 days........ = + 0°15” 
And diff. for 1 day. ....... ves = + 0015 
The equation, therefore, for Nov. 27 = — 0:235’’,. The sign 


is to reduce mean to apparent N. P. D. 


Equation for Variation. 


Gr. obs. 1813, p. 260, equation for Noy. 26. ...... = + 2°71)’ 
DEC i ys: Bei a cinipeeniem it eke 

‘Hence diff. for 10 GAYS i 6s 0s = + 0:07” 

And diff. for | day. .......... = 0°007 


The equation, therefore, for Nov. 27 = + 2:717”. This sign 
is to reduce the observed N. P. D. to the mean. 


Hence the correction for N. P. D. is + 13.05” + 9:04” 
— 7°66” 4 0°235”% + 2°717" = + 17:382”. 


Observed N. P. D...:....05 = 51° 21’. 33-9” 
Correction..... orden h see's + 17:382 


apparent. N.P.D.... 050002, 01, 21 61-282 
Mean N.:P. D. Jan. leie. = 51 22 37:2 


ee ee 


Index error .,..... sedan + — 45:918 


On inspecting these calculations, remembering that they alone 
refer to observations of a single star on a particular day, and 
aware that similar are needed for every zero star, as often as it is 
observed, few I apprehend will be found to dispute the point, 
that corrections in right ascension, and north polar distance, 
cannot be procured at the time of wanting them, without frequent 
error, and disgusting labour. 

Proceed we now to investigate the nature, and extent of the 
advantages, which would result, were we but supplied annually 
with a publication containing the daily corrections of the 46 zero 
stars. These would be comprised, in the equality upon which 
it would place the British, with the foreign observer—in the 
inducements which it would hold out, to the study of practical 
astronomy—in the comparative ease with which it would enable 
astronomers employed on scientific missions, to obtain accurate 
astronomical observations—in the facilities which it would afford 
us in the examination of published observations—in the superior 
accuracy with which our most important observations would be 
reduced; and lastly, in the immense labour which would be 
saved. We will consider them in order. 

1. As to the equality to which it would raise the British with the 
foreign observer.—On the continent by the industry of a Danish 
astronomer, and by the aid of the Danish government, the to 
rent places of the 46 zero stars for every tenth day of the year, have 
been published annually some time past ; but as the mean places 


140 Corrections in Right Ascension of [Frs. 


employed at our Royal Observatory, are mot therein used ; and 
as the corrections themselves do not exactly accord with those 
obtained from Maskelyne’s, or Pond’s tables, the work to us is 
rendered comparatively of little value; added to this also, it has 
never found its way into this country, till many months of its 
year have elapsed. When, however, it has arrived, I believe it 
has been employed by some, on the principle thatany assistance 
was better than none. But let it come as it may, sooner or 
later, it 2// accords with the general scientific spirit of the British 
government, to allow its astronomers to feel indebted’ for any 
standard tables, to the /abour of any foreign individual, or to the 
generosity of any nation upon earth. 

As to the inducements which it would hold out to the study 
of practical astronomy ;—that practical astronomy labours under 
more disadvantages, than any other pursuit, few I believe will 
deny ; the expence of procuring instruments, the trouble in 
using them, the uncertainty through capricious weather, of being 
able to use them when we wish; the time (namely the night) 
when alone they can be employed to the greatest advantage ; the 
sacrifices of the amusements, either of fancy, or of fashion, 
which a close attention to their use naturally entails upon us ; 
the recollection, that while the labourers in other departments 
of science are frequently rewarded by some bri/liant discovery, 
we ‘ cast our bread upon the waters, expecting not to see it for 
many days,” are powerful preventives to the general cultivation 
of practical astronomy ; but when in addition to these, it is felt, 
that the pleasures of observing are only preparatory to the 
labours of computing; known that more observations can be 
procured in one night, than can be reduced during the succeed- 
ing day ; remembered that unreduced observations are of no use ;* 
then J say it is astonishing, not that we have so few, but that we 
have any private observers at all ; and well do I know, that many 
good instruments are now lying idle, which if the auxiliary 
alluded to were afforded, would be immediately employed. But, 
perhaps, some will say, private observers are unworthy of consi- 
deration.+ Ifany such there be, I would remind them, that a 
private observer at Wanstead, discovered the aberration of light; 
and but for the labours of a private observer at Westbury, the 
Greenwich mural quadrant would probably, at the present 
moment, be distributing its inaccuracies to the astronomers of 
Europe, and the world. 


* Instances have occurred in which such a mass of unreduced observations has accu- 
mulated, that the observer has been induced to abandon further observations; knowing 
that he had by him already, more than he could expect to reduce during his life; and 
on a recent occasion, a distinguished astronomer was, under such a feeling, impelled to 
part with his instrument. Thus has practical astronomy lost one of its most indus- 
trious cultivators in the retirement of Mr. Groombridge. It will, however, be some 
satisfaction to know, that his observations, from 20,000 to 30,000 in number, are at the 
present time being reduced at the public expence! 

+ That Government think differently, is obvious from the preceding note. 


1824.] Thirty-Seven Principal Stars. 141 


As to the comparative ease with which it would enable astro- 
nomers employed on scientific missions, to obtain accurate 
astronomical observations ;—greatly to the credit of the British 
government, it has of late years transmitted to distant parts of 
the globe, several distinguished men, for various scientific pur- 
poses ; the period which from some cause or other, they can 
remain at the same station being generally short, any thing 
which would enable them to multiply observations, or to confer 
accuracy on those made, would prove highly valuable. At home, 
surrounded by all the paraphernalia for reducing observations, 
we have shown that the drudgery is hardly tolerable ; how much 
more severely then must it be felt by the travelling astronomer, 
whose situation denies him these advantages: his observations 
are purely differential, having the Greenwich stars as points of 
departure: grant him, therefore, the daily corrections of them, 
and his labours, instead of being protracted, would terminate, 
almost as soon, as the observations are completed. 

As to the facilities which it would afford to the examination 
of published observations ;—on this head I would dilate a little ; 
and much as I respect the Greenwich observations, 1 would with 
becoming deference suggest, that some alterations be made in 
the printed copies; whereby the invaluable data which they 
furnish, may more readily be converted to immediate use. For 
the right ascension observations, I would propose the insertion 
of a column immediately after that which contains the mean 
transit, in which should be presented the clock’s error by each 
observed zero star; so would the position of the instrument, with 
2am to the meridian, be instantly seen, although superior and 
inferior transits, of the same circumpolar stars, through unpro- 
pitious weather, may not have been procured. Were also the 
clock’s daily rate computed from consecutive clock’s errors, by 
the same stars in lieu of consecutive transits of the same stars, 
increased accuracy would be the result. For the observations 
of polar distance, two additional columns would be desirable; 
one appropriated to the correction for barometer and thermome- 
ter, the other wherein the index error, as found by each star, 
might be entered in the same manner as was hinted at for the 
clock’s error; and at the end of each day’s work, the mean 
index error should be inserted, so that a person, wanting the 
ca distance of any comet, or planet, might easily arrive at it 

y applying to its ohserved place corrected for refraction, the 
necessary equation for index error. Ifalso the apparent diame- 
ter of the planet, as observed with the micrometer were sub- 
-joined, it would, I think, be an improvement. Observations 
thus published would, with the assistance of the daily corrections, 
be readily examined, and occasional errors, however trivial, 
would promptly be discovered ; but without such an arrange- 
ment, or such an aid, the labour of wading through a mass of 
observations of zero stars alone, is such that few individuals 


142 Corrections in Right Ascension. [Fex. 


would think of undertaking it. I have dwelt upon this subject, 
from an opinion (perhaps a foolish one) I entertain, that much of 
the differences between Dr. Brinkley’s and Mr. Pond’s cata- 
logues, may originate not in the observations themselves, but in 
the manner in which those observations may be reduced. 

As to the superior accuracy with which our most important 
observations would be reduced ;—corrections computed at the time 
must alway be liable to error ; but if taken from tables, the accu-. 
racy of which is well established, this source of mischief must be 
excluded. 

Lastly, as to the labour which the published corrections 
would save ;—this, perhaps, it would be difficult precisely to 
ascertain. In a former part of this paper, it has been said, that 
three minutes would be required for obtaining the corrections of 
a single star, in right ascension only:; and I think those of north 
polar distance cannot be procured in less than twelve; so that 
fifteen minutes will be spent in getting both corrections. Now 
it is not too much to say, that 20 zero stars may be observed 
daily, in good observing weather; and supposing 90 such days 
to occur in the year, 450 hours will be consumed in obtaining 
corrections, which were they published annually, might be 
appropriated to some useful purpose. This, however, would be 
the labour saved at one observatory only, say at Greenwich ; but 
there are other observatories, where as well as at Greenwich, the 
advantages would be felt; some dependent upon Government ; 
some belonging to public bodies ; and others, the property of 
private individuals; that we may form something hke an esti- 
mate, of the aggregate benefit, let us enumerate the principal 
ones. Connected with Government, we have the observatories 
at the Cape, at Kew, at Portsmouth, and at Bagshot. Belong- 
ing to public bodies, we have the observatories at Madras, at 
Dublin, and at Oxford. As property of private individuals, the 
observatories of Col. Beaufoy, and Sir Thomas Brisbane; of the 
Rey. Mr. Catton, and Mr. Cooper; of the Rev. Mr. Evans, and 
Major Kater; of the Rev. Dr. Pearson and Mr. Sheepshanks. 
He, therefore, who can doubt that an immensity of labour would 
be saved by published corrections may be supposed able to 
doubt almost his own existence. 

Now as to the expence of procuring the publication in ques- 
tion. At present the apparent places* of 24 of the Greenwich 
stars for every 10th day of the year, are published by the Board of 
Longitude ; so that the corrections for only 20,+ remain to be pur- 
chased. What the Commissioners may pay for those of the 24, I 
know not; but I well know that daily corrections in right ascen- 
sion and north polar distance of the 46 stars for one year may be 


* The corrections are preferable to the apparent places, as they enable the observer 
to use the mean places from the latest determinations. 

+ The two stars of « Libre, and the two of « Capricorni, require only that the cor- 
rections for one star of each should be computed, 


| 
) 
) 


| 
| 


1824.) Analyses of Books. 143 


calculated by one computer for forty pounds: it is not likely, 
therefore, to be far from correct, if we say that for forty pounds 
more than.are at present expended, the daily corrections might 
be procured, done by two separate computers, and consequently 
entitled to every possible confidence. 

Having shown what would be the benefits which would result 
from such a publication ; having pretty well ascertained what 
would be the expence of procuring it; it only remains to see, 
how far the former are equivalent to the latter :—the task is easy. 
To place the British observer on an equal footing with the 
foreign, is worth something ;—to induce individuals to the study 
of practical astronomy, 1s surely worth something ;—to enable 
travelling astronomers to multiply observations, and to prove the 
accuracy of those they make, 1s certainly worth something ;—to 
afford facilities to the examination of published observations, is 
doubtless worth something;—to entail accuracy in the reduction of 
the most important observations, is unquestionably worth some- 
thing ;—and to save an immensity of labour is indisputably worth 
something. What may be the individual value of the advantages 
just enumerated, it is needless to inquire; but taken collectively, 

hesitate not to say, that it is equivalent at least to ten times the 
sum which need be spent in procuring i. 

Hence I can come to the conclusion, “ That the daily correc- 
tions in right ascension and north polar distance of the 46 zero 
stars, should be published annually at the public expence.” 

Blackman-street, Jan. 29, 1824. James Souru. 


ARTICLE XIX. 
ANALYSES oF Booxs. 


Philosophical Transactions of the Royal Society of Loudon, for 
1 pe ee 8 


(Continued from p, 65.) 


XVI. An Account of an Apparatus on a peculiar Construction 
for performing Electromagnetic Experiments. By W. H. Pepys, 
Esq. FRS.—(See Annals, N.S. v. 392.) 

VII. On the Condensation of several Gases into Liquids. By 
M. Faraday, Chemical Assistant in the Royal Institution. 
Communicated by Sir H. Davy. (See the present number, p. 89.) 

XVII. On the Application of Liquids formed by the Conden- 
sation of Gases as mechanical Agents. By Sir Humphry Davy, 
Bart. Pres. RS. 

“ The elasticity of vapours in contact with the liquids from 
which they are produced under high pressures by high tempera- 
tures, such as those of alcohol and water,” observes the Presi- 


144 Analyses of Books. [Fes. 


dent, after some prefatory remarks, “ is known to increase in a 
much higher ratio than the arithmetical one of the temperature ; 
but the exact law is not yet determined; and the result is 
a complicated one, and depends upon circumstances which 
require to be ascertained by experiment. Thus the ratio of the 
elastic force, dependent upon pressure, is to be combined with 
that of the expansive force dependent upon temperature; and 
the greater loss of radiant heat at high temperatures, and the 
developement of latent heat in compression, and the necessity 
for its reabsorption in expansion (as the rationale of the subject 
is at present understood) must awaken some doubts as to the 
economical results to be obtained by employing the steam of 
water under very great pressures, and at very elevated temper- 
atures. 

“No such doubts, however, can arise with respect to the use 
of such liquids, as require for their existence even a compression 
equal to that of the weight of 30 or 40 atmospheres : and where 
common temperatures, or slight elevations of them, are sufficient 
to produce an immense elastic force; and when the principal 
question to be discussed is whether the effect of mechanical 
motion is to be most easily produced by an increase or diminu- 
tion of heat by artificial means. 

“With the assistance of Mr. Faraday I have made some 
experiments on this subject, and the results have answered m 
most sanguine expectations. Sulphuretted hydrogen, which 
condenses readily at 3° Fahr. under a pressure equal to that 
which balances the elastic force of an atmosphere compressed 
to =, had its elastic force increased so as to equal that of an 
atmosphere compressed to -+. by an increase of 47° of temper- 
ature. Liquid muriatic acid at 3° exerted an elastic force equi- 
valent to that of an atmosphere compressed to 4; by an 
increase of 22°, it gained an elastic force equivalent to that of 
an atmosphere compressed to -!,; and by a further addition 
of 26°, an elastic force equivalent to that of air condensed to 
qv of its primitive volume. These experiments were made in 
thick glass tubes hermetically sealed. The degree of pressure 
was estimated by the change of volume of air confined by mer- 
cury in a small graduated gage, and placed in a part of the tube 
exposed to the atmosphere, and the temperatures were dimi- 
nished from the degree at which the gage was introduced, i.e. 
the atmospheric temperature by freezing mixtures; so that the 
temperature of the air within the gage could not be considerably 
altered ; and as the elastic fluid surrounding the gage must have 
had a higher temperature than the condensed fluid, the diminu- 
tion of the elastic force of the vapour from the fluids cannot be 
considered as overrated. 


“ From the immense differences between the increase of elastic — 


force in gases under high and low pressures, by similar incre- 


1824.] Philosophical Transactions for 1823, Part LI. 145 


ments of temperature, there can be no doubt that the denser the 
vapour, or the more difficult of condensation the gas, the greater 
will be its power under changes of temperature as a mechanical 
agent: thus carbonic acid will be much more powerful than 
muriatic acid. In the only experiment which has been tried 
upon it, its force was found to be nearly equal to.that of air 
compressed to =), at 12°F. and of air compressed to 5) at 
32°, making an increase equal to the weight of 13 atmospheres 
by an increase of 20 of temperature; and this immense elastic 
force of 36 atmospheres being exerted at the freezing point of 
water.* 

‘In applying the condensed gases as mechanical agents there 
will be some difficulty ; the materials of the apparatus must be 
at least as strong and as perfectly joimed as those used by Mr. 
Perkins in his high pressure steam engine: but the small differ- 
ences of temperature required to produce an elastic force equal 
to the pressure of many atmospheres, will render the risk of 
explosion extremely small; and if future experiments should 
realise the views here developed, the mere difference of temper- 
ature between sunshine and shade, and air and water, or the 
effects of evaporation from a moist surface, will be sufficient to 
produce results, which have hitherto been obtained only by a 
great expenditure of fuel. 

“ T shall conclude this communication by a few general ob- 
servations arising out of this inquiry. 

“ There is a simple mode of liquifying the gases, which at 
first view appears paradoxical, namely, by the application of heat ; 
it consists in placing them in one leg of a bent sealed tube con- 
fined by mercury, and applying heat to ether, or alcohol, or 
water, in the other end. In this manner, by the pressure of the 
vapour of ether I have liquified prussic gas and sulphurous acid 
gas, the only two on which I have made experiments; and these 
gases in being reproduced occasioned cold. 

“ There can be little doubt that these general facts of the 
condensation of the gases will have many practical applications. 
They offer easy methods of impregnating liquids with carbonic 
acid and other gases, without the necessity of common mecha- 
nical pressure. 

“ They afford means of producing great diminutions of tem- 
perature, by the rapidity with which large quantities of liquids 
may be rendered aeriform ; and as compression occasions similar 
effects to cold, in preventing the formation of elastic substances, 


* “ Since this paper was read, Mr. Faraday has ascertained that the vapour of am- 
monia at 32° exerts an elastic force equal to that of an atmosphere compressed to 
5° and at 50° to that of an atmosphere compressed to an and that the vapour of ni- 
trous oxide at 32° has an elastic force equal to that of an atmosphere compressed to 
rr and at 45° to an atmosphere compressed to aa nearly.” 

New Series, vou. vu. if 


146 Analyses of Books. [Fes. 


there is great reason to believe that it may be successfully 
employed for the preservation of animal and vegetable substances 
for the purposes of food.” 

An appendix to this paper gives the following statement :— 

“In investigating the laws of the elastic forces exerted by 
vapours or gases raised from liquids by increase of temperature 
under compression, one of the most important circumstances to 
be considered is the rate of the expansion, or what is equiva- 
lent, of the elastic force, in atmospheres in different states of 
density. 

“ It has been shown by the experiments of MM. Dalton and 
Gay-Lussac, that elastic fluids of very different specific gravities 
expand equally by equal increments of temperature, or, as it 
may be more correctly expressed, according to the elucidations 
of MM. Dulong and Petit, that mercury and air, or gases, are 
equivalent in their expansions for any number of degrees in the 
thermometrical scale between the freezing and boiling poimts of 
water ; and the early researches of M. Amontons seemed to show 
that the increase of the spring or elastic force of air by increase 
of temperature, was in the direct ratio of its density. Iam not 
however acquainted with any direct researches upon the changes 
of volume produced in gases in very different states of conden- 
sation and rarefaction by changes of temperature, and the 
importance of the inquiry, in relation to the subject of my last 
communication to the Society, induced me to undertake the 
following experiments. 

“ Dry atmospherical air was included in a tube by mercury, 
and its temperature raised from 32° Fahr. to 212°, and its expan- 
sion accurately marked. The same volumes of air, but of double 
and of more than triple the density under a pressure of 30 and 
65 inches of mercury, were treated in the same manner, and in 
the same tubes ; and when the necessary corrections were made 
for the difference of pressure of the removed column of mercury, 
it was found that the expansions were exactly the same. 

** An apparatus was constructed, in which the expansions of 
rare air confined by columns of mercury were examined and 
compared with the expansions of equal volumes of air under 
common pressure; when it appeared, that for an equal number 
of degrees of Fahrenheit’s scale, and between 32° and 212° they 
were precisely equal, whether the air was 4, +, or 4 of its natural 
density. 

“‘ Similar experiments were made, but they were necessarily 
less precise, with air condensed six and expanded fifteen times, 
with similar results.” 

XIX. On the Temperature at considerable Depths of the Carib- 
bean Sea. By Capt. Edward Sabine, FRS.: in a Letter 
addressed to Sir H. Davy.—-(See Annals, N.S. v. 462.) 

XX. Letter from Capt. Basil Fall, RN, to Capt. Kater, com- 
municating the Details of Experiments made by him and Mr. 


1824.] Proceedings of Philosophical Societies. 147 


Henry Foster, with an Invariable Pendulum ; in London ; at the 
Galapagos Islands in the Pacific Ocean, near the Equator ; at 
San Blas de California on the NW Coast of Mexico ; and at Rio 
de Janeiro in Brazil. With an Appendix, containing the Second 
Series of Experiments in London, on the Return. 


“ Abstract of the most exact Results at each Station.” 


Stations. Paenieeale to Bguatos Eiptcity. hig es 
Galapagos 0°32’ 0’N| -0051412 | az#yq| 39:017196 
San Blas.. 21 30 25 N| -0054611 = +-¢5,| 39°00904 
Rio. ..... 22 55 228} -0053481_ | sata | _39:01206 


(To be continued.) 


ARTICLE XX. 
Proceedings of Philosophical Societies. 


ROYAL SOCIETY. 


Dec. 1 (coniinued)—When the President had concluded his 
address to the Astronomer Royal, the Society proceeded to the 
election of a Council and Officers; and the following were de- 
clared duly elected :— 

Of the Old Council_—The Right Hon. Sir H. Davy, Bart. ; 
Samuel Goodenough, Lord Bishop of Carlisle; W. T. Brande, 
Esq.; Taylor Combe, Esq.; J. W. Croker, Esq.; Davies 
Gilbert, Esq.; Charles Hatchett, Esq.; Sir Everard Home, 
Bart.; John Pond, Esq.; W. H. Wollaston, MD.; Thomas 
Young, MD. For. Sec. 

Of the New Council—Bemard Edward, Duke of Norfolk ; Sir 
James Mac Gregor, Bart.; William Allen, Esq. ; Major Thomas 
Colby; James Ivory, Esq.; William Marsden, Esq.; W. G. 
Maton, MD.; Edward Rudge, Esq.; William Sotheby, Esq.; 
Henry Warburton, Esq. 

President.—The Right Hon. Sir H. Davy, Bart. 

Treasurer.—Davies Gilbert, Esq. 

Secretaries—W. T. Brande, Esq. and Taylor Combe, Esq. 

Dec. 11.—John Bayley, Esq. and George Townley, Esq. 
were admitted Fellows of the Society; and MM. Fourier and 
Vauquelin were elected Foreign Members. 

A paper was communicated, “ On the Nature of the Acid and 
Saline Matters usually existing in the Stomachs of Animals ;” by 
William Prout, MD. FRS. ~ 

The object of this paper was to prove, that the acid usually 
found to exist in the stomach of animals during the digestive 

L2 


148 Proceedings of Philosophical Societies. [Frs. 
process is the muriatic acid, and that the saline matters consist 
chiefly of the alkaline muriates. 

The method adopted by the author to prove this, was to digest 
the contents of the stomach of a rabbit, or other animal, in dis- 
tilled water as long as they imparted any thing to that fluid. 
The solution was then divided into four equal portions. The 
first of these was evaporated to dryness in its natural state, and 
the residuum burnt, by which means the muriatic acid in union 
with a fixed alkali was ascertained. Another portion was super- 
saturated with potash, evaporated to dryness, and burnt as before, 
and thus the total quantity of muriatic acid present determined. 
A third portion was exactly neutralized with a solution of potash 
of known strength, which gave the proportion of free acid pre- 
sent. A fourth portion was reserved for miscellaneous ex- 
periments. From the results thus obtained, checked by others, 
the author was enabled to ascertain the proportion of muriatic 
acid present, whether in union with a fixed or volatile alkali, 
or in an unsaturated state ; and the quantity in the latter state 
was always found to be considerable, and in some instances 
greater than the quantity in combination. Dr. Prout obtained 
similar results in different animals, as well as in the human sub- 
ject, and in one instance, from 20 ounces of fluid ejected from 
the human stomach, ina severe derangement of that organ, he 
found upwards of half a dram of muriatic acid of specific gravity 
1-160. 

The reading was also commenced of a paper, entitled, “ An 
Inquiry respecting the supposed Heating Effect beyond the Red 
End of the Spectrum; by Baden Powell, MA. of Oriel College, 
Oxford: ”” communicated by J. G. Children, Esq. FRS. 

Dec. 18.—The reading of Mr. Powell’s Inquiry was con- 
cluded. 

The primary object was to ascertain whether the explanation 
of the invisible heating rays suggested by Prof. Leslie, viz. that 
the effect was owing to a concentration of secondary light 
reflected from the clouds, refracted to a position just without the 
red rays, was correct or not.—(Inquiry into the Nature and Pro- 
pagation of Heat, p.457, and note 45.) 

‘The experiment was tried with a differential thermometer, having 
the sentient bulb blackened with Indian ink. The prism was 
placed in situations most favourable to such an effect, and in 
various inclinations ; but the effect exterior to the red rays was 
never more than 3°, while in the extreme visible red, it was often 
from 16° to 25°. 

The effect of altering the coating was next tried; and on 
covering the bulb with thin yellowish-brown silk, it stood in the 
extreme red rays at 7°; halfan inch beyond, at 7°; while, when 
merely blackened, it stood in the red at 12°; half an inch 
beyond, at 2°. 


t appears then that the exterior heating effect is not produced 


1824.] Royal Society. 149 
in proportion to the darkness of colour in the bulb, but is more 
developed by a thicker and rougher coating, not so sensible 
to light, but more so to simple radiant heat. 

A variety of different coatings were then tried, with many of 
which an exterior effect was produced nearly equal to that in the 
red rays. 

These coatings being described and arranged in the order of 
the greatest exterior effect relatively to the interior, the general 
result was, that the magnitude of exterior effect, though doubt- 
less caused in some degree by secondary light refracted to that 
position, is chiefly attributable to a peculiar heating power 
which differs in nature from that acting within the visible spec- 
trum, in the circumstance of its being more developed by such 
surfaces as are known to be most sensible to the absorption of 
common non-luminous radiant heat, without reference to darkness 
of colour, or absorptive power for fight. 

Coatings equally described as black may be very different in 
their power of absorbing simple heat, and to some slight differ- 
ence of this sort in the coatings of the thermometers employed, 
it is highly probable that much of the discrepancy between 
different celebrated observers may be attributed. 

The exterior effect being shown to be analogous in its proper- 
ties to simple heat, an attempt was made to ascertain whether it 
radiated in any specific direction; for this purpose a plate of 
glass, which stops common radiant heat, was interposed a little 
below the prism, but produced no diminution of this effect. 
When it was placed parallel to the red rays, and forming a sort 
of boundary to them, so as to intercept any eflect coming out- 
wards from them, the heating effect was greatly diminished. 

From all these experiments, the conclusion seems to be, that 
the red rays acquire a power of radiating heat outwards front 
their own particles. 

In a supplement, the author describes a heating effect exterior 
to the cone of light formed by a lens, affected like the former by 
the nature of the surface on which it acts. He also states, 
that he has investigated other phenomena connected with these, 
which may probably tend to afford an explanation of many of 
the relations of light to heat. 

A communication was also read, ** On the North Polar Dist- 
ances of the principal Fixed Stars, by J. Brinkley, DD. FRS.” 

In this paper Dr. Brinkley controverts the statements of Mr. 
Pond respecting the southeru motion of the fixed stars, as given 
in the Philosophical Transactions for 1823; and altogether 
denies the validity of that astronomer’s conclusions on the sub- 
ject. He shows that the Greenwich and Dublin Catalogues of 
1813 differ merely a few tenths of a second, and those of 1523 
still less ; and he ascribes the appearance of a southern motion 
to a slight error in the Greenwich Catalogue of 1810, In endea- 
vouring to prove this, Dr. B. adduces the observations of Brad- 
ley in 1728, of Cassini in France in 1740, of Dr. Maskelyne at 


150 Proceedings of Philosophical Societies. [Fes. 


Schehallien, of Piazzi at Palermo, of Mudge in England in 1802, 
and of Lambton in Hindostan in 1805. The Westbury obser- 
vations, he remarks, differ too much from the Greenwich to be 
available in this question ; and those of Mechain are opposed by 
others made with better instruments. Mr. Pond has diminished 
the quantities in Dr. Brinkley’s Catalogue, by applying Brad- 
ley’s refraction, while he leaves M. Bessel’s in their original 
form ; and is thus enabled to place his own as means between 
them: to which mode of correction, however, Dr. Brinkley 
strongly objects. The question of Parallax, Dr. B. considers, 
is still quite open for discussion; but its consideration he defers 
for the present. Various tables are annexed to the paper, in 
illustration of the statements it contains. 

A paper was likewise communicated, “ On the Figure requi- 
site to maintain the Equilibrium of a homogeneous fluid Mass 
Lh revolves upon an Axis;” by James Ivory, Esq. MA. 

The Society then adjourned over the Christmas vacation, to 
meet again on Thursday the 8th of January. 

Jan. 8.—At this meeting, Anthony M, R. Story, Esq. was 
admitted a Fellow; and the reading was commenced ofa paper, 
entitled, ‘‘ Observations on the Positions and Distances of 
Three Hundred and Eighty Double and Triple Fixed Stars, made 
in the Years 1821, 1522, and 1823;” by J. F. W. Herschel, 
Esq. FRS. and J. South, Esq. FRS. 


LINNEAN SOCIETY. 


The meetings of this Society were resumed on the 4th of 
November. Among the presents then on the table were speci- 
mens of eighty-five species of birds sent from India, by Major- 
Gen. T. Hardwicke, FRS. and FLS., comprising many rare and 
several new species ; and with them was a curious species of 
musk rat; and also the head of Antilope Quadricornis, the Chi- 
kara of Bengal, a notice of Gen. Hardwicke’s description of 
which, read before the Society on the 17th of June last, will be 
found in the Annals for the succeeding August. 

The following communications were read : 

“A Description of the Swallow-tailed Falcon, Falco furcatus, 
Linn. taken near Hawes, in Wensley Dale, Yorkshire, in 1805 ;” 
and, “A Description of a Bird, supposed to be the Radlus 
pusillus of Latham, shot at the same place in 1807 ;” by W. Fo- 
thergill, Esq. communicated by Dr. Sims, FLS. 

Observations on the Genus Onchidium of Buchanan, with a 
poor of a new Species ; by the Rev. Lansdown Guilding, 

S. 

In this paper Mr. Guilding gives an improved generic charac- 
ter of Onchidium ; class Mollusca: ord. Cephala; div. Gastero~ 
poda: “‘ Corpus oblongum, repens, subtus planum. Penula car- 
nosa pedem totum tegens. Os anticum, longitudinale. Anus pos- 
ticus, infra. Tentacula duo retractilia. Oculi terminales,” He 


1824.] Linnean Society. 161 
enumerates six species, including a new one thus characterized : 
“ O. occidentale, dorso fusco, atomis brunneis elevatis sparsis, 
ventre pallido, lateribus livido-maculatis, brachits apice dwwisis.” 
Found in moist places of the mountainous parts of St. Vincent’s. 

Nov. 18.—The reading was commenced of a paper, entitled, 
“« Experiments and Observations on the Light and Luminous 
Matter of the Lampyris noctiluca, or Glow-worm;” by John 
Murray, FLS. 

Dec. 2.—The reading of Mr. Murray’s paper was continued ; 
and the following communication was also read: 

* Descriptions of nine new Species of the Genus Carex,, 
Natives of the Himalaya Alps in Upper Nepal; ” by Mr. David 
Don, Librarian to the Linnean Society. 

These Carices were sent to A. B. Lambert, Esq. VPLS. by 
Dr. Wallich; they bear a greater resemblance to the European 
than to the American species. Mr. Don, in describing them, 
has taken for his model the Bishop of Carlisle’s Monograph of 
the British species, in vol. xi. of the Linnean Transactions ; their 
specific characters are as follows : 

1. C. nubigena, digyna; spiculis subnovenis ovatis confertis, 
arillis ovatis striatis rostratis bifidis margine denticulato-scabris, 
glumis ovatis acuminatis, culmo striato nudo inferné tereti, foliis 
ivolutis.—2. C. foliosa, digyna; spica elongatd, spiculis 
ovato-oblongis adpressis; inferioribus subremotis, arillis ellip- 
ticis rostratis bifidis margine levibus, glumis ovatis aristatis, 
culmo acute triquetro scabro, foliis planis.—-3. C.flerilis, digyna ; 
vaginis elongatis pedunculo brevioribus, spicis filiformibus cer- 
nuis apice masculis, glumis ellipticis acutis, arillis ovatis striatis 
pilosis rostratis—4. C. macrolepis, digyna; vaginis elongatis 
pedunculo brevioribus, spicis strictis cylindraceis apice masculis, 
glumis lanceolatis longicuspidatis, arillis ovatis rostratis seaber- 
rimis costatis apice bipartitis—5. C. longipes, digyna; vaginis 
elongatis pedunculo 4-plo brevioribus, spicis cylindraceis erectis 
apice masculis, glumis ellipticis aristatis, arillis ovatis costatis 
glabris rostratis.—6. C. aristata, trigyna; vaginis elongatis sul- 
catis, spicis cylindraceis strictis apice masculis ; terminalibus 
omnino masculis, glumis late ellipticis aristatis, arillis ovalibus 
triquetris rostratis scabris.—7. C. chlorostachya, trigyna ; vaginis 
nullis, spicis fcemineis cylindraceis erectis pedunculatis ; mascu- 
lis solitariis, glumis ovato-lanceolatis acuminatis apice scabris, 
arillis ventricosis costatis apice rostratis bifurcis gluma longiori- 
bus.—8. C. denticularis, digyna; vaginis nullis, spicis fcemineis 
filiformibus pedunculis patulis; masculis solitariis pedunculatis, 
glumis cuneatis: acumine longo spinuloso, arillis cuneato-orbi- 
culatis papilloso-micantibus compressis marginatis.—9. C. alo- 
pecuroides, trigyna ; vaginis nullis, spicis foemineis erectis cylin- 
_ draceis subsessilibus ; masculis solitariis, glumis ellipticis acumi- 

natis superne scabris, arillis lanceolatis compressis leevibus apice 
truncatis emarginatis. . 


152 _ Proceedings.of Philosophical Societies. (Fes. 


ASTRONOMICAL SOCIETY. 


Nov. 14, 1823.—This Society held its first meeting after the 
late recess this evening, when a paper by G. Dollond, Esq. was 
read, descriptive of a new instrument of his invention for mea- 
suring vertical and horizontal angles in practical astronomy. 
The instrument was. exhibited in the room, and consists of two 
telescopes, two vertical divided circles, and an artificial horizon, 
by means of which the object is seen by direct and reflected 
vision; and no less than 32 distinct readings may be obtained 
of each observation, without the usual attention to levelling the 
instrument. 

An elegant inkstand was presented for the Society’s table, and 
many other valuable presents were received. 

The honorary medals we before alluded to (Annals, N.S. vi.) 
were officially announced from the chair this evening; viz. 
the Society’s gold medals, to Charles Babbage, Esq. for his 
valuable invention of applyimg machinery to the purposes of cal- 
culation, and to Prof. Encke for his investigations relative to the 
comet which bears his name. The silver medals of the Society, 
to Mr. Rumker for the re-discovery of M.Encke’s comet in 1822; 
and to M. Pons for the discovery of two comets in the same 
year, as well as for his great zeal and perseverance in cometary 
astronomy. These medals are to be presented at the ensuing 
anniversary of the Society in the present February. 

Dec. 12.—The papers read this evening consisted of a very 
able and elaborate preface which had been prepared by J. F. W. 
Herschel, Esq. the Foreign Secretary, at the request of the 
Council, to a series of tables for calculating the places of the 

rincipal fixed stars, which have been computed by order of the 

ociety; and will be printed in the forthcoming volume of its 
memoirs, and a supplement to a paper before read on the theor 
of astronomical instruments, by Benj. Gompertz, Esq. FRS. and 
MAS. 

Jan. 9.—The papers read at the meeting of this evening were 
as follows : 

Observations on the Comet of 1811 taken at the Havannah, 
by Don Joseph Joachim de Ferror of Cadiz, deceased, commu- 
nicated by the President. 

These observations were accompanied by computations of the » 
comet in an elliptic orbit, and the elements are very nearly the 
same as those’bought out by M. Argelander. 

On the Constants of Deviation occurring in the Reduction of 
Astronomical Observations, by Benj. Gompertz, Esq. FRS. and 
MAS. 

This paper examines the causes of deviation, and proposes 
formule for their more easy reduction ; it is, however, so purely 
mathematical as not to admit of abridgment within our limits. 

On the Opposition of the Planet Mars, which will take place 


1824.} “Geological Society. 153 
on the 24th of March next; by Francis Baily, Esq. FRS. and 
VP. Ast. Soc. 

This paper we have obtained permission to print at full length ; 
see p. 107 of our present number. 


GEOLOGICAL SOCIETY. 


Nov. 7.—A letter was read, dated May 10, 1823, from George 
Cumberland, Esq. Hon. Mem. GS. “ On a Fossil of the Chalk,” 
accompanied by a drawing. 

A letter was read, dated July 14, 1823, from George Cumber- 
land, Esq. Hon. Mem. GS. “On a new Species of Encrinus 
found in the Mountain Limestone, near Bristol.” 

A notice was read, containing an Analysis of the Aluminite of 
St. Helena, by Dr. Wilkinson, of Bath: communicated by Col. 
Wilks, MGS. 

On this analysis Col. Wilks observes, that there is a remarka- 
ble difference between the component parts of the aluminite of 
St. Helena, and the sub-sulphate of alumine found at Newhaven 
and Halle, as given by Phillips, p. 111. 

A paper was read on the Geology of Parts of the Islands of 
Madeira, Porto Santo and Baxo, by T. E. Bowdich, Esq. 

From the investigations of Mr. Bowdich, it appears that such 
parts of these islands as he examined consist principally of hori- 
zontal strata of limestone and sandstone containing fossils, inter- 
sected, and sometimes capped by basalt. 

Nov. 21.—An extract of a letter was read from the Rey. Lans- 
down Guilding, MGS. containing an Account of a Fossil found 
in the Blue Lias at the Berkeley Canal, near Gloucester, accom- 
panied by the Fossil. 

A paper was read, “ On the Lias of the Coast in the Vicinity 
of Lyme Regis, Dorset,” by H. T. de la Beche, Esq. FRS. FLS, 
and MGS. 

In a former communication in the first part of vol. i. second 
series, of the Society’s Transactions, the author had presented an 
outline of the geological features of the coast near Lyme Regis. 
The present paper is intended as supplementary, and the sections 
before published are referred to. Mr. de la Beche now enters 
into a detailed description, illustrated by a drawing, of the various 
strata composing the lias formation. 

This formation consists of about 110 feet of lias, composed of 
more than 72 beds of limestones alternating with the same num- 
ber of marl beds, surmounted by about 500 feet of lias marls. 
An account is subjoined of the various fossil shells and other 
organic remains found in the lias, accompanied with several 
descriptive drawings. 

Dec. 5.--A paper was read, entitled ‘* Remarks on the Geo- - 
logy of Siam and Cochin China, and certain Islands im the 
Indian Archipelago, and Parts of the adjacent Continent,” by 
John Crawford, Esq. MGS. 


154 Scientifie Intelligence. [Fer. 


METEOROLOGICAL SOCIETY. 


The second general meeting of this new and promising asso- 
ciation was held on Wednesday, Nov. 12, 1823, in pursuance 
of the resolutions agreed tc at its establishment, as given in 
the Annals for Nov. and was very numerously and respectably 
attended. 

Dr. Birkbeck having been called to the chair, the business of 
the evening commenced by the admission of a number of new 
members, among whom were W, Allen, Esq. FRS.; W. H. Pepys, 
Esq. FRS. ; B. C. Brodie, Esq. FRS.; H. T. Dela Beche, Esq. 
FRS.; G. M. Paterson, MD. M. Asiat. Soc. Calcutta, Xe. 

The Society then proceeded to the election of a Council and 
Officers ; when the following gentlemen were appointed :— 

Council.—John Bostock, MD. FRS.; Thomas Forster, MB. 
FLS. ; William Shearman, MD.; C. J. Roberts, MD.; Luke 
Howard, Esq. FRS.;, J. F. Daniell, Esq. FRS.; Richard Tay- 
lor,. Esq. FLS.; E. W. Brayley, Jun. Esq. 

President.—George Birkbeck, MD. M. Ast. Soc. MGS. &c. 

Treasurer.—Henry Clutterbuck, MD. 

A provisional draught of regulations for the government of the 
Society having been read, it was referred to a committee for 
revision, and the Society then adjourned. 

On the 14th of Jan. 1824, a third general meeting took place, 
at which the Code of Regulations, as revised by the committee, 
was adopted by the Society; and the meeting being then 
resolved into an ordinary one, a Report from a Committee 
was read, on the objects to which the attention of the 
Society should primarily be directed ; together with a paper on 
the Vernal Winds, by John Gough, Esq. of Kendal, and several 
other communications ; all which we hope to notice more parti- 
cularly in our next. 


Articte XXI. 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS 
CONNECTED WITH SCIENCE. 


I. Dark and bright Lines traversing the Spectrum. 


To the Editor of the Annals of Philosophy. 
SIR, } is Aid Jan. 14, 1824, 
In your number for August, 1822, ashort notice appears respecting 
the prismatic experiments of M. Frauenhofer, a full account of which 
is given in the Edinburgh Philosophical Journal, No. 18, p. 288, and 
continued in the subsequent number. You will, perhaps, allow me to 
trespass upon a small space in the next number of the Annals in order 
to make a remark relative to the subject of the papers alluded to, 


1824.] Scientific Intelligence: 155 
which I am induced to do from not finding it done from higher quar- 
ters. The observation I wish to make is this, that although we must 
allow M. Frauenhofer full credit for having first minutely described the 
position of various dark and bright lines traversing the spectrum, and 
having employed them as definite points for measuring the dispersion, 
yet the, fact ot the existence of such lines has been for some years known, 
though not, perhaps, so generally as it deserves tobe. I beg to refer 
such of your readers as may not be acquainted with it, to a paper by 
Dr. Wollaston in the Phil. Trans. for 1802, p. 378, in which the exist- 
ence of such lines under particular circumstances is described as 
observed by the author. Another observation connected with the 
same phenomena will be found in p. 380 ofthe same paper ; and in the 
same volume, p. 395, in a paper by Dr. Young, an important observa- 
tion is made, bearing on the theory of the phenomena. 
I am, yours, &c. B. P. 


IL. Analysis of Cleavelandite from Finland. 
M. F. Tengstrom finds this substance to be composed of 


SAME oes Wane Wales ¢ oo et tie hes « 67:99 
| Mae a A aL 19°61 
Sod deereecnes oe eeweweee enewwe AL12 
alter ai lea ek ys the ee sictetelonwiate? OSG 
Oxide of manganese. .... Ba Sa 0°47 
Oxide of iron,..... a -HYRAS oe 0:23 
100°08 


III. Copper Pyrites of Orijarva. 


M. V. Hartwall, of Abo, has analyzed the copper pyrites of Orijarva, 
with the following results : 


STAIR Id 4 in ies <iohnd otbi Hale ities , 36°93 
Copper. .... a inate Mathie Diere +. 32:20 
TOM ektedd.* Us .corltsnh.. a »--» 30°03 
SMe. alsa lt dax ke. ieike yituin sxee 0°93 
Oxide of mang. and earthy matter. 1°30 

10079 


The author of this analysis remarks, that its results nearly agree with 
those given of the copper pyrites of Cornwall, given in the Annals, 
vol, iii. N. S. p. 300. 

IV. Scapolite from Pargas. 


The last named chemist has also given an analysis of a new species of 
scapolite from Pargas: it consists of 


epee 2 OU, ties A secccces 49°42 
Plea re Es eS 25°41 
Page 28S 5, Are 6 Bicy ipiem enced 15°59 
Soda. ...... a ie 6°05 
Oxide of iron... ..., eovsesvee, B40 
Magnesia. .... oes OLAS ovsee O68 
Oxide of manganese. .......... 0°07 


Loon by heave) | Oy 145 


156 New Scientifie Books. {Fes. 


VII. Manufacture of Pianoforte Wire. 
(To the Editor of the Annals of Philosophy.) 


SIR, London, Oct. 8, 1823. 
I should feel much obliged to you, or any of your correspondents, 
for the communication of any particulars respecting the manufacture 
of pianoforte wire, and the cause of the very decided superiority of 
what is called Berlin steel wire over all that is made in England. Have 
any of the new alloys of steel and silver, &c. or has Mr. Brookedon’s 
method of drawing through conical holes made in diamonds, rubies, 
sapphires, or other hard stones, been tried, to make pianoforte wire ? 
Considering the great quantity and value of the wire used in musical 
instruments, made in the greatest perfection in this country, it is to be 
lamented that our wire-drawers suffer themselves to be excelled by 
foreigners, 
What mode of whitening brass wire will best preserve it from oxi- 
dizement, and least injure its elasticity ? 
I am, Sir, your constant reader, M. A. 


ArTIcLE XXII. 
NEW SCIENTIFIC BOOKS. 


PREPARING FOR PUBLICATION, 


Dr: Uwins will shortly publish a Compendium of Medical Theory 
and Practice, founded on Cullen’s Nosology. 12mo. 

Thomas Sandwith, Esq. has in the press an Introduction to Anatomy 
and Physiology; in a-duodecimo volume. 

~ James Buckingham, Esq. Author of ‘ Travels in Palestine,’ will 

shortly publish * Travels among the Arab Tribes inhabiting the Coun- 
tries East of Syria.’ ‘ 

An Account of the Life and Writings of the late Thomas Brown, 
MD. Professor of Moral Philosophy, Edinburgh; by the Rev, David 
Welsh. 


JUST PUBLISHED. 


The Westminster Review, No. I. 6s. 

A second edition of Mr. Tredgold's Essay on the Strength of Cast 
Tron and other Metals, much augmented, particularly in the Experi- 
mental Parts, and the Illustration of the Application by popular 
Examples. 

Pathological Observations ; Part I-—On Dropsy, Purpura, and the 
Influenza of the latter end of the year 1822, and beginning of 1823, 
&c. By W. Stoker, MD. Senior Physician to the Fever Hospital, 
Dublin, 8vo. 8s. 

Edinburgh Medical and Surgical Journal. No, I. New Series. 
8vo. 6s. 

An Essay on the Inventions and Customs of Ancient and Modern 
Nations in the Use of Wine and other Liquors; with an Historical 
View of the Practice of Distillation, By Sam, Morewood. 8vo, 12s. 


1824.] New Patents. 157 


The Encyclopedia Metropolitana, Part XI. containing Magnetism 
and Electro-Magnetism, &c. 1/. Is. i 

A Tour through the Upper Provinces of Hindostan, between the 
years 1804 and 1814; with Remarks and authentic Anecdotes; to 
which is annexed a Guide up the River Ganges: with a Map of the 
Ganges. 8vo. 9s. 

A new Edition of Prof. Buckland’s Reliquie Diluviane, attesting 
the Action of a Universal Deluge: with 27 Plates. 4to. 1/. lls. 6d. 


ArticLe XXIII. 
NEW PATENTS. 


T. Hopper, Esq. Reading, Berkshire, for certain improvements in 
the manufacture of silk hats.—Nov. 20. 

C. A. Deane, Charles-street, Deptford, Kent, ship-caulker, for his 
apparatus or machine to be worn by persons entering rooms or other 
places filled with smoke or other vapour, for the purpose of extinguish- 
ing fire, or extricating persons or property therein.—Nov. 20. 

J. Perkins, Hill-street, London, and J. Martineau the younger, City 
Road, Middlesex, engineers, for their improvement in the construction 
of the furnace of steam-boilers and other vessels, by which fuel is eco- 
nomized, and the smoke is consumed.—Nov. 20. 

J. Bourne, Denby, Derbyshire, stone-bottle manufacturer, for cer- 
tain improvements in the burning of stone and brown ware in kilns or 
ovens, by carrying up the heat and flame from the furnace or fire below 
to the middle and upper parts of the kiln or oven, either by means of 
flues or chimneys in the sides thereof, or by moveable pipes or conduc- 
tors to be placed within such kilns or ovens; also by conveying the 
flame of one kiln more into others by means of chimneys, and thus per- 
mitting the draft and smoke of several kilns or ovens to escape, where- 
by the heat is increased, and the smoke diminished.— Nov. 22. 

J. Slater, Saddleworth, Yorkshire, clothier, for improvements in the 
machinery to facilitate the operation of cutting or grinding wool or 
cotton from off the surfaces of woollen cloths, kerseymeres, cotton 
cloths, or mixtures of the said substances, and for taking or removing 
hair or fur from skins.— Noy. 22. 

T. Todd, Swansea, South Wales, organ-builder, for his improve- 
ment in producing tone upon musical instruments of various descrip- 
tions.— Nov. 22. 

S. Brown, Gent. Windmill-street, Lambeth, Surry, for his engine or 
instrument for effecting a vacuum, and thus producing powers by which 
water may be raised and machinery put in motion.—Dec. 4. 

A. Buchanan, Catrine Cotton Works, for a certain improvement in 
machinery heretofore employed in spinning-mills in the carding of cot- 
ton and other wool, whereby the top cards are regularly stripped-and 
kept clean by the operation of the machinery without the agency of 
hard labour.—Dec. 4. 


J. Parkes, Manchester, civil engineer, for a certain method of manu- 
facturing salt.—Dec., 4. 


eee 


168 Mr. Howard’s Meteorological Journal. [Fes. 
ARTICLE XXIV. 
METEOROLOGICAL TABLE. 
—— 
BARoMETER,| THERMOMETER, 'Daniell’s hyg. 
1823. Wind. | Max.|Min.| Max. | Min. | Evap. |Rain.| at noon. 
12thMon. 
Dec. 11 W_ |29°90/29°69| 52 39 Bs ae 
S W429-69/29°69| 52 36 — 28 
31S W/29'69|29°45|. 54 39 — 10 
4| W_ {29°93/29°50| 47 30 — 
5| W_ |29°93|29°62| 46 32 — 41 
6|IN  E}30°59/29°93| 42 28 — 04 
71 W_ |30°59/30°55| 36 31 Sain 
8| W_ |30°55/30°46) 44 34 "32 
QIN W/)30°51|30°44|) 44 27 — 
10/S W/30°51/30'28) 44 29 —_ 
11/8 W/(30°28/29°97| 48 40 we 
12) W_ {30°03/29°91) 43 33 — 
13/N W/)30°34|30°03} 40 26 -- 
14|N W/30°33/30°29| 41 31 — 
15IN W/30°33/30°31} 44 31 —_ 
16'S  W/{30°31/29°82| 47 39 rr ie 
17/S.- #/29°82/29'10) 48 32 — 38 
18] W_ /|29°75|29°60|} 40 30 — 
19N W/29°75|/29°53| 36 26 "45 
20/S E)29°53/29-36]} 45 32 —_ 10 
21IN W/29:76/29°36} 50 | 36 —_ |— 
22IN W/\29'93/29'76] 45°] 30 —_ |— 
23/8 W/{30-07|29:93| 45 36 = 26 
24/8  W/30°10/30-07| 48 42 — 20 
25S W)30°10/29:97| 49 39 — 07 
26/5 W/{29:97|29°39) 46 39 —_ 10 
27/S ~~ W)29°62/29°39| 45 35 ~ 
2818 W'/29-62)29°37| 52 39 = 06 
29/S  ‘W!29°37|29°27| 46 39 a 06 
30/S  W/)29°58)\29°27| 45 38 ~~ “02 
31) W_ |29°65|29:46} 4G 38 *35 | 25 
$0°59/29'10| 54 26 1°12 | 2°33 


The observations in each line of the table apply to a period of twenty-four hours, 


beginning at 9 A.M. on the day indicated in the first column. 
_ the result is included in the next following observation. 


A dash denotes that 


aes 


1824.) Mr. Howard's Meteorological Journal. 159 


REMARKS. 


Twelfth Month.—1. Cloudy. 2. Rainy. 3. Cloudy and fine: a furious gale from 
the W all night. 4. Fine: wind still very high. 5. Foggy morning: cloudy. 
6. Rainy morning: cloudy, 7. Foggy. 8. Foggy morning: fine. 9, Fine. 
10. Cloudy. 11, 12. Fine. 13, Fine: bleak. 14. Fine clear morning: day very 
fine: evening foggy. 15. Very fine. 16. Overcast. 17. Rainy: a strong gale of 
wind in the evening, accompanied by an uncommonly rapid depression of the barometer, 
18. Fine. 19. Foggy: gloomy. 20. Overcast: drizzling. 21. Foggy morming | 
afternoon fine. 22. Gloomy, 23, 24. Rainy: gloomy. 25. Drizzling. 26. Gloomy . 
27, Fine. 28. Drizzling: night stormy. 29. Fine: some rain at night. 30, Cloudy 
and fine, 31, Fine day: night windy, with rain. 


RESULTS. 


Winds: NE, 1; SE,2; SW, 13; W,8; NW, 7. 


Barometer: Mean height 
For the month. ....2.sseccecceccccsceesccecsecses» 29'885 inches. 
For the lunar period, ending the 24th.........+.0.- 
For 15 days, ending the 10th (moon south) .. ........ 
For 13 days, ending the 23d (moon north) .. .....++s 


Thermometer: Mean height 
For the month. . . ..'..+s0sqsieies snpniesiny ¥0.0piep inne bh SO7BREP 
For the lunar period. ...... as signi ve 2 et sveccccccccce 


For 30 days, the sun in Sagittarius. ...s.eesseeeeeee 
MII: silva sedcec gecesi cosercs 


eco ccccccccescccecrvecccooccs 1°12 in. 


Rain. PPO SOCAN OR DoS ep eae dinvescepdeeertcasadebioocessescoepeense Be 


Laboratory, Stratford, First Month, 22, 1824. R. HOWARN, 


160 Mr. Hoivard’s Meteorological Journal.. (Fen, 1824, 


Note.—Some doubt having arisen as to the accuracy ‘of the high mean lately assigned 
to the barometrical observations in this Register, we have thought it needful to verify the 
actual height of the barometer employed, by comparison with a good standard. 

On the I6th inst. at three, p.m. I suspended by the side of the barometer in question, 
the one belonging to my friend J. F. Daniell, described in page 358 of his ‘* Meteoro- 
logical Essays,”” and which he considers (with due allowance for the depression of the 
column, caused by the smaller diameter of the tube) to agree with the excellent standard 
barometer, lately constructed under his direction for the Royal Society. ‘The result was 
very Satisfactory: the mountain barometer, and that employed for this Register, stood 


respectively at 30°66 in. ; nor could a difference of 1-100th of an inch be found between 


them, by either of two observers, who examined them at intervals during a full hour. 


The temperature of each was 55°: the inner diameter of the mountain barometer (the 
quicksilver of which has been boiled in the tube), is O'15 in. :. the inner diameter of the 
wheel barometer, as nearly as could be ascertained, 0°23 in. The quicksilver has not 
been boiled in this instrument. The barometer was very nearly stationary on the 16th, 
from noon to midnight. 4 

In a comparison made this day, for an hour before noon, in the lower part of the scale, 


the instruments at the conclusion stood thus, at temp. 58°, 


The siphon barometer ........sceeeeeeceee LO'94 


‘The mountain ditto........-ceececeeee% .. 28895 
Difference.......:.- ‘045 


The correction for the capacity of the cistern in the mountain barometer being applied 
reduces the difference in the present case to ‘014, and crcates a difference in the former 
of ‘O11 in. both in excess on the part of the siphon barometer. The corrections for tem- 
perature and capliey depression cannot here be so accurately applied, on account of the 
different constnteton of the two instruments, On the whole, there appears no ground 


to disturb the tA stinient of our own barometer, 


er ph Pe 


Tottenkim, Fivst'Month, 23, 1824. ; ee Ee An 


. 


<= 


gt tee ge re 


¥ 


ANNALS 


OF 


PHILOSOPHY. 


—s 


MARCH, 1824, 


ARTICLE J, 


On the Crystalline Forms of Artificial Salts, 
By H.J. Brooke, Esq. FRS. 
(Continued from p. 117.) 
Tartrate of Potash. 
Tue primary form is a right oblique 
angled prism, with cleavages parallel to 
the lateral planes. 


maron Fes OR ey 80° 30’ 


Ome. ... me eaten oe 142° 13 
MOS Sac ok oak 107 30 
NTE ig he's Sis Mes Ses P27. 7 
Ms Sn ies Paces 103 40 


Bitartrate of Potash. 
It has been already observed by Dr. Wollaston, that the 
cleavages of the crystals of this salt are parallel to the lateral 
lanes and diagonals of either a rectangular or a rhombic prism. 
rom the figures and measurement of seve- 
ral crystals, I am inducedto adopt the right 
rhombic prism as the primary form. ‘The 
annexed figure represents the planes which 
occur on many of the crystals placed symme- 
trically in relation to the primary planes. 


OE ae ae IYO WAGERS TO Ne 
OO Se 126.),25 
EN SE a neg tvs .2 
SS ae Tore 125 30 
0 ES ee 109 +O 
NM 5 sie s bunched s APE 63 i 


162 On the Crystalline Forms of Artificial Salis. [Marcn, 


There is a bright cleavage parallel to the edge between M and 
M’ and perpendicular to h, and consequently parallel to the great 
diagonals of the primary terminal planes. The crystals may be 
also cleaved parallel to A, and to M and M’. The figure, it has 
been observed, is symmetrically drawn, but the crystals are 
frequently much distorted by the disproportionate extension of 
some planes and the disappearance of others; so that it is not 
always easy to compare them with any general type of the 
whole. We may, however, be much assisted in this comparison 
by the character of the plane /, which, in all the crystals I have 
seen, is striated, as shown in the figure. By the assistance of 
this plane, and the bright cleavage plane perpendicular to it, and 
by measurement, we may be enabled to compare the crystals 
with the engraved figure, however irregularly formed they may 
be. On very many of them the planes ) and b’” are so much 
enlarged as nearly, if not eutirely, to exclude the other four 
planes which appear in front of the figure; while at the back, 
the planes parallel to 0’ and b” are similarly enlarged. If these 
four planes were so much extended as to exclude all the others 
which appear on the figure, an irregular tetrahedron would 
result. 

On some crystals there is one and sometimes two planes 
replacing the edge between ’ and M, one of them measuring 
with h about 156°, and the other about 1454°, 


Nitrate of Silver. 


Primary form a right rhombic prism. 


PURGE cbMisssckecs. S20 "oe 
WOE Se eadeca cy ERO > 
DED ML cok cseraas tad ae 
UM he wanes veanca 160) ae 


On some crystals received from Mr. 
Teschemacher the planes d were barely 
visible ; while on others from Mr. Cooper, 
those planes encroached so much on M 
and M’ as to leave only minute portions 
of these visible. 


Be 


1824,] Variation of the Horizontal and Dipping Needles. 168 


Artic.e II. 


Observations and Experiments on the daily Variation of the 
Horizontal and Dipping Needles under a reduced directive 
Power. By Peter Barlow, Esq. FRS. of the Royal Military 
Academy.* : 


Ir is now just a century since Mr. Graham discovered the 
daily change in the variation of the horizontal needle, subsequent 
to which time numerous observations have been made on the 
same subject by Wargentin, Canton, Gilpin, Col. Beaufoy, and 
others, which have all confirmed, with certain shades of variety, 
the general fact as first described by the ingenious philosopher 
above named. 

The actual daily change, however, is so small, even in the 
horizontal needle, that it can only be detected with the most 
careful observations and with the most delicate instruments ; 
and in the dipping needle that change, if any, is so extremely 
minute, as hitherto to have escaped observation ; for it was only 
in the year 1820, that the Royal Academy of Sciences of Copen- 
hagen proposed the determination of this motion, on satisfacto 
experiments, as the prize subject for that year ; but the prize, 
understand, has never been adjudged, no satisfactory communi- 
cation having been received. 

Under this difficulty of observation, it occurred to me, that it 
would be possible to increase this deviation on both needles, so 
as to render it distinctly observable, by reducing the directive 
power of the needle by means of one or two magnets, properly 
disposed to mask, at least in part, the terrestrial influence ; a 
method which has been long practised by mineralogists and 
others, when the object has been to detect minute attractions 
{ expected by this means that the cause, whatever it might be, 
that produces the daily variation, would exhibit itself in an 
increased degree, and thereby render the results more perspicu- 
ous, and fix with more precision than has hitherto been done, the 
time of change and moment of maximum effect. 

Suppose, for example, that a finely suspended horizontal 
needle, under the natural influence of the earth, makes one 
vibration in 2”, and that by masking the terrestrial influence by 
magnets properly adjusted, that time of vibration is increased to 
8”; then it would follow that the directive power was reduced to 
one-sixteenth of the former, and consequently, that any lateral 
magnetic force acting upon the needle would produce an effect 
sixteen times greater than before; so that if the former were 
12’, the new effect or deviation might be expected to amount ta 


* Abstracted from the Phil. Trans. for 1823, Part II, 
M 2 


164 - Mr. Barlow on the daily Variation of the [Manrcu} 


between three and four degrees, and therefore be such as to 
admit of distinct and satisfactory observation. 

A course of experiments carried on for a few days, convinced 
me that my ideas were correct, and that we might, while the 
needle was kept inits natural meridian, or rather adjusted to that 
direction, produce a daily variation to almost any amount. I 
obtained, for instance, the first day, a maximum deviation of 
3° 40’; the second, I increased it by bringing up my magnets 
to 7°; the third day I reduced it to 2°, and soon. I found also 
that a very considerable daily change would exhibit itself with 
the north end held to the south, to the east, west, and, in short, 
in any position at pleasure, at least within certain limits, which 
will be pointed out as we proceed. 

For this it is only necessary, first, to deflect the needle by 
repulsion into any required position, and then, by means of 
another magnet, to modify its directive power, in the same way 
as when in its natural meridian. Or the same may be done by 
bringing two magnets with their contrary poles pointing inwards, 
and each opposite to the pole of the same name of the needle 
placed between them, and by a slight adjustment of the former 
to produce the deviation in question ; or, which is perhaps still 
better, the opposing magnets may be brought into the actual 
direction of the dip, and then adjusted to produce the deflection 
required. 

Having mentioned my ideas and first experiments to my 
colleague, Mr, Christie, and having expressed a wish that he 
would repeat them for the sake of verification, he very readily 
agreed to undertake a complete set, with the needle in its natu- 
ral meridian, by means of a very delicate compass, and an appa- 
ratus he had employed for other experiments, and which admitted 
of his bringing his neutralizing magnets very exactly into the 
line of the dip. In the mean time I proposed to undertake the 
observations on the dipping needle, and on the horizontal needle 
in different directions ; viz. with its north end pointing to the 
south, east, west, &c. Having, however, met with some embar- 
rassment in the commencement, and having employed, in con- 
sequence, a longer time in the observations than [ had antici- 
pated, Mr. Christie, after having finished his observation in the 
meridian, continued them at other points, and has thereby 
detected several curious and minute peculiarities, which, with his 
other experiments, will, | hope, accompany this memoir.* 


Account of the Observations made on the daily Variation of the 
Horizontal Needle in various Directions. 


My first experiments, as I have already stated, were only 
matters of trial, from which | had merely ascertained that the 


* Mr. Christie has detailed his experiments in an extended paper, which succeeds 
Mr. Barlow’s present communication in the Phil. Trans. 


1824.] Horizontal and Dipping Needles. 165 


idea I had formed was practicable, and that in certain situations 
the needle had certain directions of motion, but I had obtained 
no numerical results. Having, however, provided myself with a 
needle proper for the purpose, very delicate and light, and eight 
inches and a half in length, I began, towards the end of March, 
to register the amount of the daily change at every hour, or half 
hour, from morning to night; my son taking the observations 
during my occasional absence. 

My first observation in the new series was made with the 
north end of the needle pointing to the west, balanced in that 
position with two magnets placed to the southward attracting 
each exiremity ; the directive power was considerably reduced, 
and I obtained a maximum deviation of 3°15’; which happened 
at about eleven o’clock in the forenoon, and from which time the 
variation decreased to a late hour in the evening. The needle 
was kept in this position for three days, with some change of 
directive power, but the character of the results, as to the direc- 
tion of motion, the times of commencement and maximum, &c. 
were of precisely the same nature, but the amount was more or 
less, according to the directive power left upon the needle. 

Having, however, after a few days, removed my apparatus from 
the room in which the experiments had hitherto been made, into 
a bower in my garden, and having detected a remarkable differ- 
ence in the results obtained in these two situations, [ determined 
to commence the experiments de novo in this latter spot, which 
was at least thirty yards distant from any building ; and after- 
wards to examine the cause of the difference in question. This 
examination is reported in the conclusion of this article. 

(Mr. Barlow here gives a series of tables of observed daily 
variations, with the north end of the needle directed to the fol- 
lowing points of the compass respectively :—north, south, 
north-east, south-west, east, west, south-east, north-west, north 
north-east, south-south-west, east-north-east, west-south-west, 
east-south-east, west-north-west, south-south-east 1 south, (ex- 
act bearing N. 16° W. and 8. 16° E.) and north-north-west.] 

From the above results, although the experiments were not made 
under such favourable circumstances as I could wish, we may 
draw some very curious, if not important conclusions ; such, for in- 
stance, as the following. That while the north end of the needle 
is directed to any point from the south to NNW, its motion during 
the forenoon is towards the left hand (the spectator facing the 
north end of the needle) ; advancing therefore to some point be- 
tween the NNW and north; and while it is directed towards any 
point between the north and SSEit passes to the right hand, thatis 
still to some point between the north and NN W;; the south end of 
the needle at the same time passing of course to some point be- 
tween the south and SSE; so that it would seem that there ought 
to be some direction between those limits, viz. between the N and 
NNW, and the S and SSE, in which the daily motion is zero, or 


166 Mr. Barlow on the daily Variation of the (Marci, 


at least a minimum; but whether this is a fixed direction during 
the year, or whether it has any vibratory motion as the sun 
changes its declination, or even during his daily course, is a 
question which cannot be decided without a much longer course 
of experiments than those I have here the honour to present. 

It is also questionable, whether the direction of this line of 
no daily variation is the same in different parts of the world; a 
point on which I hope to obtain some information in the course 
of the present year. Mr. Forster,* of H. M.S. Griper, having 
very obligingly undertaken to repeat my experiments at Spitzber- 
gen, during the stay of the vessel at that place for the pendulum 
experiments ; and from which we may hope to derive some inte- 
resting deductions, particularly in reference to the influence of 
the direction of the solar rays; for it is clear from the experi- 
ments reported in the preceding table, that the amount of the 
deviation does not entirely depend upon the moment when the 
heat of the sun is the greatest, as has been generally imagined ; 
for the time of the maximum deviation varies from eleven 
o’clock in the morning to four o’clock in the afternoon, accord- 
ing to the direction in which the needle is pointed, and to other 
circumstances that will be mentioned in the conclusion of this 
article. Mr. Christie’s observations are also of a kind to throw 
great light on this subject. 

Another conclusion, which I think we are justified in drawing 
from the above experiments, is, that the daily change is not 
produced by a general deflection of the directive power of the 
earth, but by an increase and decrease of attraction of sonte 
point situated between the north and NNW, or between the south 
and SSE; for 1 cannot conceive any other hypotheses that will 
account for two needles, situated as in these experiments, both 
approaching and both receding at the same time to and from the 
line of no daily variation ; nor for the total suspension or equi- 
vocal vibratory motion of a needle when placed towards this 
direction. 

I am sorry, that not foreseeing at the commencement of my. 
experiments, the leagth to which I should carry them, I did not, 
from the first, register the temperature and state of the atmo- 
sphere; for from certain notes of this kind made lately, it 
appears to me that the quantity of daily change depends ina 
greater degree on the intensity of the solar light, than on the 
mere temperature of the day; although it is certain, from some 
recent experiments by Mr. Christie, that the change of tempera- 


* I am already highly indebted to this gentleman for the accurate and satisfactory 
observations he made during the recent voyage of H. M. S. Conway, under the com- 
mand of Capt. Basil Hall, on the method I had the honour to propose for correcting the 
local attraction of vessels; and it is with great pleasure that I find he has been directed: 
by the Admiralty to continue his attention to them in the present voyage of the Griper. 
My best thanks are also due to Capt. Hall, for the facilities he afforded in the instance 
abovementioned, and for the judgment with which he selected the most appropriate 
situations for submitting that method to the test of actual experiment. 


1824.] Horizontal and Dipping Needles. 167 


ture of the air, during the day, has a much greater effect upon 
the intensity of action in the opposing magnets, than I could 
possibly have imagined. 


On the daily Variation of the Dipping Needle. 


Notwithstanding my observations on the daily change of this 
instrument have not been so successful as those on the horizon- 
tal needle, yet it will be proper to say a few words on the sub- 
ject of the experiments, although I do not intend, in the present 
instance, to give any numerical results ; those I have obtained 
not being so uniform as I could wish, nor such as to justify their 
publication. 

The instrument I employed was made by Messrs. W. and T. 
Gilbert : it was remarkably free and accurate, and certainly gave 
results with greater uniformity than any dipping needle I ever 
used. The needle was only six inches in length, a quarter of an - 
inch broad, and very thin; it performed in the meridian forty- 
one vibrations in one hundred seconds, when under the usual 
terrestrial influence ; and when masked and adjusted by two . 
magnets placed in the line of the dip, it made only fifteen vibra- 
‘tions and a half in the same time; the power was therefore 
reduced about eight times. 

It is not necessary to explain here the means that I employed, 
and the precautions I took to ensure stability; it will be suffi- 
cient to observe, that 1 paid the utmost attention to this essen- 
tial condition, and that ivbaliges my want of success did not 
arise from any defect in this part of the process, but from the 
extreme delicacy of this instrument, and the consequent diffi- 
culty in adjusting it when under the influence of the neutralizing 
magnets. I tried its action for three weeks in the house, . but 
the jarring of doors and other circumstances prevented me from 
drawing any conclusions. I then removed it to the garden, to 
a spot well protected by trees and shrubs, and fixed the entire 
apparatus to my garden wall, which is exactly in the magnetic 
meridian; and further sheltered the whole in the best way I 
could from the effects of the wind and weather. Indeed the 
only inconvenience was that I could not leave the needle out in 
the night, and could therefore only notice what took place in the 
day time, and this, as I have said above, was not so uniform as I 
could have desired. 

In general a motion commenced soon after the instrument 
was adjusted in the morning; but it was not of that gradual and 
progressive kind which indicated an uniformly increasing or 
decreasing power, as in the other instrument; it passed, for 
instance, suddenly from one half or quarter degree, to another 
more or less, and which sometimes in the course of the day 
would give a difference in the dip to the amount of a degree and 
a half, or even more, but | seldom saw in it a tendency to 


168 Mr. Barlow on the daily Variation of the [MArcn, 
return ; although when I vibrated it towards night, it commonly 


took up its morning position. I made these observations with 


the needle in various directions, viz. with the face of the instru- 
ment to the east, west, north, south, &c. but in every case I 
obtained the same sort of daily motion. The question, there- 
fore, respecting the law of variation of this instrument, still 
remains to be submitted to fixed principles, although there can 
be no longer any doubt that it is subject toa daily change. 


On a curious Anomaly observed between the daily Variations in- 
doors and in the open Air. 


I have already mentioned that I was, at the commencement 
of my experiments, a good deal embarrassed and delayed by 
certain anomalies which I noticed between the daily changes of 
the needle made in the house and in the garden. These may be 
stated shortly as follows. That in certain positions of the needle 
towards the east and west, the daily motion, although it pro- 
ceeded with the same determinate uniformity in both cases, yet 
it took place in different directions ; passing in the one instance 
from the east, or west, towards the south, and in the other 
towards the north, at the same corresponding hours of the day, 
the motion in both instances being equally distinct, regular, and 
progressive. : 

After carefully examining every circumstance that might be 
supposed to be the cause of this singular change, I could only 
imagine three, that seemed in any way likely to account for it, 

1. Were the two magnets and the compass needle in the two 
cases in precisely the same relative situation ; and if not, might 
not the cause lie in this discrepancy ? 

2. The window of the room was to the northward ; was it 
possible that the light, arriving at the needle in this direction, 
was the cause of the change? 

3. There was an iron stove in the room; could it be that this 
was subject to a periodic increase and decrease of magnetic 
power? 

In order to examine the first of these cases, I measured very 
carefully the distance, direction, Kc. of the compass and mag- 
nets while in the garden, and placed them in precisely the same 
relative situation in the parlour ; still the motion im the two cases 
was reversed. 

To examine the second, it occurred to me that if the direction 
of the motion depended upon that of the light, the needle ought 
to be wholly stationary in the dark, or when excluded from the 
solar rays. I therefore kept my room shut for two days, and 
only examined the needle by the light of a wax taper; but 
although there was certainly less motion on those days than 
usual, yet I could come to no satisfactory conclusion ; but I 
still think that further observations will show that the solar 


Oh Pa, he 


1824.] Horizontal and Dipping Needles. 169 


light,* and not the solar heat, is the principal operative agent in 
producing the daily variation. It remained, however, to examine 
the third query, which I attempted to do as follows. Having 
placed the compass in its former situation in the garden, I fixed 
on one side of it a ten inch howitzer shell, in the same direction 
with respect to the compass as the stove had in the parlour, and 
at such a distance that it might produce a sensible deviation in 
the needle, and which I afterwards adjusted to zero by a slight 
change in the position of the magnets, thus placing the needle, 
as I imagined, under similar circumstances in both cases, with 
respect to local attraction; but, notwithstanding | did in this 
way actually produce an alteration in the daily motion, changing 
its maximum from eleven o’clock in the morning to about four 
o’clock in the afternoon, yet the direction of the motion was the 
reverse of what it was constantly found to be in-doors; the 
cause therefore of this perplexing anomaly still remains to be 
discovered. , 

It is proper to observe that Mr. Christie, having made some 
of his observations in-doors, and some in his garden, on two 
compasses at the same time, found the same reversion of motion 
in the two cases. His house is a mile distant from mine; he 
has no stove in the room in which the in-door experiments were 
made; and the only resemblance of situation is, that his window, 
like mine, is towards the north. It should be further added, 
that this confirmation of the singular anomaly in question did 
not arise from his simply repeating my experiment, but grew 
naturally out of the particular mode he had adopted to prose- 
cute the inquiry ; our experiments, with the exception of the 
first suggestion, are independent, and, therefore, where they 
both lead to the same result, they may be considered as con- 
firming the accuracy of each; and where there is any difference, 
they will at least point out those circumstances which require 
further investigation. 


P. 8. The experiments to which I have alluded in p. 166—167, 
made since this article was written, seem to indicate that this 
anomaly, as well as the circumstance there mentioned, may be 
occasioned by the daily varying intensity of the opposing magnets. 


* I am sorry I have not the necessary apparatus for repeating Morichini’s experi- 
ment on the violet ray ; but I would suggest to those who have, that the finest test to 
which this experiment could be submitted, would be to make use ofa needle neutralized 
as above described, by which the magnetic property of the ray, if it possessed any, 
could not fail of showing itself. 


170 Mr. Cooper on an Improved Apparatus for [Marcn, 


ArTIc.eE III. 


On an Improved Apparatus for the Analysis of Organic Products. 
By Mr. J.T. Cooper.* (With a Plate.) 


AN easy and accurate method of determining the ultimate 
elements of bodies composed of carbon, hydrogen, oxygen, and 
azote, has been of late years a great desideratum among chemists, 
as such a variety of contrivances have been suggested by scien- 
tific individuals, all of which have their peculiar merits and 
defects. It is presumed the instrument and method of operat- 
ing now presented to the Society and the public, if not entirely, 
may be considered as nearly free from those objections which, in 
my opinion, may be fairly urged against those heretofore in use. 
It might, however, be considered ungenerous, was I to take upon 
me the task of pointing out those defects, I shall therefore con- 
tent myself by briefly stating in this communication, the class 
of substances to which it is applicable with a view to determin- 
ing the proportions of their elements, and a description of the 
method of operating upon each of them. 

As this apparatus seems more particularly calculated than any 
other for operating on volatile matter, such as the essential oils, 
camphor, benzoic acid, and a variety of similar substances, I 
shall in the first place describe the method I have adopted in the 
analysis of this class of bodies ; and when it is considered that 
I write not for those who are accustomed to the more minute and 
delicate operations of chemical analysis, but for those who are 
or may be considered as unacquainted for the most part with 
this subject, I hope I may not be considered as tedious should I 
venture to give those directions which to the more matured in 
science may seem to be unnecessary. 

The oxide of copper used in the experiments is best procured 
from the residuum of verdigris (binacetate of copper), which is 
or was used to be distilled in glass retorts for the preparation of 
strong acetic acid. The reason I prefer the oxide of copper 
prepared by this process over any other is, that it is more likely 
to be free from impurity than that which is prepared by precipi- 
tation from acid solutions. Every one who is in the habit of 
preparing precipitates knows the difficulty there generally is in 
freeing considerable quantities of precipitated matter from adher- 
ing neutral salts; and as the smallest impurity would in some 
measure contaminate the result of the analysis, it is a very 
necessary precaution that the oxide, which is by far the greatest 
in quantity of any substance that is employed in the operation, 
should be perfectly pure. Should it however happen that at any 


* From the Transactions of the Society for the Encouragement of Arts, Manu- 
factures, &c. Vol. 41, 


1824.] the Analysis of Organic Products. 171 


time such an oxide is not readily to be procured, the oxide that 
is obtained by heating copper plate and quenching it in water 
may be substituted ; although I give the decided preference to 
the former on account of its mechanical texture being much 
more porous, and consequently exposing a larger surface to the 
action of substances in vapour passing through it; neither is it 
so likely to choak up the tube and endanger its bursting, and of 
course a failure in the experiment. Supposing the residuum 
above mentioned to be employed, it is requisite to expose it to a 
red heat fortwenty minutes or half an hour to destroy the carbo- 
naceous matier that invariably accompanies it; it should then 
be pulverised and sifted through a fine wire sieve; that portion 
which has passed the sieve being again sifted through a fine 
cyprus or lawn sieve, the finer dust is got rid of, and each of 
these portions may be separately kept, and is applicable to dif- 
ferent purposes. 

A tube of hard glass, either of crown or green bottle glass, 
being selected about 14 or 15 inches long, and from one to two- 
tenths of an inch internal diameter, clean the inside from dust 
by passing through it a piece of cotton, then make. it as hot 
from end to end as the fingers can conveniently bear, and draw 
air through it into the mouth (but not blow through it) while it 
is still hot, to ensure its perfect freedom from adhering moisture 
on its inside, and while still warm seal up one end with the 
blowpipe ; the tube may be now balanced, but it is necessary 
in this, as in all other operations of analysis where very small 
quantities are concerned, that the beam should be affected by 
1-200 or 1-300 of a grain, even when loaded with 400 or 500 
grains at each end.* The substance intended for analysis is 
now to be introduced into the tube ; if it be solid, as for instance 
camphor or a like substance, it may be broken into small frag- 
ments and shaken down to the bottom; if it be a fluid, asa 
volatile or fixed oil, it may be introduced by means of a small 
funnel, as is shown in fig. 7 (Plate XX VII), which funnel is pre- 
pared, on the instant, from a piece of flint glass tube of conve- 
nient size and substance by heating it near one of its extremities, 
and suddenly drawing it out; itis evident the semifluid glass will 
be thus elongated, and a funnel with nearly a-capillary tube and 
of any required length, may be thus obtained; a very little prac- 
tice will render this part of the business very easy to be accom- 
plished ; the funnel is to be put into the tube, reaching very 
near its bottom or sealed end, and the fluid matter introduced 
without soiling the upper part of it; care must also be taken on 
withdrawing the funnel, that no portion of the fluid is attached 
to its lower extremity, or otherwise this willhappen. The vola- 
tile substance, or that which is capable of being rendered so by 


* The balance I have been in the habit of using was made for me by Mr. Robinson, 
and is sensibly affected by 1-400th of a grain when loaded with 1000 grains at each 
end, ; 


172 Mr. Cooper on an Improved Apparatus for [Marcn, 
a red heat, being now introduced into the tube, its weight is to 
be very carefully taken, which, when done, the oxide of copper 
previously freed from its fine dust by the lawn or cyprus sieve,* 
and recently heated red hot, is to be poured into the tube while 
warm, to the length of eight or ten inches, having previously put 
into the tube as much only of perfectly cold oxide as will absorb 
the fluid portion of matter, and about a quarter of an inch above 
it, or to stand about the same height above the solid substance. 
Why I recommend the present proceeding is, that a small quan- 
tity of the cold oxide only is used to prevent the hot oxide from 
coming in contact with the volatile matter which might other- 
wise endanger the escape of a small portion from the tube, and 
of course would give erroneous results; and that portion of cold 
oxide, even if it be fully saturated with moisture, can contain 
such a very minute quantity of water as not to sensibly affect 
the accuracy of the analysis. Having proceeded thus far, a 
quantity of recently ignited asbestos, or spun glass (the former 
is best), is put into the tube, soas to occupy an inch or two, de- 
pending on the quantity of water that is expected to be formed; 
this must not be crammed, but put rather lightly into the tube. 
The tube is now to be bent as represented in fig. 1, and its 
weight may be again taken, but this is not absolutely requisite ; 
it is, however, well to do it. The tube is then to be covered 
with thin sheet copper, and placed between the forceps, as 
represented in the same figure, with its open extremity inserted 
under a jar in the ordinary mercurial pneumatic trough, or it 
may be connected with a gasometer of Mr. Pepys’s construction, 
which, when ten or twenty grains of a substance are employed, 
and the quantity of either carbon or azote it contains is consi- 
derable, is convenient. Small mercurial graduated jars may be 
used, even if very large quantities of gas are obtained, as the 
process of decomposition may at any time be stopped almost instan- 
taneously, | and the quantity contained in them being registered, 
they may be alternately filled with mercury and displaced by the 
gaseous products, as long as any comes over, reserving only the 
last portions for examination, of which a few cubic inches alone 
are requisite. ~ 

The lamps being trimmed with very short wicks are now to be 
lighted, lighting those first that are nearest the gasometer, and 
when the tube is red hot, the remaining ones may be set fire to 
in succession, until the whole length of tube that is filled with 
the oxide is red hot. One set of lamps fora tube, of the size [ 
have mentioned above, is generally sufficient, but should tubes 
be used of larger size, such as half an inch in diameter, both sets 
will then be required. In coating the tube with sheet copper 


* The finer portion is taken from the oxide to allow more freedom of passage for the 
vapour through it; in some cases the rush of gas is so sudden, was it not for this precau- 
tion, it would be likely to burst the tube. ‘ 

+ I consider this as one of the advantages of this apparatus. 


Se ee 


1824.] the Analysis of Organic Products. . 16 
care must be taken not to cover that part of it which contains 
the asbestos, otherwise the heat will be conducted by it to that 
portion of tube, and prevent the condensation of the vapour of 
water, which is very essential ; and in placing the tube between 
the forceps, it will be convenient to allow that part of it which 
contains the volatile matter to project beyond the forceps ; the 
heat that is conducted by the copper coating is generally enough 
to volatilize most substances. In the analysis of substances 
containing much hydrogen, and especially when ten or twelve 
grains of them are taken, it will be found convenient to attach 
to the tube a small bulb to contain the water that is generated : 
this is represented by fig. 6. I believe I have stated the whole 
that is necessary as respects the management and use of this 
apparatus as far as regards the decomposition of volatile sub- 
stances ; in the next place, I shall speak of its application to the 
decomposition of fixed substances, which after what has been 
said will require but very few words. 

If the substance be a vegetable salt, it must be freed from all 
extraneous moisture; this is best effected by suffering it to 
remain over an hygrometric substance in vacuo for some time, 

Those who have not the convenience of an air-pump, may 
content themselves by operating in this way, which, although 
not quite so elegant, answers the purpose extremely well. A 
wide-mouthed phial provided with an accurately-ground stopper 
being procured, select another and much smaller phial that will 
easily go into it, and allow the stopper of the larger one to close 
accurately ; it is as well to apply a little tallow to the stopper to 
ensure its more perfect fitting; strew on the bottom of the 
larger phial a quantity of chloride of calcium (dry muriate of 
lime), put into the smaller phial the substance in fine powder 
intended to be dried, and place this in the larger phial standing 
on the chloride; moisten a small piece of bibulous paper with 
alcohol, and put it into the larger phial, but not inside of the 
smaller one ; when thus arranged set fire to the moistened paper, 
and when it has burned a second or two put the stopper in its 
place; a very good vacuum is by this means formed, and the 
process of dessication goes on rapidly. I have repeatedly used 
this method, and found it succeed very well; I think equally so 
with that usually adopted by means of the air-pump ; although 
by some it may be ridiculed in these days of elegance and refine- 
ment. 

The substance in this state is to be mixed with a portion of 
the oxide recently ignited, but in this case suffered to cool, then 
as quickly as possible introduced into the tube. As much of 
the oxide may be used as would occupy an extent of tube equal 
in proportion to that shown in fig. 5; a quantity of oxide is then 
to be put upon the mixture, and over this it is sometimes well to 
put a small quantity of copper filings or scrapings ; upon these 
the asbestos is to be used as above, and the operation of igni- 


a 


174 Apparatus for the Analysis uf Organic Products. (Marcu, 


tion is to be conducted in a somewhat different manner to that 
last-mentioned. te. 

The lamps in this case are to be lighted at the extremity next 
the gasometer, and as soon as the-gas ceases to be liberated, the 
next in succession may be empJoyed, and so on to the end; but 
instead of suffering the whole of them to continue in flame, it is 
as well to extinguish a portion, and to suffer only about three or 
four to remain in operation at once, but taking care to ignite 
the whole extent of tube at the close of the process. The 
gaseous products being collected, and their bulk noticed, their 
analysis is to be conducted in the usual manner, taking care, 
however, in all instances, to observe the precise temperature of 
the gases, that their bulk, as also the quantity ofaqueous vapour 
they contain, may be estimated,* and either to equalize the 
internal and external surfaces of the mercury, or to calculate the 
volume of gas by the difference of mercurial levels, 


Description of the Plate. 


Fig. 1, aa and b b, two long spirit lamps, each having ten 
burners and wicks, the burners of each lamp sloping towards 
those of the other, as seen in the end view, fig. 2; they are 
placed in a tin tray, ¢ c, mounted on four feet ; this tray is pers 
forated in the middle the whole length of the lamps, and as wide 
as e ¢, fig. 2; the object in making the bumers sloping is, that 
they may clear the lamps and approach each other as near as 
requisite, and yet leave a clear current of air to the flames, and 
the tray is perforated and mounted on feet to admit this current. 

dd, ave springing wires placed at each end of the tray to 
receive the tube f f, which contains the substance to be analyzed, 
and to hold it over or between the two rows of flames; by press- 
ing the finger and thumb on the two shoulders, g g, fig. 2, the 
wires open to receive the tube, and close on letting go; and 
should the tube be shorter than the lamps, an additional support 
on a leaden foot, fig. 3, is placed through the opening e e of the 
tray to rise between the flames, and hold the end of the tube; 
the tubes are hermetically sealed at one end, and the materials 
then put in while the tube is straight; it is then bent at the 
other end to suit the mercurial trough. 

The tubes are coated with copper foil, wrapped spirally round 
them; if each succeeding fcld lie on half the other there will be 
a double coat of copper all the way ; if it lie on two-thirds, there 
will be three layers of copper, and so on; by which the glass 
tube is supported from bending when hot, and becomes very 
uniformly heated. The spirals are continued beyond the end of 
the tube, to reach the support, and leave the end within the 
flames. The dotted lines at h, fig. 4, show the end of the tube, 


* For which very convenient formule will be found in the ninth edition of Dr. 
Henry’s Elements of Chemistry. 


1824.] On the Ancient Tin Trade. 175 


short of the support; the foil is secured at the last coil by bind- 
os a as ati. 

_ Fig. 5 shows the foil in act of being wrapped on, also the pro- 
portion of the space occupied by the materials ; first, the mixture 
of oxide of copper with the material to be analyzed, next pure 
oxide of copper, or copper filings; and lastly, asbestos. hen 
the quantity of water formed is considerable, the tube is either 
blown into a bulb, as at k, fig. 6, or melted on to one ready pre- 
pared, as at /. 

Fig. 7 is a long funnel, made by drawing out the end ofa tube 
of a suitable thickness at m, till it is long and small enough 
through n » to reach to the bottom of the tube, and then cutting 
it off at m, by which liquids may be introduced to the bottom of 
the tube without wetting the sides. 

As the wicks nearest the trough are to be lit first, and the 
remainder in succession, as the former finish their action, there 
are upright supports of tin, 0 o, fixed on the lamps, one for each 
space between the burners, against which to resta slip of tin p p, 
to prevent the lighted wicks from kindling those next, and it 
also enables the experimenter to blow out those that have done 
their duty. In fig. 2, the tin slip, p p, is shown by dotted lines, 
reaching from lamp to lamp: little flat caps are put on each 
burner when done with, to prevent the waste of spirit. Fig. 8 
shows one of these caps, g, on its place ; rr, fig. 1, a shelf fixed 
to the mercurial trough, to hold the lamps; ss the graduated 
jar. Tin pipes with corks, w w, as shown in fig. 2, are the 
apertures to pour the spirit into the lamps ; their places only are 
marked at w w, fig. 1. 


ArticLe IV, 


On the Ancient Tin Trade, as described by the Rev. J. Hodgson. 
(To the Editor of the Annals of Philosophy.) 


SIR, Huel Vor, Cornwall, Jan. 1, 1824. 

One of the adventurers in our mine very obligingly lends me 
the Annals of Philosophy, with which I am much amused in the 
winter evenings. In No. 36, for December, 1823, there is a 
aper “ On the Era when Brass was used in Purposes to which 
ron is now applied,” by the Rev. J. Hodgson; and I find it 
mentioned there, “ that it is probable that the Egyptians or 
Phoenicians had made abet voyages to this country ” (the 
land of the Britons) “ more than 16 centuries before that time ” 
c e. the time of Julius Cwsar). “ That it was known to the 
heenicians in the time of Homer, his accounts of amber and 
tin are unquestionable evidence.” ‘ And there can be no doubt 


176 On the Ancient Tin Trade. [Marcu, 


but that the Greeks and Romans frequented it commonly ever 
after the destruction of Carthage, if not sooner.” 

Now, Mr. Editor, this account of the tin trade induced me to 
make some inquiries of the vicar of my parish, who gave me 
permission to look at the books in his library ; so after my day’s 
work in the mine (of which, Mr. Editor, I am a captain), I hada 
peep into Dr. Borlase’s Natural History, and a few other works, 
but in none of them can [ find that the Egyptians or Pheeni- 
cians were such great navigators at the period above mentioned, 
i. e. about 1700 years before Christ. 

In the 31st chapter of Numbers, verse 22, we are told that the 
Israelites in their wars against the Midianites are directed to 
keep for their own use the gold, the silver, the brass, the iron, 
the ¢in, and the lead. If this country were then known, we 
should feel much obliged to Mr. Hodgson, if he would tell us his 
authority. Had this country been the only one in which tin was 
ever found, it would certainly have been a strong ground for pre- 
suming that the Pheenicians had traded here at the time of the 
Trojan, war. Tin was generally known in Spain,*-and amber+ 
has been found in other places besides the Baltic. Therefore I 
do not think that there is “ unquestionable evidence” that it 
was known to the Pheenicians in the time of Homer, about eight 
centuries before Christ. Carthage, we know, was founded by a 
colony from the Phoenicians nearly 900 years before Christ; and 
other colonies were planted by them at Tangier, Malaga, Gades, 
&e. Now, Sir, as 1 know very few of the old books, I should be 

lad to be informed where I shall find any account of people 
before that period venturing into the Atlantic. Where we are 
left in darkness we may be allowed to reason from analogy. 
When the Portuguese became acquainted with the use of, the 
compass about three centuries ago, what sort of voyages, and 
what discoveries, did they make, on the coast of Africa, and how 
easily were they deterred from prosecuting them by a storm. 
Cape Non was for some time the extreme point to which they 
ventured. Will it then be believed that the Pheenicians or 
Egyptians were in the habit of trading to this country without 
the aid of the needle 164 centuries before Christ. It may be in 
the recollection of those who have read Robertson’s America, 
that a Portuguese in sailing for the Cape of Good Hope was 
driven by the currents and winds out of his course, and unex 
pectedly discovered a part of South America. In the same way 
do I believe that this country was first found; for in those 
days what navigator, however adventurous, would have quitted 
the coast of Spain to explore unknown seas! If the trade in 
tin by sea had been known for so many centuries, how does it 
happen that Herodotus} should have been perfectly ignorant of 
the matter, and in his mention of tin poimts to the Eridanus, 


”®* Pliny, lib. 34, c, 16. + Pliny, lib. 37, c. 3. + Thalia, Sect. 115. 


1824.] Mr. Dillwyn on Fossil Shells. 177 


which he says has a Greek derivation. How comes it that we 
have no accounts recorded of any voyages made to a great dist- 
ance beyond the Straits of Gades much earlier than 600 years 
before Christ. Then with respect to the Greeks trading here, 
Camden says, that they came here 160 years before Cesar, and 
Bochart fixes the period more than a century lower, 117 years 
before Christ. These Greeks were adventurers whovhad quitted 
Samos with the intention of forming a colony on the coast of 
Egypt, and were driven by a storm through the Straits, near 
which place they settled. These were the only people of that 
nation who traded with us. Nor after the destruction of Car- 
thage do I believe that the Romans frequented this country, for 
if they had done it, the spring tides would certainly have been 
well known to Cesar.* 

I am not unacquainted with the account in Strabo, lib. 3, of 
the Pheenician vessel being run on shore by the crew when pur- 
sued by a Roman, That could not possibly have taken place 
until the conclusion of the first Punic war, and by that time, and 
long before the trade in tin had been established across France 
by the Marseillois, a Greek colony, who had quitted Phocea, - 
before Christ 539, and had carried on the trade in tin and amber 
with the Romans, to which Herodotus points, and which is sub- 
sequently detailed by Diodorus Siculus. 

_ I trust, Sir, that you will allow these few observations to be 
inserted in the Annals, solely with the view of drawing Mr. 
Hodgson’s attention to the subject, and with the hope that he 
will kindly favour us with a paper ‘On the Tin Trade,” in one 
of your future numbers. 
J am, Sir, your obedient servant, 
A TINNER. 


ARTICLE V, 


On Fossil Shells. By Lewis Weston Dillwyn, Esq. FRS.t Ina 
Letter addressed to Sir Humphry Davy, Bart. Pres. RS. 


As fossil shells are more numerous, and generally occur in a 
better state of preservation than any other of the organic remains, 
they have become one of the most interesting objects for geolo- 
gical research, and there is such an exact conformity in the 
structure of manv of these fossils with the living genera, as to 
render it in the highest degree probable, that the habits of their 
animals were also similar. By availing ourselves of these ana- 
logies, some circumstances attending the distribution of fossil 


* Lb. iv. sect. 9. + From the Philosophical Transactions for 1823, Part II. 
New Series, vor. vil. N 


178 Mr. Dillwyn on Fossil Shells, [Marcn, 


shells may be observed which have hitherto escaped notice, and 
if you should find them to be sufficiently interesting, or likely to 
open a new door for inquiry, I beg that you will submit to the 
Royal Society the following observations on the fossil remains of 
the Mollusce. 

Pliny, in describing the shell fish which was supposed to 
yield the Tyrian die, has observed, ‘ lingua purpure longitudine 
digitali, qua pascitur perforando reliqua conchylia;’ and 
Lamarck says, that all those moliuscee whose shells have a notch 
or canal at the base of their apertures, are furnished with similar 
powers, by means of a retractile proboscis; and in his arrange- 
ment of invertebral animals they form a section of the Tracheli- 
podes, with the name of ‘ Zoophages.’ Whether all these 
Trachelipodes are possessed of the same predaceous powers of 
boring into hard substances, and whether some of them may not 
subsist chiefly on dead animals, my own observations have led 
me greatly to doubt ; but this notch or canal is made for the 
protrusion of a trunk, which is formed to answer the same pur- 
poses as the respiratory organs of a Gastrobranchus,* and ma 
serve at once to distinguish a carnivorous species. The follow- 
ing fossil genera belong to this section of the Trachelipodes— 
Conus, Oliva, Ancilla, Terebellum, Seraphs, Cypreea, Ovula, 
Volvaria, Marginella, Voluta, Mitra, Terebra, Buccinum, Harpa, 
Monocerus, Purpura, Cassis, Cassidaria, Strombus, Rostellaria, 
Triton, Murex, Ranella, Pyrula, Fusus, Cancellaria, Potamides, 
and Cerithium. 

In all the other genera of turbinated univalves, the lower mar- 
gin of the aperture, instead of being either notched or chan- 
nelled, is entire ; and Adanson, in his History of Senegal, so far 
back as 1757, has shown that the Mollusce of these shells have 
jaws which are formed for feeding on vegetable substances ; and 
they have heen proved, by subsequent observations, to be 
entirely herbivorous, i. e. the marine genera feed on alge, and 
the fresh water and land genera on the leaves of vegetables. 
These together constitute the other section of the Trachelipo- 
des, which Lamarck has called ‘ Phytiphages,’ and it comprises 
the following genera of fossils—Turritella, Turbo, Cirrus, Euom- 
phalus, Trochus, Solarium, Delphinula, Scalaria, Natica, Nerita, 
Ampullaria, Vivipara,} Paludina, Melania, Planorbis, Cyclos- 
toma, Auricula, Tornatella, Bulinus, Helicina, and Helix. ; 

Every turbinated univalve of the older beds from transition 
lime to the lias, which I have been able to procure, or of which 
I can find any record, belongs to these herbivorous genera, and 
the family has been handed down through all the successive 


* See Sir E. Home’s observations on this animal under the name of Myxine, in the 
Philosophical Transactions for 1815, p. 261. 

+ I am unable to distinguish this genus from Paludina; and the name of Vivipaya is _ 
calculated to mislead, for none of the species are more than ovi-viviparous. " 


1824.] Mr, Dillwyn on Fossil Shells, 179 


strata, and still inhabits our land and waters. On the other 
hand, all the carnivorous genera abound in the strata above the 
chalk, but are comparatively extremely rare in the secondary 
strata, and not a single shell has been detected in any older bed 
than the lower oolite. As a proof of this rarity it may be 
remarked, in the list of British fossils which Mr, Parkinson has 
given in his Introduction to the Study of Organic Remains, that 
not one single species of either of the carnivorous genera has 
been referred to any stratum below the London clay, and only 
the few following species appear in any of the numerous lists of 
the secondary strata which are given in Conybeare and Phillips’s 
Outlines of Geology, viz. a Murex* and Pleurotoma rostrata in 
the green sand, Certthium melanoides in chalk marle, and a few 
species of Rostellaria in various strata from chalk marle to the 
lower oolite, For the Pleurotoma and the Cerithium, a refer- 
ence to the Mineral Conchology is given; and Mr. Sowerby 
there only says that he has seen an imperfect cast, very like the 
former, from the canal at Devizes ; and of the latter, that it was 
found in the London clay, and in the clay above the chalk at 
Newhaven. It is also worthy of remark, that all the above- 
mentioned Rostellarie which have been found in secondary 
strata are nearly allied to the Linnean Strombus Pes Pelecani ; 
and it may be observed that this species, when fully grown, has 
not any open canal at its base; and that in the figure which 
Muller has given of the animal there is no appearance, nor in 
Montagu’s description is any mention made, of that retractile 
proboscis or respiratory trunk, which are the distinguishing cha- 
racters of a carnivorous Trachelipode. I therefore propose to 
remoye these Rostellarie of the secondary strata, which are 
readily distinguished by the remarkable expansion of their outer 
lips, to form a separate genus with Petiver’s name of Aporrhais 
and the other fossil Rostellariz which have the recent Strombus 
Sissus, for their type are only to be found in strata above the 
chalk. 

Small circular holes, which have been bored by the predaceous 
Trachelipodes, are frequently found in recent shells, and I have 
seen exactly similar holes in many fossils, but they have all been 
taken from the London clay or crag; nor have I been able to 
find any such appearance in any fossil of the older formations. 
If this observation should be confirmed by a more extended 
examination of other cabinets, it will prove that neither the 
Aporrhaides, or any of those few undoubtedly carnivorous species 
which have been found in the secondary formations, were fur- 
nished with any such predaceous powers as Pliny has described, 
and that they belong to a subdivision of the Trachelipoda zoo- 


“ Mr. George Sowerby has sent me this shell with the name of Murex calcar, and if 
I am not much mistaken, I have seen another species of Murex from the green sand in 
the extensive collection of Mr, J. S. Miller. 


N 2 


180 Mr. Dillwyn on Fossil Shells. [MArcn; 


phaga, which feed only on dead animals. Without attempting 
to distinguish the more predaceous from these other genera, I 
shall however at present content myself with proving, and for 
this I have adduced sufficient evidence, that the whole family of 
the carnivorous Trachelipodes are extremely rare in all those 
strata where the Ammonites and other Nautilide abound. 

In describing the Ammonites, De Montfort, in his Conchologie 
Systematique, observes, that they are found ofall sizes, “ depuis 
la grandeur d’une Lentille jusqu’a celle de 8 pieds de diametre ;” 
and, as a proof of their great abundance, Lamarck says, “ La 
route d’Auxerre 4 Avalon, en Bourgogne, est ferrée avec des 
Cornes d’Ammon.” These Ammonites, as well as most of the 
other principal multilocular genera, ‘appear to have become 
extinct in our northern latitudes when the chalk formation was 
completed ; but a few of the Nautilide still inhabit the southern 
ocean, and their mollusce belong to the carnivorous order 
which Lamarck has described under the naine of Cephalopodes. 
From the occurrence in such great numbers of the carnivorous 
Trachelipodes in the formation above the chalk, it therefore 
appears, that the vast and sudden decrease of one predaceous 
tribe has been provided for by the new creation of many genera, 
and a myriad of species possessed of similar appetencies, and 
yet formed for obtaining their prey by habits entirely different 
from those of the Cephalopodes. 

It may be further observed, that all the marine genera of the 
herbivorous Trachelipodes to which either of the fossil species 
belongs, are furnished with an operculum, and that the few car- 
nivorous species which have been found in the secondary strata, 
agree with them in this particular, although the unoperculated 
genera are very abundant in the London clay. Lamarck, of the 
fresh water Trachelipodes says, that those which are not fur- 
nished with an operculum are formed for the occasional respira- 
tion of air; but | believe that this observation is not applicable 
to the marine genera; and it was Adanson’s opinion, that the 
operculum is intended for the protection of the animal; nor can 
Iimagine any thing against which such a shield would be more 
necessary than the long and pliable fingers of the Cephalopodes, 
when they abounded in the seas, as they must formerly have 
done. It is, therefore, at least a curious coincidence, that all the 
marine Trachelipodes of the transition and secondary strata, of 
which [ can find any record, belong to genera which are 
furnished with an operculum, and that none of the numerous 
anoperculated genera should have been found in any other than 
the tertiary formations where the Ammonites disappear. For 
the protection of the testaceous Gasteropodes no such shield 
would be wanting, and including this order it may be generally 
observed, that none of the marine unopercalated Mollusce, 


except the Cephalopodes, are to be found in the lias, or im any of 


1824.] Active Power of Dilatation of the. Heart. 181 


its older strata; and it appears to me that a much greater 
approach towards the same variety of testaceous animals which 
now inhabits our seas is to be found in the adjoining bed of 
lower oolite. 

The foregoing observations are confined chiefly to British 
fossils; for as a few of the testaceous Cephalopodes still live in 
the warmer climates, it is possible that the Ammonites, as well 
as some others of the extinct genera, may have existed longer, 
and that their remains may be found in the tertiary formations 
of the more southern latitudes. Although fossil Nautilide are. 
common in the secondary strata of the United States, they are 
said not to have been found in South America; and it may, 
therefore, be queried whether the Cephalopodes were not con- 
fined to the more northern latitudes when the chalk formation 
was completed, and whether a decrease in the earth’s tempera- 
ture at that period may not have occasioned the entire destruc- 
tion of some genera, and a migration of others to the southward. 

It is highly probable, when a more perfect knowledge of the 
testaceous animals has been obtained, that the line of inquiry 
which I have now suggested may be greatly extended, and the 
collected tendency of such analogies between the habits of living 
animals and the organic remains of the different strata, may 
serve to throw some light on the nature of the changes which 
the surface of our planet has undergone. 


(EES Se PAO EN SL SS 


ArticLe VI. 


On the active Power of Dilatation of the Heart.* 
By David Williams, MD. 


(To the Editor of the Annals of Philosophy.) 
DEAR SIR, Liverpool, Feb, 1, 1824, 


The following observations were made during my experiments 
on the practicability of an operation for phthisis pulmonalis,+ 
and also while inquiring into the cause and the etlects of an 
obstruction of the blood in the lungs.{ By securing the trachea 
of an animal at the acme of inspiration, the heart continues its 
action for some time. To ascertain the strength of the active 
power of dilatation attributed to the right auricle and ventricle, 


* Extracted from An Essay on the Motive Powers of the Circulation of the Blood, 
read before the Literary and Philosophical Society of Liverpool, Jan, 1824, 

+ Annals for June. 

} Annals for September. 


182 Dr. Williams on the active Power [Marcu, . 


the cay were compressed, the inferior as near the diaphragm 
as possible, and the superior, a little above its entrance ito the 
auricle. As the auricle was thus suddenly limited to the small 
quantity of blood, that the vena azygos and the coronary veins 
poured into it, it was expected that the blood, which remained 
m the inferior cava between the compressed part and the auricle 
would have been pumped out ; but no effect indicating a sudden 
extraction of blood from the isolated portion of the inferior cava 
could be perceived. Had the auricle or ventricle exercised the 
function of active dilatation, it must have been discovered, for 
the lungs were quiescent, and no muscular action, save that of 
the heart itself, perplexed the observation. After the last systole 
of the left ventricle has occurred, irregular and hurried, or flut- 
tering contractions of the muscular fibres of the right ventricle take 
place. When they have ceased, the right ventricle feels full and 
soft, and the left feels contracted orcollapsed. If now we open 
one of the pulmonary veins near their termination in the auricle, 
no expansion of the latter chamber or of the ventricle will take 
place; but as the residue of the blood in the pulmonary veins 
drains into the ventricle, it imperceptibly fills, and its walls feel 
softer to the touch. 

We shall now take into consideration the influence ascribed 
to the active power of dilatation of the heart in the economy of 
the circulation. Inthe first place, we shall inquire into the 
nature of the power; then compare its characteristic qualities 
with the above phenomena ; afterwards we shall be able to 
judge whether we have arrived at any facts capable of furthering 
our acquaintance with the moving powers of the circulation. As 
Dr. Wilson Philip is the last author on our subject whose writ- 
ings I have perused, I shall take the liberty of quoting the fol- 
lowing periods from his valuable essay,* so as to give my 
readers a correct statement of the ideas entertained by Dr. 
Philip, as to the nature and the influence exercised by the inhe- 
rent dilating power of the heart, and also the resilience of the 
lungs. “What purpose then,” says Dr. Philip, “is served by 
the dilating power of the ventricles increased by the tendency of 
the lungs to collapse ? It favours the entrance of the blood sud- 
denly propelled into it by the contraction of the auricle; and 
the degree of dilating power is well proportioned to this office. 
Without this dilating power, the tendency of the ventricle would 
be to remain in a state of collapse after the systole, and part of 
the power of the auricle would be expended in dilating the ven- 
tricle. Here, as in many other instances, both in man and the 
inferior animals, we see nature saving the muscular by the sub- 
stitution of the elastic power.” In the last sentence we perceive 
Dr. Philip recognizing elasticity to be the nature of the mherent 


* Some Observations relating to the Powers of Circulation, &c. Medico-Chir, Trans. 
Vol. xii, Part. II. 


1824.] of Dilatation of the Heart. 183 


power which enables the ventricles to dilate themselves. Pra 

what is the nature of the action of an elastic body? Mr. John 
Hunter thus defines it: “ The action of elasticity is continual, 
and its immediate effects are produced whenever the resistance 
is removed; by which it may be distinguished from other 
powers.” * From our definition, we learn that the action of an 
elastic body is permanent, and that as soon as the resisting 
power which retains it in a forced position is removed, that it 
immediately regains its natural state of rest. In order to the 
elucidation of our problem, we shall admit the body of the left 
ventricle of the heart to be possessed of an elastic property. As 
the systole of the ventricle throws the elastic property into a 
forced position, and as the ventricle remains for some time after 
its last systole in a comparative state of collapse, we have only 
to do away with the influence of the power which retains it 
during that period in that state, and the elastic property will 
instantly restore itself to its natural position. Before we set 
about releasing it from its constrained situation, we shall inquire 
into the nature of the power which we have to contend with. 
As a state of relaxation in a muscular fibre succeeds the state of 
contraction, it follows that the action of the muscular fibres of 
the walls of the ventricle cannot be the cause of the confinement 
of the elastic property in its unnatural position, for we admit 
contraction to be the last motion of the ventricle. The resisting 
power then must arise from the propulsion of a portion of the 
blood into the aorta from the cavity of the ventricle by its sys- 
tole, without its being able (by its elasticity or active power of 
dilatation) to draw its wonted supply in return from the auricle, 
on account of the latter being itselfdeprived of its usual supply. 
Therefore, as the elastic property endeavours by its reaction to 
regain its natural state of rest, a tendency to form a vacuum in 
the cavity of the ventricle must be the result, which effectually 
retains the elastic property in its constrained position. Now if 
we can establish a communication between the cavity of the 
ventricle and the exterior air, it is evident that we shall do 
away with the tendency to a vacuum, and consequently with the 
resistance offered to the reaction of the elastic property. Such 
a communication is easily established without doing any injury 
to the walls of the ventricle, by opening one of the pulmonary 
veins, near their junction with the auricle. In the narration of 
our experimental investigation, we are informed that after such 
an expedient was had recourse to, that no such phenomenon as 
dilatation of the ventricle was remarked. Therefore if we can 
depend on the correctness of the observations during the above 
experiments, and if observations under such circumstances can 
be relied on, we must conclude the active power of dilatation, or 


* On the Blood, 


184 Active Power of Dilatation of the Heart. (Marcu, 


the action of the elastic property of the auricles and ventricles, 
to be either ideal, or to be so extremely feeble, as to be capable 
of evading our senses under the most favourable situation in 
which we can place the organs for inspection. For I can 
scarcely conceive it possible to devise more decisive modes of 
ascertaining the existence of such a power, though ever so 
trifling, than those had recourse to. 

Further, as the action of an elastic substance is as perfect 
after the extinction of life, until the process of putrefaction 
destroys its texture, as during the existence of the animal; by 
examining a heart detached, after its absolute death, or after 
its utmost contraction by the vis mortua, we can readily 
satisfy ourselves, whether the walls of the ventricles have 
any elastic property that can be appreciated. If we find a heart 
contracted, and on pressing its body so as to flatten it, that it 
does not present to our senses a disposition to recover its natural 
shape similar to what we witness in the truly elastic arteries 
whose roots are attached to its base, what inference are we to 
draw? Why certainly we must need infer that it possesses no 
greater elastic property than muscles incommon. ‘The condition 
of the heart greatly depends on the state of the animal when 
killed. Fat beasts (more particularly sheep), from their un- 
wieldiness, and from the action of their diaphragms being 
restrained by their obesity, are easily overdriven, and sometimes 
on their way to the slaughter-house, to prevent their suffocating, 
they are obliged to be “ stuck;” or from urgency, they are killed 
while yet breathless and ready to faint. The right ventricle of 
the heart of an animal killed in such a plight is found to be 
gorged, and the reason appears to me to be obvious. As the 
blood is more or less obstructed in its passage through the 
lungs, previous to the sticking of the animal, the pulmonary 
artery and the cavities of the right side of the heart are necessa- 
‘rily more or less gorged, and the ventricle and pulmonary artery 
must remain so; for during the time the animal is bleeding to 
death, a small portion only of the blood which they contain at 
the time the animal is stabbed, can pass into the system of the 
pulmonary veins, for want of pure air in the air cells of the Jungs 
to enable it to undergo the mysterious change in the rete Mal- 
pighii. Thus the right ventricle will be large and flabby, or 
with its muscular fibres relaxed after the pluck is extracted ; for 
in consequence of its being retained in a state of extension, the 
action of the vis mortua is prevented from affecting its muscular 
fibres. When an animal is killed by dividing the blood-vessels 
of the neck without any previous obstruction in the lungs, then 
no engorgement can take place in the right ventricle, for the 
blood rushes with unusual impetuosity towards the point where 
there is the least resistance, and in a few minutes nearly the 
whole of the blood in the body escapes through the artificial out- 


1824.] — Table of Equivalent Numbers. 185 


lets. .I think the. gorged state of the right ventricle of the heart 
of an. animal when killed, while breathless. and. faint, to be 
another evidence.in support of my opinion, that prostration of 
strength, arising from short continuance of anxious exertion, is 
the immediate etfect of an obstruction of blood in the lungs.* 


ArTicLE VII. 
A Table of Equivalent Numbers. 


[Since the publication of any table of equivalents in the Annals, 
various important additions have been made to this department 
of chemistry ; new editions of Dr. Thomson’s and of Dr. Henry’s 
treatises on chemistry have appeared, and Mr. Brande has pub- 
lished a table in the Institution Journal. In the present table, I 
have inserted corrections obtained from various sources, and 
a few as the results of my own experiments.—Ldit.] 


TABLE I. 
ACID, acetic, : . 50 | Acid, iddic : : . 165 
crystallized (1 water). . 59 malic z : ; 10 
arsenic : . : 62 inolybdic  , y ‘ 7Z 
arsenious © , : . 54 molybdous , 4 64 
benzoic - - sone ese) muriatic ° F ° 31 
boracic? ~ , fei - 22 nitric (dry) . - Z 54 
’ erystallized (2 water) . 40 liquid (sp. gr. 1:50 2 water) 72 
carbonic ~ . : Pipe nitrous - - . A6 
chloric . : . 16 oxalic . . 36 
chloriodic © . . eee UTE crystallized (4 water) é 72 
chlorocarbonic ~ . . 50 perchloric . - ° 92 
chlorocyanic - - 62 phosphoric . : ° 28 
chromic s . . 52 phosphorous . . . 20 
citric - : » 58 saclactic : c a kOe 
crystallized (2 water) . 76 succinic (anhydrous crystals) 50 
columbic? =. . rip caged G5) sulphuric (dry) p + 40 
ferrocyanic, . : ; ? liquid (sp. gr. 14838) , 49 
fluoboric? . : ° 22 sulphurous . = : 32 
fluoric : ° . 17 tartaric Fé ° 67 
formic . : c 3T erystallized (1 water) 5 16 
fluosilicie . . ; 24 tungstic 7 rete si, 1 220 
gallic ? . ° : 63 uric . ; . 45? 
hydriodic . P - 126 | Alum (dry) . : -., 262 
hydrocyanic , ° 2 QT (crystallized 25 water - 487 
hydrofluoric . A . 17 |} Alumina. F ° ° 27 
hyposulphurous ° : 24 sulphate ’ . . . 67 
hyposulphuric . - 86 subsulphate (2 acid, 3 base) 116 


.* Medical and Surgical Journal for Oct. 1823, p. 535, 


186 


Aluminum . 


Ammonia 
acetate 


Table of Equivalent Numbers. 


bicatbonate (2 water) 
borate ? (dry) 


crystallized (2 water) 


carbonate 


sesquicarbonate (2 water) 


citrate 
fluoborate 
hydriodate 
iodate 
molybdate 
muriate 
nitrate 
oxalate 


(eryst. 


phosphate 
phosphite 
succinate 
sulphate 
sulphite 
tartrate 


potassa-tartrate 


Antimony 
chloride 
iodide 
deutoxide 
peroxide 
protoxide 
sulphuret 


potassa-tartrate 
Arseniate of ammonia 


potash 
soda 
Arsenic . 
acid 
chloride 
iodide 


. 


. 


Arsenious acid . 


Azote . 

Barium . 
chloride 
iodide 
peroxide 
phosphuret 
sulphuret 

Barytes 
acetate 
arseniate 
arsenite 


19 
17 
67 
19 
39 


benzoate 
borate 
earbonate 
ehlorate 
chromate 
citrate 
hydrate 
iodate 
nitrate 


muriate (cryst. 1 water) 


oxalate 
phosphate 
phosphite 
succinate 
sulphate 
sulphite 
tartrate 
tungstate 
Benzoic acid 


Bicarburetted hydrogen 


Bismuth 
acetate 
arseniate 
benzoate 
chloride 
citrate 
iodate 
iodide 
nitrate 
oxalate 
oxide 
phosphate 
phosphuret 
sulphate 
sulphuret 
tartrate 

Boracic acid 


acid crystallized (2 water) 


Borax (8 water) 

Boron. 

Cadmium 
carbonate 
chloride 
iodide 
nitrate 
oxide 
phosphate 


. 


phosphuret . 


sulphate 
sulphuret - 
Calcium 


181 
118 


Se ee ee 


1824,} 


chloride 
fluoride 
iodide 


oxide (lime) 


phosphuret . 


sulphuret 
Calomel . 
Camphoric acid 
Carbon . 

perchloride 


protochloride. 


subchloride 


hydrochloride 


oxide 


phosphuret . 


sulphuret 
Carbonic acid 
oxide 


Carburet of azote, 


sulphur 


phosphorus . 


Carburetted hydrogen 


Cerium . 
Chloric acid 
Chlorine 
Chromium 
deutoxide 
oxide 
Cobalt. 
acetate 
arseniate 
benzoate 
borate 
carbonate 
chloride 
citrate 
iodide 
nitrate 
oxalate 
peroxide 
phosphate 


phosphuret . 


protoxide 


sulphate (dry) 
crystallized (7 water) 


sulphuret 

tartrate 
Columbium 
Copper . 


acetate 


56 


64 
130 


cryst.(6 water, Com verdigris) 184 


Table of Equivalent Numbers. 


binacetate 5 


187 


180 


cryst. (3 water, dist. verdigris) 207 


subacetate (1 acid 2 base) 


carbonate (unhydrous) . 
(2 water. malachite) 


iodide 5 . 
perchloride , : 
pemitrate . . 
persulphate . ° 
crystallized (10 water) 
perphosphate . 
phosphuret . : 
protochloride - 
protoxide . . 
peroxide . 
sulphuret . . 
Corrosive sublimate - 
Cyanogen 
Fluorine 2 ° 
Glucina ° . 
Glucinum 
Gold A : . 
chloride A : 
iodide ° ° 
protoxide . ° 
peroxide , . 


sulphuret , 


crystallized, 8 water 


Hydrogen : 5 
Todine . : , 
protochloride 
perchloride 
peroxide , 


protoxide . 
sulphate (dry) 
crystallized (7 water) 


persulphuret . 
protosulphuret . 
Lead : ; 
acetate , 
crystallized (3 water) 
sub-binacetate 
sub-tritacetate - 
arseniate ° 
benzoate : . 
borate ‘ F 
carbonate , F, 
chlorate F z 
chloride : ° 


210 
102 
111 
189 
136 
188 
160 
250 
136 

76 
100 

72 


26 
16 
26 
18 


200 
236 


325 


1+1=208 
14+3=224 
1+3=248 
chloride of, & sodium (dry) 


296 


36 

76 
139 

60 

dd 
104 
162 
189 
274 
386 
174 
232 
134 
134 
188 
140 


188 Table of Equivalent Numbers. [Marcu, 


chromate - . ; . 164 | Magnesia . . «= =20 
citrate ; 4 S190 ammonia-phosphate . F 93 
deutoxide . ° iene OCF borate ? . : : A2 
jodate - . : ob eal) carbonate. S . 42 
iodide . : 3 229 hydrate - 2 4 29 
malate 5 : Ep iiacame tek muriate ; i r 57 
molybdate . . . 184 nitrate : . ° TA 
nitrate 3 Q . 166 phosphate . 5 5 48 
oxalate A : . 148 sulphate (dry) P 60 
peroxide . : seme EL) crystallized {<7 water) tae L235 
phosphate . : . 140 tartrate . ° : 87 
phosphite. 4 . 132 | Magnesium : : ciated 
phosphuret , . oe LAG chloride : ° 48 
protoxide . 5 thd eH iodide - 3 2 Pear eae 
succinate . : 162 phosphuret . 5 : 24 
sulphate. p . 152 sulphuret . . a” 28 
sulphite ‘ 5 . 144 | Manganese . . : 28 
sulphuret . : - 120 acetate é . 5 86 
tartrate : : a hie benzoate. FOGG, 
Lime. ° . ° 28 carbonate . - ' 58 
acetate 5 . . 78 chlorate A z ook LS 
arseniate . . 4 90 chloride * : : 64 
benzoate. ’ - 148 citrate ° 5 94 
biphosphate . : 5 84 deutoxide - “ » Ad 
borate . : - 50? oxalate s . , 12 
carbonate . ° c 50 peroxide. : : Ad 
chlorate . . ~ 104 phosphate . . : 64 
chloride ° : . 64 phosphuret . PE 2: 40 
citrate : : : 86 protoxide . . i 36 
chromate. 5 80 succinate. . . 86 
hydrate “ ° a 37 sulphate . A é 716 
iodate . . SOR: tartrate . . om 103 
muriate cryst. (5 water) - 110 | Mercury : . aoe 200 
oxalate ° ° . 64 bipersulphate ° a, 206 
phosphate . ° . 56 bisulphuret . “tp oY 2338 
phosphite. . - - 48 - ‘bicyanuret . . - | 252 
succinate. A ° 78 perchloride . . om 212 
sulphate : ° : 68 periodide . - F +. 450 
crystallized (2 water) é 86 permitrate . . + 324 
sulphite 4 F : 60 peroxide . 2 eeu. SiG 
tartrate 5 . ; 95 perphosphate : sie, 212 
tungstate . ; . 148 persulphate , ° o(q S5GEe 
Lithia. 4 _ - 1s protochloride. : any, 236 
carbonate. . . AO protonitrate . . pi Se 
nitrate : ‘ 12 protosulphate 3 s . | Oar 
phosphate . : : 46 protoxide . ° . 208 
sulphate . . : 58 | Molybdenum. . : AS 
Lithium : . A 10 protoxide . 2 mt 56 
chloride : e : AG | Nickel . ; ° f 29 
iodide . ’ by ap I) acetate . . . 87 


sulphuret  . . am 20 arseniate —« ° a) eee 


1824.] 


benzoate 
borate 
carbonate 
chloride 
citrate 
iodide 
nitrate 
oxalate 
peroxide 
phosphate 


phosphuret . 


protoxide 


sulphate (dry) 


crystallized 


sulphuret 
' tartrate 
Nitric oxide 
Nitrogen 
Nitrous oxide 
Olefiant gas 
Osmium 
oxide 
Oxygen 
Palladium 
oxide 
Phosphorus 
carburet 
chloride 


perchloride 


sulphuret 
Platinum 


Table of Equivalent Numbers. 


(7 water) 


ammonia-muriate . 


perchloride 


peroxide 


bi-phosphuret 


bi-sulphuret 


Potash (dry) 
acetate 
arseniate 
arsenite 
benzoate 


bicarbonate . : 
crystallized (1 water) 


bichromate 


binarseniate . 


binoxalate 


biphesphate . 


bisulphate 


crystallized (1 water) 


bitartrate 


crystallized (1 water) 


157 
59 


borate 
carbonate 
chlorate 
chromate 
citrate 
hydrate 
iodate 
molybdate 
nitrate 
oxalate 
phosphate 


. 


quadroxalate. 


succinate 
sulphate 
sulphite 
tartrate 
tungstate 
Potassium 
chloride 
iodide 
peroxide 


phosphuret . 


protoxide (dry) 


sulphuret 
Rhodium 
peroxide 
protoxide 
Selenium ? 
Silica 
Silicium . 
Silver . 
acetate 
arseniate 
arsenite 
benzoate 
borate ? 
carbonate 
chlorate 
chloride 
chromate 
citrate 
iodate 
iodide 
molybdate 
nitrate 
oxalate 
oxide 
phosphate 
sulphate 
sulphite 
sulphuret 


189 
10? 
124 
100 
106 
213 


120 
102 


192 


115 
168 


165 


190 Table of Equivalent Numbers, [Marcu, 


tartrate ° E 185 { Sulphur . “ ‘ 16 
tungstate. : tedaks 238 carburet . ° ° 38 
Soda : ° 3 , 32 chloride F . > 52 
acetate - 4 82 iodide ° 3 site Lal 
crystallized (6 wake) vitiy 136 phosphuret . . . 28 
arseniate . 94 | Sulphuretted Siemens ° . 17 
arsenite 5 2 = 86 | Tannin? - ‘- 41 


Tellurium . . F 38 
chloride : : ° 74 
oxide : . . 46 

Tin . ; . Ot eis) 
bisulphuret é . 90 
iodide . : sium 18S 
peroxide , : . 74 
protoxide . . ° 66 
perchloride . ° mint ESO: 
protochloride : ». 848 
sulphuret . é aun Fe 
phosphuret . : Pete {2 

Titanium : . . ? 

Tungsten : ° » 96 

Tungstic acid. . rv 120 

crystallized (10 water) . 162 | Uranium . : : ? 
sulphite : j 64 oxide - i 5 ? 


tartrate . i . 99 | Uric acid p A - 48? 

and potash - . 214 | Water .. . "i 9 
Sodium . 2 * O4 | Witria |. ‘ ; ‘ 4O 
chloride - sd r 60 | Yttrium ? c A " 32 


benzoate A - : 152 
bicarbonate .- és a 16 
borate » . r . 54 
carbonate (dry) s ° 54 

crystallized (11 water) . 153 
chlorate ° ° nuk LOS 
chromate . : ‘ 84 
citrate s . 90 
hydrate : . . Al 
iodate . 5 mii LOT 
molybdate . ° . 104 
nitrate - : ‘* 86 
oxalate : Ps , 68 
succinate. : ° 82 
sulphate (dry) z 3 72 


iodide > : . 149 | Zinc 4 : F cs 34 
phosphuret . - é 36 acetate , ie " 92 
peroxide - . . 36 arseniate « : . 104 
protoxide . : ¢ 32 benzoate ‘ . ore 168 
sulphuret  . : : 40 borate 6 & ’ 64 
Starch ? : c seer 142 carbonate . sé - 64 


chlorate e . a Lie 
chloride , y . 70 
citrate : A . (ape 
iodate “ pe ROT 
iodide : 5 ang 159 
nitrate = . > 96 
oxalate E 5 ey 18 
oxide < ¢ > AQ 
phosphate 
phosphuret . . ‘ A6 
succinate = = “ 92 
sulphate (dry) iil ace 
crystallized (6 oe - 156 
sulphite : . ° 74 
tartrate . i , . AG 
Zirconia . - C oan AON, 
Zirconium . ° a Sue 


Strontia. - c 2 52 
acetate : 5 oe 102 
borate ? . : £ TA 
carbonate . : : 4 
citrate a : girts TO 
hydrate . : : 61 
muriate (cryst. 5 water) - 134 
oxalate 2 C ° 88 
phosphate . . ‘ 80 
sulphate : : 5 92 
tartrate x 5 vie LTD 

Strontium : : S 44 
chloride “ : : 80 
iodide ; 2 . 169 
phosphuret . . . 56 
sulphuret « . > 60 

Sugar. : . . 


. 
4 
Sc 


1824.] 


Hydrogen 

Carbon . 
Boron ? 

Bicarburetted vad 
Oxygen 

Silicium .« 
Carburetted _— 
Water ss 
Lithium 

Magnesium 
Phosphorus 


Phosphuretted hydrogen . 


Nitrogen 
Carbonic oxide 


Bihydroguret of Micapheoe 


Sulphur . 

2 Oxygen. 
Silica. ° 
Fluorine . 
Ammonia - 
Sulphuretted hydrogen 
Hydrofluoric acid 
Alunium ° 
Lithia 

Phosphuret of een 
Glucinum 


2 Water ° 
Aluminum - 
Phosphorous acid. 
Magnesia 

Calcium 


Carbonic acid . 
Nitrous oxide 
Boracic acid ? 


Fluoborie acid ? 

Sodium . ° r 
Phosphuret of magnesium. 
3 Oxygen s 
Hyposulphurous acid 
Fluosilicic acid 

Glucina . 

Alumina 
Cyanogen 


Sulphuret of lithium 


Table of Equivalent Numbers. 


TABLE II. 


1 


71 


14 


16 


17 


18 


19 


20 


22 


24 


26 


Hydrocyanic acid. 
3 Water . . 


Sulphuret of magnesium . 


Alumina 


Lime 

Phosphoric watt 
Phosphuret of sulphur 
Iron 
Manganese . 
Chromium 


Hydrate of magnesia 
Nickel 


Nitric oxide 


Sulphurous acid . 
Soda 

Phosphuret of caleiuniy 
Yttrium ? A 

4 Oxygen - 


Protoxide of cobalt 
Zinc . = 
Chlorine 
Hyposulphuric acid 
Protoxide of iron , 
manganese 


chromium 
Peroxide of sodium 
Phosphuret of sodium 
Sulphuret of calcium 
Fluoride of calcium 
Oxalic acid (dry) 
Water . “ 


Muriatic acid 
Phosphite of ammonia 
Protoxide of nickel 


Hydrate of lime . 


Zirconium ? - 
Formic acid - 


Sulphuret of carbon 
Arsenic . ° 
Tellurium 2 


Borate of ammonia ? (dry) ‘ 
Fluoborate of ammonia? . 


191 


27 


28 


29 


30 


32 


34 


36 


37 


192 


Boracic acid (crystallized . 


Sulphuric acid. : 
Potassium 5 . 
Yttria ? A 5 


Sulphuret of sodium ° 
Carbonate of lithia 
Deutoxide of manganese . 
Peroxide of iron . 
Phosphuret of manganese 
Phosphuret of iron 

5 Oxygen . . 


Hydrate of soda . : 
Phosphuret of nickel . 
Selenium ? . . 


Protochloride of carbon °. 
Oxide of zinc 
Carbonate of magnesia 
Borate of magnesia ? - 
Sulphuret of cobalt 


Protoxide of chlorine 
Strontium 

Peroxide of manganese 
Deutoxide of Chromium . 


Rhodium ? . ¢ 
Protosulphuret of iron. 
Antimony : 


Phosphate of ammonia . 


Zirconia ? : . 
Sulphuret of nickel 5 
Uric acid ? 6 : 
5 Water : ° 
Nitrous acid : - 
Chloride of lithium . 
Phosphate of lithia ‘3 
Phosphuret of zinc ; 


Oxide of tellurium 
Cerium ? 


Protochloride of phosphorus 
Potash (dry) 

Phosphate of magnesia. 
Subchloride of carbon. 
Molybdenum ? . 

Chloride of magnesinm . 
Phosphite of lime ? ; 
6 Oxygen - 


Sulphite of ammonia. 
Liquid sulphuric acid (1 water) 


40 


Al 


AQ 


A6 


48 


49 


Table of Equivalent Numbers. 


Hydrochloride of carbon . 
Carbonate of lime : 
Borate of lime . a 
Acetic acid 

Sulphuret of zinc. 
Succinic acid? . . 
Chlorecarbonic acid 
Chloride of sulphur 
Protoxide of rhedium . 
Phosphuret of potassium . 
Protoxide of antimony 
Strontia . 2 : 
Chromic acid . 


Oxalate of ammonia 


Dry nitric acid. ° 
Muriate of ammonia 

Carbonate of soda * 
Protoxide of cerium 
Arsenious acid . F 
6 Water. ‘ ; 


Sulphuret of potassiim . 
Deutoxide of antimony . 
Chloride of calcium . 
Phosphate of lime F 
Phosphuret of strontium . 
Protoxide of molybdenum 


Carbonate of cobalt te 
Borate of cobalt ? 

Cadmium ; iu 
7 Oxygen = . 


Sulphate of ammonia. 
Hydrate of petash 

Borate of ammonia (2 water) 
Muriate of magnesia 


Tin s . . 
Cabonate of manganese . 
Sulphate of lithia ° 
Citric acid (dry) . f 
Borate of nickel ? . 
Acetic acid crystallized . 
Carbonate of nickel : 
Chloride of sodium ° 
Persulphuret of iron 

Peroxide of rhodium 3 
Phosphate of soda . 
Sulphate of lime . 


Sulphate of magnesia (dry) 
Sulphuret of antimony 
Peroxide of antimony. 


[MARCcH, 


50 


52 


53 


54 


56 


57 


58 


59 


60 


1824.) 
Hydrate of strontia =. 
Phosphate of cobalt . 
Chloride of cobalt . 
Arsenic acid : . 
Chlorocyanic acid 


Oxalate of ammonia (1 water) 


Gallic acid ; ‘. 


7 Water. : - 


Peroxide of potassium . 
Sulphite of soda.. “ 
Chloride. of manganese .. 
Protochloride of iron 
Oxide of cadmium 

Copper . . 
Molybdous ania’, 
Sulphuret of ciaivhdchats 
Phosphate of manganese , 


Chloride of lime . : 
8 Oxygen . 
Carbonate of zinc 5 


Borate of zinc? . 7 
Oxalate oflime , 2 


Chloride of nickel 
Phosphate of nickel 


Protoxide of tin 
Sulphate of alumina ° 


Sulphate of alumina 2 


Tartaric acid (dry) ‘ 
Acetate of ammonia é 
Succinate of ammonia. 
Ferrocyanic acid 

Peroxide of chlorine ; 
Sulphate of lime ° 
Phosphuret of cadmium ? 
Oxalate of soda . 


Carbonate of potash 
Borate of potash ? - 
Oxalate of cobalt 
Chloride of zinc . 
Phosphate of zinc 
Barium . ‘ r 
Acetate of magnesia ° 
Phosphuret of tin : 
Malic acid 4 
Nitrate of ammonia 
Tannin ?. . 

New Series, vol. 


61 


63 


64 


65 | 


66 


67 


68 


70 


1 


Table of Equivalent Numbers. 


Liquid nitric acid (2 water) 


Crystallized oxalic acid (4 water) 


8 Water . 5 
Sulphate of soda (ary) . 
Nitrate of lithia 

Protoxide of copper . 
Oxalate of manganese 
Bismuth . . 
Molybdic acid °. . 
Sulphuret of cadmium 
Carbonate of strontia . 
Borate of strontia ? . 
9 Oxygen . . 


Oxalate of nickel F 


Nitrate of magnesia 
Sulphuret of tin. 
Peroxide of tin . . 
Sulphite of zinc. : 
Sulphate of cobalt (dry) . 
Chloride of tellurium . 


Citrate of ammonia A 


| Chloric acid . . 
Crystallized citric acid (2 water) - 
Crystallized tartaric acid (1 water) 


Chloride of potassium 
Phosphate of potash 
Phosphuret of copper 
Bi-carbonate of soda (dry) 
Protosulphate of manganese 
— iron (dry) 


Sulphate of nickel (dry) . 


Baryta . . . 
Acetate of lime . 4 
Succinate of lime . . 


Arseniate of ammonia . 


Bi-carbonate of ammonia (2 water 


Oxalate of zinc . o 
Sulphite of potash . 
Oxide of bismuth ; 
10 Oxygen Fa . 


Peroxide of copper 
Protosulphuret of copper . 
Chromate of lime. 5 
Phosphate of strontia 
Chloride of strontium 


“ . 
—. 


4) 


13 


14 


19 


76 


7 


18 


79 


80 


194 


Chloride of antimony 
Sugar? . ‘ 


Nitrate of lime . 
Phosphuret of barium 
Perchloride of iron 
Sulphate of zinc (dry) 
Acetateof soda . 
Succinate of soda . 


Bi-chloride of phosphorus. 


Phosphuret of bismuth 
Bi-phosphate of lime 
Chromate of soda . 
Acetate of cobalt . 
Oxalate of potash 
Tartrate of ammonia 


Arsenite of soda . 


Sulphate of lime cryst. (2 water) . 


Carbonate of cadmium 
Acetate of manganese 
Succinate of manganese 
Peroxide of barium 
Sulphuret of barium 
Nitrate of soda. 
Citrate of lime . 
Acetate ofiron . 
Hydrated baryta . 
Acetate of nickel . 
Tartrate of magnesia 
Sulphate of potash 
Sulphuret of bismuth 
Nitrate of cobalt . 
Oxalate of strontia 

11 Oxygen 

Molybdate of ammonia 


Arseniate. of lime. 
10 Water. “ 
Nitrate of manganese 
Bi-sulphuret of tin 
Protonitrate of iron 
Citrate of soda 


Nitrate of nickel . 


Perchloric acid + 


Bi-cerbonate of potash dine) 


Chloride of cadmium 
Citrate of cobalt < 
Phosphate of cadmium 
Sulphate of strontia 
Acetate of zinc = 
Succinate of zinc « 


. 


86 


87 


88 


89 


90 


91 


Table of Equivalent Numbers. 


Chlorate of ammonia 


. 


93 
Ammunia-phosphate of magnesia * 


Citrate of manganese 
Protochloride of tin 
Arseniate of soda . 


Tartrate of lime . 
Citrate of nickel . 


Arseniate of nickel 


Platinum 4 
Nitrate of zinc. 
Tungsten ? . 


12 Oxygen . 


Succinate of potash 
Acetate of potash. 
Phosphite of baryta 


Tartrate of soda . 


| Arseniate of nickel 


1l Water : 


Carbonate of barytes 


| Borate of barytes ? 


Persulphate of iron 
Citrate of zinc. 
Protochloride of copper 
Chromate of potash 


c 


96 


| 
: 98 
. 


100 


Bi-carbonate of potash cryst, (1.w.) . 101 


Tartrate of cobalt 
Nitrate of potash . 
Acetate of strontia 
Arsenite of potash 
Carbonate of copper 


Prototartrate of manganese 


2 ee i 


Bi-phosphate of potash 
Chlorate oflime . 
Arseniate of zinc . 
Molybdate of soda 
Tartrate of nickel 
Sulphate of cadmium 
Lead = < 


Ammonia-phosphate of soda 


Saclacticacid ? 


Chloride of barium 
Phosphate of barytes 
Citrate of potash « 


. 


} 
| 5 

wt 102 

t 103 


104 


f 
i 
J 
;: Ve 


106 


1824.] 

Chlorate of soda . 
Phosphate of bismuth . 
Chloride of bismuth . 


12 Water . . . 
Cryst. nitrate of lime (3 water) . 
Nitrate of strontia. . 

Silver . 

Muriate of lime cgi (5 et) 
Arseniate of potash ° 
Tartrate ofzinc . . 

Citrate of strontia . 
Sulphite of barytes . 
Protoxide of lead . . 


Chlorate of manganese’ . 


Oxalate of barytes as 
Tartrate of potash . 
Phosphuret of lead ’ 
Oxalate of bismuth , 
Deutoxide of lead . 
Crystallized carbonate of soda (7 
water) . . 
13 Water. . 
Hydrated carbonate of ammonia 
Sulphate of barytes . ‘ 
Nitrate of cadmium . 
Chlorate of zinc . . P 
Oxide of silver . . ’ 
Tartrate of strontia = 
Peroxide of lead . . 
Sulphate of bismuth . 
Sulphuret of lead . 
Tungstic acid > 
Molybdate of potash ‘ : 
Binoxalate of potash ’ . 
Benzoic acid ; P 
Perchloride of carbon. ° 


Rhodium ? c 


Crystallized sulphate of mag 
(7 water) . 


Chlorate of potash . . 
Muriate of barytes (5 water) =. 


Todine . . . . 


Mydriodicacid . “ 
Sulphuret of silyer . . 
4 Water, . . ¢ 


- 
| 


eb ey) 


: 
4 
i 


Table of Equivalent Numbers. 


109 


110 


112 


114 
115 
116 


17 


118 


119 


120 


195 
Bi-sulphate of potash . 
Protoxide of rhodium? . *l 1. 
Succinate of barytes . . 8 
Acetate of barytes . . 
Acetate of bismuth . i 
——— of copper. ° . 
30 
Chromate of barytes > . : 
Perchloride of tin abesl dna 
Nitrate of barytes . . 
Arsenite of barytes . f 132 
Phosphite of lead . + He . 
Nitrate of bismuth alr *) 
Carbonate of lead . “th 1394 
Borate of lead ?. . . : ¢ 
Prototartrate of tin J 
Todide of lithium . . i 135 
15 Water ° . . 
Perchloride of copper. . 


Acetate of soda cryst. (6 water) . 
Citrate of barytes . 
Sulphate of zinc cryst. (water) . 


ee eS 
oe 
ror) 


Perphosphate of copper . ° 
Bi-sulphate of potash crystallized 

(6 water) ° : . 
Iodide of phosphorus. . 7 

“magnesium ~ . 13 

Sulphate of cobalt (crystallized 1 

water) . . ° . 
Citrate of bismuth . - 138 
Cryst. sulphate of iron (7 water) . 139 
Oxychlorate of potash, : 
Chloride of lead . ; e 
Phosphate of lead ‘ 
Sulphate of nickel (crystallized 1 i 140 

water) . . . : 
Arseniate of barytes . . 
Carbonate of silver ° . 
Borate of silver? . . . 
Iodide of sulphur. taste 
Arseniate of bismuth . - 14 
Starch? . . . 143 
Hydriodate of ammonia . : 
Sulphite of lead . . . 
Columbium? =. . “lL 44 
Peroxide of rhodium? . » 
16 Water. 9 . . 


02 


196 
Tartrate of barytes 
Todide of calcium 


Chloride of silver. 
Phosphate of silver 


Tartrate of bismuth 
Benzoate of lime . 


Tungstate of lime 
Oxalate of lead 


Iodide of sodium . 


Cryst. nitrate of barytes (2 


Sulphite of silver . 
Iodide of cobalt . 
Sulphate of lead . 
Benzoate of soda . 
Bichromate of potash 
Columbic acid 


17 Water 

Chlorate of barytes 
Benzoate of cobalt 
Iodide of nickel . 
Oxalate of silver . 
Benzoate of manganese 
Sulphate of silver . 
Benzoate of nickel 
Borax (8 water) . 
Iodide of zinc . 


Persulphate of copper (ary) 


Chloriodic acid 


Crystallized sulphate of 


water) . 4 
Succinate of lead . 
Benzoate of zine . 
Acetate of lead ./ 


18 Water - 
Chromate of lead . 
Todic acid ews 


Todide of potassium 
Nitrate of lead 


Acetate of silver . 
Tungstate of potash 
Benzoate of potash 


Iodide of antimony 
Todide of strontium 


Chromate of silver 
Citrate oflead * . 


\ 
Carbonate of soda (crys, 11 went 
} 
t 
t 


. 


. 


soda (10> 


§ 
i 


* 


suey ' 


Table of Equivalent Numbers. 


145 


146 
147 


148 


153 


162 


[Marcu, 
19 Water B ° epee th 
Nitrate of silver . (4 ‘ 
Binarseniate of potash . ‘ 1712 
Arsenite of silver . . i 
Arseniate of lead . é . 174 
Citrate of silver . i se 
Tartrate of lead . 5 179 
Binacetate of copper 
Arseniate of silver . ye 180 
20 Water. F 4 
Todide of cadmium c 
Bi-tartrate of potash c 
Todate of ammonia } 182 
Malate of lead 
Iodide of tin 
Acetate of copper (crys. 6 peat 
Tartrate of lithia and soda i: 184 
Molybdate of lead . 
Tartraté of silver. : 
Pernitrate of copper (dry). 
Chlorate of lead . p i 188 
Protoxide of platinum? . 
Acetate of lead (cryst. 3 ivi 
Iodide of copper . $8 
Molybdate of silver 3 190 
Bitartrate of potash (cryst, ] water) 191 
Quadroxalate of potash . - 192 
Todate of lime’ . ; . ~ 193 
Chlorate of silver . 3 - 194 
Iodide of barium . 195 
Todide of bismuth F 
Todate of soda. : é: pis 
Tungstate of barytes . . 
Benzoate of barytes . ‘} i” 
Benzoate of bismuth’  . - 
Mercury . . } 200 
Gold 4 Me “ 
Binacetate of copper (cryst.3 water) 207 
Todate of zinc. ; Py 
Protoxide of mercury. 
208 
— gold. . . r 
Potash-tartrate of ammonia J 
Subacetate of eepper _ . . see 
Phosphuret of mercury 212 
Todate of potash . - 213 
Tartrate of anne oui , 214 


1824.] Jol, Beaufoy’s Astronomical Observations. 197 
Peroxide of mercury : - 916 | Alum (dry) 4 - : 
\ 262 


Protosulphuret of mercury Periodide of phosphorus . . 
Prototartrate of iron and potash . 218 | Protonitrate of mercury . : 
Peroxide of gold ? . - 224 F 

Perchloride of mercury. } 

i 2 
aedid> of lead”. 5 hii Perphosphate of mercury . . ' 
Benzoate of lead . ° ‘} 939 
Bi-sulphuret of mercury . ’ Sub-binacetate oflead . - 214 
Iodide of silver. j . a5 | Todate of lead . * 217 
Pisdeiliside! of mercury” ;) ale Iodate of silver. . « 283 
— -god . . Bi-persulphate of mercury ‘} 296 
Tungstate of silver ‘ } aah Chloride of gold and sodium 
Reimes of silver. 4 ; Pernitrate of mercury . - 324 
Todate of baryta . . . 243 } 

Todate of bismuth. ‘ . 245 | Protiodide of mercury. ‘ 395 
Id. . . 

Sulphuret of gold ? . ¥ 248 a 

Protosulphate of mercury. ° 


Crystallized chloride of gold a 368 
Crystallized persulphate of copper | 950 sodium (8 water) - 4 


(10 water) Subtriatacetate of lead. . 386 
By-cyanuret of mercury . . 252 | Periodide of mercury : » 459 
Persulphate of mercury . . 256 | Alum (crystallized 25 water) - 487 


ArticLe VIII. 


Astronomical Observations, 1824. 
By Col. Beaufoy, FRS. 


Bushey Heath, near Stanmore. 


Latitude 51° 37’ 44°3” North. Longitude West in time 1’ 20-93”. 


Jan, 11. Emersion of Jupiter’s on 6» 07’ 47” Mean Time at Bushey. 
6 09 O8 Mean Time at Greenwich. 


satellite.» ...seeseeeeerees 
In contact with et 10h 14! 45” 
Jan, 26.* Jupiter’s third satellite. planet’s limb. .. M.T.Bushey. 
Immersion. .....- 10 25 10 
Jan, 29. Emersion of Jupiter’s first § 9 25 33 Mean Time at Bushey. 
satellite. .....26+ .0s-s-eee- 9 26 54 Mean Time at Greenwich, 
Jan. 31, Emersion of Jupiter’s second §11 21 36 Mean Time at Bushey. 
satellite...... -+- ceevecee 11 22 57 Mean Time at Greenwich. 
Feb, 1. Jupiter’s fourth §Immer. 74 48’ 35” M.T.Bushey —74 49' 56” M,T.Gr. 
satellite. ... 5 Emer. 9, 59 36 10 O 57 
Feb. 11. Immersion of 2 « Gemini by? g 3; 47-6 Siderial ‘ime. 


Feb. 14. Emersion of Jupiter’s first § 7 43 56 Mean Time at Bushey. 
satellite ...-.+++- gb Ae tinicy .2 7 45 17 Mean Time at Greenwich. 


* According to the Nautical Ephemeris, the eclipse of this satellite took place at 
13 18’ 35”; but the satellite immerged behind the planet, at 10" 26’ 31” Greenwich 
time, making a difference of 2" 52’ 04”, 


198 Mr. Cumberland on [MArcH, 


sites ArticLE IX. 7 
On Animal-Remains found in Caves, By G. Cumberland, Esq. 


(To the Editor of the Annals of Philosophy.) 


SIR, . Bristol, Dec. 29, 1824, 


When, in the Annals for February last, you did me the 
favour to publish my remarks on the enigmatical cave at Picker- 
ing, which has given nse to so many unsatisfactory conjectures, 
I confess I was carried away with the then prevailing opinion, 
that the remains of the animals found there had been localized to 
the spot, and their assembling there for safety was in that case 
not improbable at the rising of waters of the general flood. But 
[ have since felt, that the objection founded on climate is insur- 
mountable, and that they could not have been dragged there by 
the hyznas is now, I believe, the most general behef; for not to 
insist on what Dr. Knox asserted at the Wernerian Lectures, 
reported in the Physical Journal, No. 16, viz. that the hyenas of 
southern Africa are not in the habit of conveying their prey 
away into dens, it seems impossible to-reconcile to reason that 
they should have found such various animals near together, as 
the elephant, rhinoceros, ox, horse, hippopotamus, tiger, bear, and 
wolf; or, if they had, that they should have been able to effect 
such a labour,so much beyond their united strength, or to have 
destroyed all the skulls by even their forcep jaws; neither can 
any one be made to believe, could all this be proved, that such 
animals as these antediluvian hyenas are described to be in point 
of magnitude, would have left even the smallest remains of such 
small bones as those belonging to the rat, mouse, raven, pigeon, 
and lark. Ducks and partridges would have been but a mouth- 
ful to them, and it is not very easy to imagine by what means 
they could be able to catch them any more than rabbits and 
hares. . 

Let us suppose the gnawed marks on the bones to be esta- 
blished by comparison ; it proves nothing of their having been 
gnawed where they were found; and as to the polish acquired by 
their feet and hair passing over them, that really must always 
be considered as conjectural, and proves nothing as to locality. 

Admit even that a considerable portion of original gelatinous 
matter (as has been asserted) remained, it could only show that 
the period since the destruction of these animals had not been 
very extended, not that they died there. Again, ifno skull was 
left entire, but only chips found, and solid parts of bones, or 
angular fragments projecting through the stalagmite above, we 
should be a little cautious in naming so many species, and varie- 
ties of species, of small animals :—even Messrs. Cuvier and 


1824.) Animal Remains found in Caves. 199 


Clift might startle at this difficulty one would think. But as 
this is a subject on which so few are competent to decide, and 
so much has beer advanced on the continent by supposed infal- 
lible judges, that we must be silent on that head; only it does 
seem strange, that if some are so evidently gnawed, more are 
not so; and I do not find one in that supposed state among the 
immense mass that Mr. Cottle has collected from Oreston ; and 
as some one must have been left if this was their den of slaugh- 
ter, why have not their skulls been found—at any rate that of the 
lastsurvivor ? Stress has been laid on these bones not having been 
rolled, but I think that could not have been, or pebbles found 
with them, in the places where they are found; for if granite 
rocks have been proved to have been removed by water hundreds 
of miles, surely bones floating in masses might have been con- 
ducted by currents from very distant parts from those where we 
find them, and being lighter they would not have mixed: with 
gravel or beach stones at the retreat of the waters, but probably 
washed up with mud, and entangled in each other, they fell into 
these cavities on the retreat of the waters, or were carried in by 
whirlpools, so as, after receiving many fractures, to be deposited 
at length in a level bed such as they were discovered in, resting 
on the original stalagmite, and when all was dry, receiving in the 
course of ages an additional covering of a similar deposition. 
This conjecture accounts also for their intermixture, as well as 
fractured state ; for rolled bone, and wood, or ivory, are only 
invariably found among ancient beaches of gravel such as now 
lies below the land at Shorehampton, near Bristol, and which 
has produced many specimens whenever the mine is opened to 
gravel Lord de Clitford’s park there, a deposit undoubtedly left 
there on the borders of the Severn channel at the retreat of the 
waters of the flood. 

To come at the truth will be difficult, and therefore we are 
obliged to Prof. Buckland for the great pains he has taken in 
bringing forward all that has hitherto been known gn a subject 
that seems so strongly to corroborate the Scripture history of the 
Deluge; but we must not in the history of natural events look 
toe any authority but that which is founded on circumstances 
applicable to the event under discussion. 

Yours, &c. G. CUMBERLAND. 


a 6" os U See — — 


(Marcu, 


Mr. Giddy’s Comparative Thermometrical Table. 


200 


a at 


The Thermometrical Register at Pisa 


iles E.S.E. from the city. 


s near as possible the same. 
was kept at the Observatory, 6 m 


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1824.] On the Volcanos at present in Activity. 201 


ARTICLE XI. 


An Account of the Volcanos at present in Activity, 
By M. Arago.* 


Some persons having appeared desirous of seeing in the 
“ Annuaire” an account of the volcanos now in activity, I 
engaged to write it, but without having sufficiently reflected, as 
I afterwards discovered, on the difficulty of this work. The 
details with which most travellers have furnished us on these great 
phenomena are incomplete, and extremely vague. In the esti- 
mation of one, those parts of the earth from which a little smoke 
arises, or upon which a few sparks are perceived, are volcanos ; 
another gives this name only to mountains which incessantly 
cast forth torrents of lava, burning matter, and ashes. The 
first will insert in his catalogue the trifling flames of Pietra-Mala, 
Barigazzo, Velleia, of Persia, and Caramania; the second 
will place Santorini itself in the class of solfaterras. To this diffi- 
culty must be added the still greater one of determining what 
distance should separate two craters, that they may be considered 
as two distinct volcanos. At Tenenfte the eruption of 1706 
broke out at an opening two leagues distant from the Peak ; 
that which destroyed Garachico burst out at an opposite side, 
and at a point a league and a half distant from the Peak ; there 
- were then three leagues and a half between the two openings 
without their being considered as belonging to two distinct vol- 
canos. But, shall we consider the isle of Palma, where there 
was an eruption of lava in 1699, as containing a volcano separate 
from that of Teneriffe? Ought the destruction of a third of the 
isle of Lancerote in 1730 to be considered as the effect of a 
lateral eruption of the volcano of the Peak, or of a separate 
volcano? Analogous questions present themselves at every step, 
and the means are wanting to answer them. I should, therefore, 
have omitted printing this notice in the Annuaire, from which it 
is desirable to exclude every thing that does not possess a cer- 
tain degree of precision, if I had not had the advantage of con- 
sulting the two persons to whom the physical history of the 
globe is best known, MM. de Humboldt, and Leopold de Buch. 


Volcanos of Europe and the adjacent Islands. 


Vesuvius ; kingdom of Naples. 
Etna; Sicily. ' 
Stromboli ; Eolian islands. 
Hecla; Iceland. 

Krabla; northern part of Iceland. 
Katlagiaa-Jokul ; Iceland. 


* From L’ Annuaire pour lan 1824. 


202 _M., Arago on the [Marcu, 


Eyafialla-Jokul ; Iceland, south-east of Hecla. 
Eyrefa-Jokul ; ditto. 

Skaptaa-Jokul ; ditto. 

Skaptaa-Syssel ; ditto. 

Wester-Jokul; ditto. 

Esk ; island of Jean Mayen. 


Vesuvius, the only volcano now in activity upon the conti- 
nent of Europe, has been repeatedly extinguished, and in com- 
bustion. Before the reign of Titus, this mountain was much 
visited, and is mentioned only on account of its extraordinary 
fertility. Vitruvius and Diodorus Siculus, who lived in the time 
of Augustus, do indeed state, upon historical authority, that 
Vesuvius had formerly vomited fire like Etna; but these state- 
ments refer to remote and nearly forgotten periods. 

It was on the 24th of August in the 79th year of the Christian 
era, that Vesuvius was rekindled. This eruption buried the 
cities of Herculaneum, Pompeii, and Stabiea; and it will be 
recollected that Pliny, the naturalist, perished, as the victim of 
the ardent curiosity with which he was inspired by this interest- 
ing phenomenon. 

After the eruption of the year 79, the volcano remained in 
combustion for 1000 years ; still later it appeared to be totally 
extinct ; so that in 1611, the mountain was inhabited almost to 
the summit, and there were a copse and small lakes in the inte- 
rior of the crater. . 

Etna.—Pindar, who lived in the year 449 before the Christian 
era, mentions Etna as being in a state of combustion. Thucy- 
dides has preserved some details of the eruption which occurred 
476 years before Christ. As to Homer, he does not even men- 
tion the mountain, although in the Odyssey he disembarks 
Ulysses in Sicily. The silence of a poet who has always been 
admired for the extent and universality of his knowledge, has led 
to the probable supposition, that long before the time of Homer 
the volcano was extinct. The Roman historians, both of the 
middle ages and of modern times, have described so great a 
number of eruptions of Etna, that it probably would not be diffi- 
cult to prove that during a period of 2000 years it was never 
extinct for a whole century. 

Seneca has observed that volcanic mountains do not supply 
the combustible matter of the fire, but that they merely give it 
vent. Father Kircher seems to have commented on these words 
of the Roman philosopher, when in the fourth book of his Sub- 
terranean World, he has advanced the opinion that the matter 
ejected from Etna, would, if formed into one mass, form a moun- 
tain 20 times larger than Etna itself. The work of Father 
Kircher appeared in 1660. Nine years afterwards a single 
eruption of the volcano, covered with lava a space of six leagues 
long, two and a half in width, and of a mean depth of at least 


1824.) Volcanos at present in Activity, 203. 


100 feet. According to Dolomieu the eruption of 1755 produced 
a current of lava four leagues in length, half a league wide, and of 
at least 200 feet mean depth. In reflecting on the immense void, 
that eruptions so considerable must have produced in the moun- 
tain and at its base, is there not yet cause for wonder that erup- 
tions, like that of 1787 for instance, should still occur at the 
summit, the height of which is 10,600 feet above the level of 
the sea. 

Stromboli—M. de Humboldt has remarked that the activity 
of volcanos appears to be in the inverse ratio of their mag- 
nitude. Stromboli is a striking confirmation of this principle ; 
it is perpetually sending forth Hames ; but with this peculiarity, 
that for 2000 years it has not, strictly speaking, made any erup- 
tions, although the nature of the surrounding country shows, that 
it was formerly subject to them. Mount Epomea, in the island 
of Ischia, ought not to be considered as a volcano, but it would 
probably become one if Stromboli were extinct. 

Santorini was the site of a great eruption in 1707, As this 
phenomenon has not been repeated, and as the island exhibits 
no crater, of the true chimney of a volcano, I have not inserted 
it in the catalogue. 

Volcanos in Fesietidt the last eruption of Hecla occurred in 
1766. The eruptions of this volcano, according to Sir George 
Mackenzie, are not ia general so extensive as they have been 
represented. The most recent eruption of Krabla oceurred in 
1724. In 1756, between January and September, there were 
five eruptions of Kattlagiaa; since which period this volcano 
remained perfectly tranquil, until the 26th of July, 1823, when 
strong eruptions occurred accompanied with earthquakes. 

Eyajfialla-Jokul, which appeared to be extinct for more than 
a century, emitted torrents of flames from its summit on the 20th 
of Dec. 1821. Eye-witnesses report that the column of fire was 
still visible on the Ist of Feb. 1822, and that it projected stones 
weighing from 50 to 80 pounds, with so much force as to cause 
them to fall at a distance of two leagues from the mountain. The 
mountain burst at its base on the 26th June, 1822, and a great 
quantity of lava issued from it. 

Lyrefa-Jokul.—The last eruption occurred in 1720 

Skaptaa-Jokul and Skaptaa-Syssel.—The eruptions of these 
two volcanos, which occurred in 178 , occupy the first rank in 
phenomena of this nature; they ravaged an immense extent of 
country. During a whole year after the eruptions, the atmo- 
sphere of Iceland was mixed with clouds of dust, which the sun’s 
rays scarcely penetrated. 

Wester-Jokul.—An eruption of ashes and stones happened in 
January, 1823. 

Esk.—This volcano was discovered and visited in 1817 by 
Mr. Scoresby. It made an eruption at the end of April, 1818 ; 


204 M, Arago on the [Marcu, 


columns of smoke arose every three or four minutes to the height 
of 4 or 5,000 feet. 


Islands near the Continent of Africa. 


~ No volcano, strictly so called, is with certainty known to exist 
in Africa; but the islands which geographers consider as the 
dependancies of that continent, contain several volcanos. 

1 Pico.—Island of El Pico, Azores. 

Peak of Teneriffe—Island of Teneriffe. 

Fuego.—Island of Fuego, Archipelago of Cape Verd. 

Les Trois Salasses.—Isle of Bourbon. 

Zibbel-Teir.—Island of this name, Red Sea. 

- Ascension Island. 

Ei Pico.—This mountain is the only one of the Azores which 
rises in the form of a cone; the only one entirely composed of 
trachyte, and the only one in which there is a vent always open. 
Geologists are agreed in the opinion, that the great currents of lava 
which flowed in 1812 in the Isle of St. George were the results 
of a lateral eruption of the volcano of El Pico. They explain in 
the same way the sudden formation of an isle in the neighbour- 
hood of St. Michael in 1811. This isle was taken possession of 
in the name ef the King of England, by the Captain of the 
Sabrina, who witnessed the event ; it has since totally disap- 

eared. The part of the sea in which this isle arose is not less 
than 80 fathoms deep. 

Peak of Teneriffe——This volcano appears to be much more 
agitated on its sides than at its summit. Neither flames 
nor lava have issued from it from time immemorial, nor any 
smoke which could be seen at a distance. The last erup- 
tion, that of 1798, took place laterally in the mountain of Cha- 
horra. It continued for more than three months. Various 
fragments of rocks, of very considerable size, which the volcano 
projected from time to time into the air, occupied, according to 
the observations of M. Cologuan, from 12 to 15 seconds in fall- 
ing. Teneriffe had suffered no eruption for 92 years, until that 
of 1798, which began suddenly on the 9th of June. 

Immense torrents of lava flowed upon the island of Palma, 
25 leagues distant from the Peak, through new volcanic open- 
ings which were formed in 1558, 1646, and 1677. The isle of 
Lancerote was also destroyed by an eruption in 1730. 

Fuego.—Scarcely any details are known respecting the isle of 
Fuego. It would appear, in opposition to an opinion formerly 
adopted, that no other active volcanos exist in all the Archipe- 
lago of Cape Verd. 

Volcano of Bourbon.—There are few volcanos which are in a 
state of greater activity than that of Bourbon. Its last eruption 
occurred on the 27th of Feb. 1821. It formed three currents of 
lava, which opened a passage in the summit of the mountain, a 


1824.] Volcanos at present in Activity. 205 


little below the true crater. One of these currents did not 
reach the sea till the 9th of March. Some time after the 
explosion, there fell in many parts of the island, a shower 
composed of black ashes, and long flexible threads of glass, 
resembling golden-coloured hair... This phenomenon, which was 
chiefly noticed in 1766, has been considered as peculiar to the 
volcano of Bourbon ; but Hamilton states, that he found similar 
glassy filaments mixed with the ashes by which the atmosphere 
of Naples was obscured during the eruption of Vesuvius in 
1779. 
Those persons who have not particularly studied volcanic 
heenomena will probably be surprised to learn, that in 1821 the 
ignited lava of the volcano of Bourbon should be six whole days 
in traversing, upon inclined ground, the short distance from the 
crater to the sea. But it ought to be observed that lavas are not 
perfect fluids, and that in proportion as they cool, their progress 
must slacken. [n 1805, M. de Buch observed a torrent of lava 
issue from the summit of Vesuvius, and reach the sea shore in 
three hours ; but the history of volcanos offers few instances of 
similar rapidity. 

In general the motion of lavas is slow; those of Etna are 
whole days in flowing a few feet in the flat lands of Sicily. The 
external part is sometimes fixed and stationary ; while the cen- 
tral mass, still fluid and incandescent, continues to flow. The 
great viscidity of the lavas, when slightly cooled, occasions them 
to be extremely thick on the edges even when they flow ina 
level country. 

Zibbel- Tier, according to Bruce, is in 152. degrees north latitude. 

The summit of the mountain has four openings, through which 
there issue thick columns of smoke. 
_ Few details are known respecting the volcano of Ascension 
Island. As to that of Madagascar, which is stated to project 
immense columns of aqueous vapour visible at a distance of 10 
leagues, its existence has not appeared to me sufficiently proved 
to induce me to insert it in the catalogue. 


VoLeanos Or AMERICA. 


North-west Coast. 
Mount Saint-Elia. . 
Mount del Buen Tiempo. 
Volcan de las Virgenes ? 


Mexico. 
Orizaba or Citlaltepetl. 
Popocatepetl or volcan de la Puebla. 
Tuxtla. 
Xorullo. 
Colima. 


206 


Volcano of Sotara. 


M. Arago on the [Marcu, 


Guatimala and Nicaragua. 
Volcano of Soconusco. 


Sacatepeque, 

Hamilpas. 

Atitlan, 

Fuegos de Guatimala. 

Acatinango, 

Sunil, 

Toliman, 

Isalco. 

Sacatecoluca, near the Rio del Empa. 
San-Vicente 

Traapa. 

Besotlen. 

Cociyina, near the gulf of Conchagua. 
Viego, near the port of Rialexo. 
Momotombo. 

Talica, near San-Léon de Nicaragua. 
Granada. 

Bombacho. 

Papagallo. 

Barua, south of the gulf of Nicoya. 


a Group of Popayan. 


Purace 
Pasto. 
Rio Fragua. 


Volcano of Cumbal. 


Volcano of Antisana. 


Chiles loo of the province de 
Azufral. astpe 
Group of Quito. 
Rucupichincha. 
Cotopaxi. 
Tunguragua. 
Sangay. 


Volcano of Arequipa (Peru). 


Group of Chili. 


Volcano of Copiapo. 


Coquimbo. 
Choapa or Lisnari. 
Aconcagua, 
Santiago. 

Petoroa. 


los 


1824.] Volcanos at present in Activity. 207 


Chillan. 
Tucapel. 
Callaqui. 
Chinal. 
Villa-Rica. 
Votuco. 
Huaunauca. 
Huaiteca. 
San-Clemente. 


Antilles. 


Volcano of Saint- Vincent. 
Saint-Lucia. 
Guadaloupe. 


It is unknown whether the volcanos of the north-west coast 
haye recently made any eruption. 

Orizaba is 17,500 feet high ; the streams of lava observed on 
the sides of the mountain remove every doubt as to its volcanic 
nature; but no recent eruptions are known of. 

Popocatepet! has smoked ever since the conquest of Mexico. 
Cortes relates indeed, that he ordered ten of his most courageous 
companions to reach the summit, and to discover the secret of its 
smoking, which he wished to communicate to Charles V. This 
volcano is always burning, but it has projected lava from time 
immemorial. Its height measured by M. de Humboldt is 17,600 
feet. 

The volcano of Txt/a is situate to the south-west of Veracruze. 
Its last very considerable eruption occurred in 1793. The 
ejected ashes were then carried as far as Perote, a distance, in a 
straight line, of 57 leagues. 

Xorullo—M. de Humboldt remarks, that the catastrophe 
which gave rise to the volcano of Xorullo, is, perhaps, one of the 
most extraordinary physical revolutions which the annals of 
our planet contain. In the middle of a continent, at 36 leagues 

distance from any active volcano, the earth rose to the extent of 
three or four square miles in the form of a bladder, on the night 
of the 28th and on the 29th of September, 1759. In the centre 
of a thousand inflamed cones, six mountains from 1,300 to 1,700 
feet high above the original level of the surrounding country, sud- 
denly arose. The principal of them is Xorullo, the height of 
which is 1,700 feet. Its eruptions continued without cessation 
until the month of February, 1760. The subterranean fire is now 
very active. . 
he volcano of Colima, the most western of those in New 
Spain, ejects now hardly any thing but ashes and smoke. Its 
height is about 1,000 feet. 
’ M. de Humboldt has made the important observation, that the 
Peak of Orizaba, Popocatepetl, Colima, and other extinct vol- 


208 _M. Arago onthe ; [Marcn, 


canos, are ina line, as if they proceeded from one fissure or vein, 
in a direction perpendicular to that of the great chain of moun- 
tains which traverses Mexico from the north-west to the south- 
east. 

The volcano of Xorullo just mentioned interposed itself in 
1759 in the line of the ancient volcanos. This curious arrange- 
ment, which we shall observe in other places, exists also, accord- 
ing to M. Daubuisson, in the extinct volcanos of Puy-de-Dome. 

‘he volcanos of Guatimala which have most lately erupted, 
are Los Fuegos of Guatimala, Isalco, Momotombo, Talica, and 
Bombacho. These active volcanos, and the sixteen others 
whose names have been mentioned, are contained between the 
10° and 15° of north latitude, -and in a line corresponding with 
the general direction of the Cordilleras. 

The connexion of the volcano of Pasto with those of the pro- 
vince of Quito was shown in astriking manner in 1796, A thick 
column of smoke had existed from the month of November, 
1796, from the volcano of Pasto; but to the great surprise of all 
the inhabitants of the city of that name, the smoke suddenly dis- 
appeared on the 4th of February, 1797. This was precisely the 
moment at which, at 65 leagues further south, the city of Rio- 
bamba, near Tunguragua, was destroyed by a tremendous earth- 

uake. 
Antisana is 20,000 feet high. No eruption of this volcano is 
known to have happened since the year 1590. 

The last eruption of Rucupichincha occurred in the year 1660. 

Cotopazi made an eruption in 1742, while the French acade- 
micians were measuring a degree of the meridian in its neigh- 
bourhood. The column of flames and of burning substances 
rose 500 toises above the mountain. The snows which had been 
heaped up during two centuries, from the summit of the mountain 


to 500 toises below it, were melted en masse ; the torrent which ° 


it occasioned rushed into the plain with impetuosity, forming 
waves from 60 to 100 feet in height. At a distance of three or 
four leagues from the mountain, the rapidity of the water, in the 
opinion of Bouguer, was from 40 to 50 feet ina second. Six 
hundred houses were destroyed, and 700 or 800 persons were 
drowned in the torrent. The eruptions of 1743 and 1744 were 
still more disastrous. 

Bouguer and La Condamine, having examined the remaining 
traces of the great eruption of 1533, the memory of which is 
preserved from generation to generation among the inhabitants, 
they found that the volcano had ejected to a distance of more 
than three leagues, stones containing from 70 to nearly 100 
cubic feet, or. to use the expression of La Condamine, larger than 
the cabin of an Indian. The origin of these stones was unques- 
tionable; they formed lines in every direction towards the 
volcano. It does not appear that Vesuvius has ever ejected 
stones to more than 4,000 feet high. 


1824.) — Volcanos at present in Activity. 209 


Tunguragua made an explosion in 1641, 

5 Sangay has remained constantly burning ever since the year 
728. 

Chimboraxo does not appear in the list; for although no one 
disputes its volcanic nature, no account of its eruption has been 
preserved. The case is the same with Carguairazo. The inun- 
dation of mud which in 1698 covered 18 square leagues of land 
was not the effect of an eruption, properly so called. When 
Carguairazo fell, the waters which it concealed in its bosom were 
precipitated impetuously into the plain, and occasioned the dis- 
asters mentioned by the historians of America. 

There are in some maps of Chili more volcanos marked than I 
have placed in the catalogue; but I felt it proper to confine 
myself to what appeared to me to be most certain; and I ought 
further to.add, that of the sixteen volcanos of this country whose 
names have been given, several are now probably extinct. 
Peteroa made an eruption in 1762 ; Vil/a-Rica in 1640, &c. 

-In looking at the coast of America, it will undoubtedly have 
occasioned surprise to find no volcano, either between the 2d 
and 16th degree of south latitude, or between the 17th and 27th 
degree. Ifthe volcano of Arequipa did not exist, the range of 
Guatimala and Nicaragua, the groups of Popayan and los Pastos 
would be separated from the long track of Chili, by a space of 
25° of latitude, totally without volcanos. Although Peru con- 
tains only one volcano, there are few countries in the world 
where earthquakes are more severely felt, and where they make 
sreater devastation. They frequently occasion the formation of 
immense fissures, over which bridges are built to preserve com- 
munication between different provinces. One of these fissures, 
after the earthquake of 1746, was a league in length, and nearly 
seven feet wide. 

The volcano of the island of St. Vincent ejected lavas in 1718 
and 1812, The ashes of the latter eruption were carried by the 
upper counter current of the trade winds, to the island of Barba- 
does, 30 leagues to the west. 

At St. Lucia, there is a continual formation of sulphur, occa- 
sioned by the condensation of the vapours, which rise from the 
crater called Oualibou, at a height of 1200 to 1800 feet. Jets of 
hot water are also observed there. 

The volcano of Guadaloupe, at a height of about 4,800 feet, 
made its last eruption in 1797. It then ejected pumice, ashes, 

and clouds of sulphureous vapours. 

I shall conclude these notices relative to the volcanos of 
America, by remarking, that no active volcanos occur either at 
Buenos Ayres, at Brazil, Guyana, or on the coast of Venezuela, 
‘or in the United States; that is to say, at any point of the coast 
to the east of this great continent. ‘There exist to the east of the 
Andes only three small volcanos situate near the sources of the 

New Series, vou, vii. Pp 


210 M. Arago on the [Marcn, 
Caqueta, the Napo, and the Morona, and which, according to 


M. Humboldt, probably result from the lateral action of the vol- 
canos of Popayan and Pasto. 


Volcanos of Asia. 

Elburs, in Persia. 

Tourfan, central region of Asia; latitude 43° 30’; longitude 
orerl': 

Bisch-Balikh.—Ibid. Latitude 46° 0’; longitude 76° 11’, 

Avatscha.—Kamtschatka. 

Tolbatchick.—Ibid.; and three other volcanos more consider- 
able than the two last. 


Kourtle Islands. 
Nine active volcanos, according to Kracheninnikou. 


Aleutian Islands. 


Four volcanos at Ouminga, Ounalaska, Omnak, and Ourimack. 
The last made a great eruption in 1820, 


Islands of Japan. 


Ten volcanos. The island of Niphon, which is the most 
extensive, contains three. According to the evidence of 
Kcempfer, several of the volcanos of Japan are subject to very 
violent eruptions. | 

Islands of Lieou-Kievu. 

The Sulphur Island emitted a thick sulphureous smoke, when 
the Lyra, commanded by Capt. Basil Hall, passed near it on the 
13th of Sept. 1816. 


Elburs has been mentioned by several travellers as a volcano 
in activity ; but the fact is doubtful, and at any rate there is no 
evidence to prove that it has recently made any eruption. 

The mountains of Tourfan and Bisch-Balikh are represented 
as continually emitting flames and smoke. It is stated that the 
Kalmucks collect sal ammoniac there, which they export to 
the different countries of Asia. 

Avatscha made an eruption in 1779, while Capt. Clerke was 
iu the harbour of St. Peter and St. Paul. In 1787 La Peyrouse 
aud his companions saw flames and smoke continually at the 
summit of the same mountain. | 

An eruption of Tolbatchink occurred in 1739. A third voleano, 
and more considerable than the two others, but of which Capt. 
Clerke does not give the name, ejected a permanent column of 
smoke from its summit. Since this, two new volcanos have 
made eruptions at Kamtschatka. vet 


1824,} Volcanos at present in Activity. 211 


OcEANIA. 


Philippine Islands. 


Five active volcanos. Travellers have hitherto given only 
vague accounts of the volcanos of the Philippines. A/bay is the 
name of that in the island of Luconia; Taal is situate to the 
south of Manilla; Fuego to the south of Luconia; Mindanao 
also contains a volcano. 


Borneo. 


Geographers agree in assigning volcanos to Borneo, but with- 
out stating either their number or situation with precision. 


Barren Island. 


Barren Island contains a very active volcano of nearly 4000 
feet high, which frequently ejects immense columns of smoke, 
and red-hot stones, of the weight of three or four tons. Its lati- 
tude is 12° 15’. Its distance from the most eastern of the 
Andaman Islands is 15 leagues ; the island is not more than six 
leagues in circumference. 

Sumatra. 


Four volcanos are marked by Marsden in his map of Sumatra ; 
but as the interior of the island is very little known, there proba- 
bly exist a greater number. 
' Java. 


The island of Java contains a great number of volcanos 
arranged in right lines; their names and the dates of their erup- 
tion are the following: 


Salak, 1761 ; eruption. 
Tankuban, 1804 ; sulphureous vapours. 
Guntur, 1807 ; eruption. 
Gagak, —— ; partial combustion. 
Chermai, 1805; eruption. 
Lawn, 1806 ; sulphureous vapours. , 
_ Arjuna, ; permanent column of smoke, 
‘Dasar, 1804; eruption. 
Lamongan, 1806; eruption. 
Tasher, 1796 ; eruption. 
Klut, 1785 ; eruption. 


_ Arjuna is 10,614 feet high; this mountain is not, however, 
the most lofty in the island. 

Mount Papandayang was one of the principal volcanos of 
the island; but it is no longer in existence. Between the 11th 
and 12th of August, 1772, after the formation of a great lumi~ 
nous cloud, the mountain totally disappeared in the bowels of 
the earth. It has been estimated that the land thus ingulphed 
was 14 miles long and 6 miles broad. 

P2 


212 M. Arago on the [Marcu, 


Sumbawa. 


Tomboro, in Sumbawa, made a violent eruption in 1815. The 
detonations were heard in Sumatra at places 300 leagues distant 
from the volcano in a right line. 


Flores. 
The volcano of this island was seen by Bligh. 


Daumer. 
Daumer contains a volcano. 


Dampier, in 1699, saw a volcano constantly in combustion 
on a small island between Timor and Ceram. 


Island of Banda, 


Goonoung- Api, in Banda, made a violent eruption on the 11th 
of June, 1820, during which it ejected red-hot stones as large as 
the habitations of the natives. Several of these stones rose to a 
height double that of the mountain. 


Moluccas. 

In the island of Ternate, there is a burning volcano. Tidere 
is the name of one of these islands, and of an active volcano 
which it contains. 

According to geographers, Celebes contains several active 
volcanos ; they do not mention their situations. ‘ 

Sanguir.—Between Mindanao and Celebes, is one of the 
greatest volcanos of the globe. 


New Guinea. 


Two volcanos were burning, in 1700, in the island of New 
Guinea, when Dampier explored the coast of it. 


New Britain. 


There are three volcanos in the Archipelago of New Britain. 
D’Entrecasteaux saw an eruption of that which is situated in 
latitude 5° 32’, and 145° 44’ of east longitude, the 29th of June, 
1793. <A torrent of lava flowed into the sea, and formed differ- 
ent cascades. Lemaire and Schouten formerly saw an eruption 
of the same volcano. 

Lhe Archipelago of 0 Espiritu Santo—The island of Amhrym, 
in this Archipelago, which Bougainville called the Great Cyclades, 
and Cook the New Hebrides, contains an active volcano. That 
of Tanna is also voleanic. In Aug, 1774, Cook witnessed one 
of its eruptions. The volcano cast forth flames, ashes, and 
stones of a size at least equal to that of the great, boat 
belonging to his ship. In April, 1793, d’Entrecasteaux and his 
companions saw a thick column of smoke on the top of the 
mountain. 


1824.] Volcanos at present in Activity. 213 


Archipelago of the Ladrones. 

There are nine volcanos in this Archipelago; but I do not 
know if they are all to be placed in the class of those which are 
still burning. 

Sandwich Islands. 

The Mouna-Roa, in Owhyhee, appears to be, or at least to 
have been a volcano; but is it the same as the mountain of 
Mowee, which Vancouver has called the Volcanic Mountain. 


The Island of Amsterdam. 


The island of Amsterdam was burning when D’Entrecasteaux 
saw it in the month of March, 1792. Some attribute this phe- 
nomenon to the effect simply of a great fire; others have con- 
cluded that the island contains a voicano. 


The Islands of the Marquis de Traversé. 


The islands lately discovered by the Russian navigators, 
between New, Georgia and Sandwich Land, contain an active 
volcano. There exists one equally so in Sandwich Land. 


General Summary. 


Number of active volcanos. 
—S ee ee 


On the Continent. In the Tae Total. 
Europe..... ase: BARRA 0-14: AAS 12 
Weare ST) St) eee ss ee PAE Mes 
amiptied . .. FO seitiMls » <0 OMe en woes: 61 
Aas... es 8 on akt ss o  PAMROIE Sia ss 32 
oo ER RR 3 RE oo pales 

67 96 163 


Before I finish this account, I shall remark, that if the two 
volcanos in the central part of Asia are excepted, the existence 
of which may appear doubtful, not one will be found in the pre- 
ceding list which is more than 50 leagues from the sea. It 
seems difficult not to draw the conclusion from this curious fact, 
‘that water acts an important part in volcanic eruptions. 

A phenomenon equally worthy the attention of observers, is 
the propagation of sound which precedes or accompanies erup- 
tions. It has been previously shown, that in 1815 the explosions 
at Tomboro, in Sombrero, were heard at Sumatra, distant ina 
right line 300 leagues from the mountain. M. de Humboldt 
‘states in his excellent work a circumstance nearly as surprising. 
The explosions which announced the first eruption of ashes from 
St. Vincent, did not appear louder to the inhabitants of the 
island than the report of a large cannon, These explosions not- 
withstanding were heard perfectly upon the Rio-Apure, at the 
confluence of Rio Nula, 200 leagues from the voleano, which is 


214 On cértain Instruments formerly used for [Manrcn, 
equal to the distance of Vesuvius from Paris. The report seemed 
so well transmitted by the air, that it was mistaken for the dis- 
charge of artillery, and was the cause of several military move- 
ments in various parts of the American continent. 


ArticLte XII. 


An Account of certain Instruments formerly used for the Purpose 
of Blasting in the Lead Mines of Colonel and Mrs. Beaumont, 
at Allenheads. Communicated by Mr. Thomas Crawhall, of 
Neweastle-upon-Tyne.* 


cs op auy g escoaxy N 


Turse sketches represent an iron instrument found in Allen- 
heads lead mines, supposed to have been formerly used in blast- 
ing, the length of which was 2; or 3 feet ; the upper part having 
since been cut off, there only now remain 6 inches above the 
bended part, which is 14 inch square to the elbow, forming an 
angle of about 10°; is of a cylindrical shape, slightly tapering 
to the other end, which is one inch in diameter. On the out- 
ward side of the angle, along the circular part, is a groove six 
inches in length, of one-quarter inch broad, and of similar depth, 
projected (it is supposed) to receive the train of gunpowder, per- 


’ * From the Archxologia Eliana, vol, i. 


-1824.] the Purpose of Blasting in Lead Mines. 215 


taining to the charge: the application of which has been to 
drive it tightly into the hole bored in the rock above the powder, 
and the upper part fixed by strong timbers placed across the 
top for the purpose of preventing it being thrown out, without 
the desired effect. 

Another instrument of iron, found in the same 
lead mines, differs from the above, in wanting the 
square bar at top, and in place of the hollow on one 
side, is cylindrical, and has a tube, one inch diameter, 
to nearly the upper end, where it is flattened, and 
has a shoulder projecting half an inch on each side, 
resembling the head of a spear, and apparently 
intended for fixing across it bars of iron or timbers, 
to oppose the violence of the ignited gunpowder. 

At the round end of the cylinder is a perforation 
a, communicating through the hollow tube, with 
another at 4, placed for a touch hole on one side, 14 
inch below the shoulder, and 8 inches distant 
from the other end. 

A tradition exists among the miners, that formerly 
strong timbers atid wedges were used for fixing down 
the charges in blasting, to hinder explosion without 
effect ; but no further explanation, as to the mode 
in which this was achieved, is to be obtained, neither 
in regard to the process of charging, nor of the tools 
used. It is highly probable, however, that such 
application might have been, and was adopted, for securing the 
two instruments above described. 

A series of five more of these instruments have been found in 
the same mine, of the respective lengths of 84, 10, 104, and 12 
inches. 

There was also discovered, in opening some old workings at 
the west end of Allenheads lead mines, about a month since 
(Jan. 1820), a tool, formerly used, it is conjectured, for the pur- 
pose of blasting with gunpowder, or rather, in forming a commu- 
nication with it in the rock to be exploded. . The spot where it 
was found is in the Great Limestone there, about 40 feet from 
the surface. The latest record of this place having been wrought, 
was in the year 1716, since which period this part of it has been 
entirely filled up with rubbish and fallings in of the vein, and 
only recently re-opened; when the following (see next page), 

ith some other instruments, were discovered in one of the flatts 
in the limestone. The oldest workmen of the present day do 
not recollect their use, nor did they ever hear of such tools 
employed for the purpose ; they seem, however, to have been 
meant for it, and their application as follows:—After having 
drilled a hole in the rock to be blasted, with a chisel or jumper 
sufficiently deep, the gunpowder is put into the bottom of it, say 
to the depth of three or four inches; next the tool sketched 


216 On certain Instruments formerly used for [MArcu, 


~ dha > 


UOT 


LET TCT 
=== 


i" 


“sarpou] OT 


mre rtcereereneen (1 ¢r¢// ee 


which is round at one end, one inch in diameter, with a hole in 
the centre about one-eighth of an inch, which communicates 
with ancther of the same dimensions, about one and one-fourth 
inches from the other end on the cylindrical side, the opposite 
being flattened from within one inch of the bottom, or circular 
end; to one-third of an inch thick at the other extremity ; this 
hollow cavity appears to have been filled with powder, which, 
when the instrument was placed in the hole, would immediately 
communicate with the charge. In this situation, it is presumed, 
wedges (of wood) were driven against the flat side of the iron 
tube, to resist the force of the gunpowder, 
when fired through the touch-hole marked a, 
by a train or match laid for that purpose. How 
long this has been in disuse is altogether uncer- 
tain, even the name is forgotten: it 2s probable 
a century might since have passed away. 
Nearly in the same spot with the above, to 
which I annex a sketch, a tool of more recent use 
was found, called by the miners the stock and 
feathers; and remembered by some to have 
been occasionally used about fifty years ago, par- 
ticularly in wet situations, where gunpowder 
could not, without great difficulty, be applied. 
A perforation was made in the stratum, say four 
to six inches deep ; placing two thin pieces of 
iron, called the feathers, which are rounded on 


1824.] the Purpose of Blasting in Lead. Mines. 217 


one side and flat on the other, in this hole, the former being 
next to the rock, the wedge or stake was driven between until a 
portion of it split asunder. 
- This wedge also was found near the same place 
with the preceding, of six inches in length, and one 
and one-fourth inches square, tapering to a point, 
having a hole one-fourth inch square, through it, at 
one anda half inches from the top; this, according to 
the reports of very old miners, was intended to receive 
a shall rod of iron, by which, one man held, whilst 
another drove the wedge; but not used during the 
life of any present workman. 

At what period the present method of blasting was 
introduced into these mines cannot be ascertained. A person 
now residing there, recollects to have heard his father (who died 
thirty-nine years ago at the age of sixty-seven) say, although it 
took place before his time, that prior to the pricker and drive-all 
being used, it was so hazardous an experiment, that two men 
were specially appointed, whose province it was to visit the dif- 
ferent workings, for the express purpose of charging and blast- 
ing, after the holes had been prepared. Another, who, as well 
as his father and grandfather before him, has been a pickman 
for sixty years past, has a faint remembrance of hearing very old 
men say, that formerly stemples were employed, but has no 
knowledge as to the process, nor ever saw any other mode prac- 
tised than the present ; but that the stock and feathers had been 
in use during both the lifetimes of his father and grandfather. 


ArTIcLE XIII. 


Inquiry how far the Opinions generally entertained of the Inuti- 
lity of Observations of the Eclipses of Jupiter’s Third and 
Fourth Satellites, are well or ill founded. By J. South, FRS. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Blackman-street, Feb, 23, 1824. 


To the advancement of natural knowledge there is probably 
no one thing so inimical as prejudice, and perhaps there is no 
science, which has suffered so much from this common enemy to 
all, as has astronomy. ‘To enumerate the various mischiefs 
which this busy fiend has inflicted upon this peculiar science 
would be foreign to the present purpose. Suffice it to say, its 
baneful effects have been not only felt by physical, but also by 
practical astronomy. 

__ After the discovery of telescopes (as pa expected), we find 
them employed upon Jupiter and his satel 


ites, more than upon any 


218 Mr, South on the Eclipses of (Maren, 


other object. The phenomena of four moons were naturally interest- 
ing, nor was the inquiry unattended with important consequences. 
The velocity of light repaid the labours of Roemer, and the eclipses 
of the satellites opened a new, easy, and at that time a compa- 
rative accurate mode of determining the differences of longitude 
of distant stations. Hence astronomers were taught to look out 
for these phenomena, and their observations became recorded : 
in proportion, therefore, as the opportunities of observing these 
eclipses were more or less frequent, were they supplied with 
means of improving their tables ; ,till at length something like 
accuracy was arrived at, as far as relates to those of the first and 
second satellites ; to this also we must add another cause which 
will be found in the nature of the instruments at this time em- 
ployed ; for the rapid motion of these two satellites is such, that 
the intervening period between their first entrance into the 
shadow, and their complete obscuration by it, is short; hence 
telescopes were able to give something like uniformity to the 
observations of various observers—in short, theory and practice 
assisted each other. 

But not so with the outer satellites ; eclipses of them were 
comparatively of very rare occurrence, and the time of their 
entering the shadow till their complete obscuration being many 
times greater than in the case of the two first satellites, the 
observations became more difficult ; and the instruments were 
inadequate to the purposes for which they were now wanted: 
observations, therefore, of different observers differed considera 
bly with each other, and theory and practice were everlastingly 
at variance. Hence observations of these satellites came into 
disrepute, and almost into disuse. 

At length, however, in the preface to a work entitled “ Tables 
Ecliptiques des Satellites de Jupiter,” the monstrous discordan- 
cies between the existing observations of the eclipses of the 
third and fourth satellites were dwelt upon, with considerable 
energy, by the celebrated Delambre ; and, perhaps, to the senti- 
ments expressed by this great man, may we trace the principal 
cause why at the present moment, observations of the eclipses 
of these two satellites are almost generally neglected. When, 
however, prejudice seems distributed by one whose name, like 
that of Delambre, is never mentioned but with respect, does it 
become dangerous; and more and more imperative is it, upon the 
humblest labourer in science, to point out the errors which it 
leads to—this must plead my excuse for the present communi- 
cation. 

As the work to which I allude, may not be in the library of 
every practical astronomer, I shall quote from it some of the 
passages calculated in my mind to prejudice observers. 

Page 51.—Having alluded to some trifling equation which 
might be applied as a correction to his tables of the third satel- 
lite. He says, “Je n’ai poussé l’examen plus loin; mais il 
parait en résulter que cette equation ne s’accorde pas plus avec 


1824.) Jupiter's Third and Fourth Satellites. 219 


Vobservation qu’avec la théorie ; et si la théorie est imparfaite, 
s'il reste A découvrir quelqu’ inégalité sensible, elle dépend dus 
moins d’un argument tout-d-fait différent. Ce n’est pas d’ail- 
leurs sur quelques observations isolees qu’il faut chercher a recti- 
fier des tables fondées sur 140 ans d’observations. A la vérité, 
toutes ces observations sont incertaines; mais celles qu’on leur 
opposerait ne sauraient ¢tre beaucoup plus sires ; et !’on en con- 
viendra sans doute, quand on verra Messier et Méchain, dans la 
méme ville et presque dans le méme quartier, tous deux munis 
d’excellens instrumens et d’une vue excellente, ne s’accorder 
cependant qu’d quelques minutes pres sur la méme é€clipse. II 
est evident, de méme, que pour les differences des meridiens, on 
ne peut se fier qu’au premier satellite ; les autres ne sont guére 
bons qu’a éclaircir quelque point de physique céleste ; le pre- 
mier satellite est le seul qui puisse étre vraiment utile aux astro- 
nomeés et aux géographes. Mais ce satellite luicméme peut-il 
s’observer avec une precision bien parfaite? Quel astronome 
osera répondre de 10” sur l’observation qui lui paraitra faite dans 
les circonstances les plus favorables ? En rassemblant les obser- 
vations faites pendant cent ans a Paris et 4 Greenwich, on h’a 
pu trouver qu’a 10” pres la différence entre les deux meridiens.” 

‘Page 55.—He says, “ D’aprés ces remarques, le calculateur 
ajoutera s’il juge a propos, 18 a 19” a toutes nos epoques du 
troisiéme satellite; mais nous sommes loin de lui garantir l’ex- 
actitude de cette correction ; et que font en effet 18” pour des 
observations qui ne sont presque jamais sires 4 2 ou 3 minutes?” 

Page 49.—We have observations of immersion and emersion 
of the fourth satellite recorded,* and thus spoken of: “ Pour 
cette derniére éclipse, les astronomes de Paris different éntre 
eux de 3 sur chaque phase.” . 

Page 55.—Speaking of eclipses of the fourth satellite, he 
says, ‘‘ Je trouve entre les observations d’une méme éclipse des 
ditférences quivont a 7, 8, 10, 12, et 14’; et ce qwily a d’éton- 
nant, c’est que ces discordances énormes ne sont pas toutes vers 
les limites. J’en trouve une qui est de 29’ 15”, mais la demi- 
durée calculée n’était que de 16”.” 

]. We are not told what instruments Messier and Mechain 
employed, whether immersions or emersions were observed ; nor 
do we know any more, than that their observations on the same 
eclipse differed some minutes; hence therefore the statement 
only proves, that differences of longitude could not be gotten by 
reference to the computed tables. 

The assertions that differences of meridians can only be pro- 
cured by the first satellite ; that 7¢ alone can be truly useful to 
astronomers and geographers: the confident tone in which our 
illustrious author asks, What astronomer will dare to answer to 
10 seconds for the accuracy of an observation, which he shall 


* Im, observées,.., 14 37’ 41” Em, observées,... 54 1/1” 
1 41 15 5 8 656 
1 41 47 u 5. Th 222 


220 Mr. South on the Eclipses of [Marcu, 


deem made under the most favourable circumstances, cannot be 
read without making a deep impression on the mind of the 
reader. We must, however, remember, that these sentiments 
were founded upon comparison of all the observations of eclipses, 
which had been made from the year 1662 to the year 1802; and 
there will be little difficulty in believing that the chaotic mass 
would fully justify the assertion ; for among the earlier obser- 
vations immense discordancies would naturally be found ; but I 
feel little hesitation in saying, that the observations which have 
been made since the year 1802 would be far more than sufficient 
to entitle the accuracy of the assertions, as far as they relate to 
modern observations, not only to be disputed, but even to be 
disproved. Observations made during 100 years at Greenwich 
and Paris, did not determine the difference of the two meridians 
nearer than 10 seconds. But observations made during seven 
months in Blackman-street and at Bushey, gave the difference of 
longitude to 17 hundredths of a second. 

2. In a table which will be given presently, there are three 
observations of the third satellite, each coming far within two or 
three minutes of the truth; we shall also produce observations 
of eclipses of the fourth, liable to infinitely less error; hence 
I cannot coincide with our author, in the justice of his remarks.’ 

3. From the recorded observations of immersions and emer- 
sions of the fourth satellite, it is evident enough that the incon- 
gruities are considerable ; and if examined, as our own will 
hereafter be, they are found irreconcilable ; hence supposing the 
same observers, the same instruments, and the same weather, 
at each station, both at the immersion and emersion, we may 
safely infer, that the telescopes were long and unmanageable ;* 
and consequently would afford results inconsistent not only with 
each other, but with themselves. 

4. As to the immense discordancies between the observations 
of the same eclipse related in the last paragraph ; they do zndeed 
place the observers and their instruments in the back ground ; 
tor it would be difficult to account why the observed periods of 
immersion or emersion should differ more than the time which 
the satellite requires to travel through a portion of space, equal 
to its own diameter. 

On consideration of these passages then, I am induced to 
apply the sentiments they convey, more to the earlier observa- 
tions, than to those of modern date; still there can be no doubt 
but that an immense quantity of the latter will be necessary, to 
invalidate the monstrous inaccuracies of the former. An obser- 
ver, however, of the present day, will, 1 think, let his respect for 
the name of Delambre be great as it may, have some difficulty 
in supposing, that similar incongruities would attend obserya- 
tions of similar phenomena, ow that telescopes are better made, 
and what is almost of as much importance, better mounted. 


* When it is known that they were from 15 to 20 feet in focal length, there will be 
some difficulty in arriving at any other conclusion. ' 


1824.] Jupiier’s Third and Fourth Satellites. 221 


That observations of eclipses of the fourth satellite, are the 
most incongruous it would be silly to doubt, and unless the 
immersion and emersion can be procured, they cannot without 
much difficulty be brought to bear, upon any useful point. The 
difference of the telescopes employed will alway need a correc- 
tion ; this may indeed be found by previous comparisons at the 
same stations; but as the dissimilarity of the weather at the 
places of observation will materially influence the results, when 
only the immersion or emersion be observed, an equation is 
wanting, not so eas’/y to be found. Fortunately, however, the 
immersions and emersions of this, and the third satellite, are occa- 
sionally observable within a space of time little more than two 
hours ; let us, therefore, inquire a little into this matter. 

We have already noticed that the fourth satellite having 
entered the shadow, is a very considerable time before it becomes 
lost in it; hence its disappearance will be extremely gradual ; 
let us suppose that during this time it passes through three dis- 
tinct gradations of lustre ; that at the first, it resembles the small 
star of ¢ Urs Majoris ; at the second, the small star of Polaris ; 
and at the third, the small star of « Lyre. Let us then have three 
telescopes ; the one able only to show the small star of ¢; the 
‘second only that of Polaris; the third adequate to show the 
small star of « Lyre. Ona fine night, all the telescopes show 
their respective objects very well—say at 10 o’clock; provided 
the stars have considerable altitude, and the weather be equally 
good, why should they not show them equally as well at 12 
o’clock? it would puzzle most persons, I think, to determine ; if 
so, provided the analogy hold good, why may not the evanes- 
cence, and re-appearance of the fourth satellite be observed, 
within reasonable limits? I confess I see no reason. I know it 
is said, an observer will have an impression left on his mind, that 
the satellite continues visible when it rea//y is not so; but this 
is not distinctly proved ; and again on the emersion, knowing 
the point at which he is to look for it, he thinks he sees it ear- 
lier than he actually does; this again is not proved: we will, 
however, allow them both, and we shall be as if they were not 
allowed at all. The only difference between the three telescopes 
would be, that A would give the immersion earlier than B; and 
B sooner than C. And at the emersion, A would show the satel- 
lite /uter than B, and B /ater than C; circumstances, as we shall 
hereafter see, not of the deast importance. 

Entertaining then sentiments such as these, I determined on 
‘the first favourable opportunity, to observe the immersion and 
emersion of the fourth satellite, with every possible care ; and the 
first day of the present month enabled me to do so. Jupiter’s 
meridian altitude was about 62°; the immersion occurred when 
the planet was 1" 34’ east of the meridian ; the emersion when 
it was 34 minutes west of it. The memoranda relative to the 
observations, as entered in the Journal at the time are as follow: 


¥ 


222 Mr. South on the Eclipses of [Maren, 


. © Prior to taking the transit of Aldebaran, the five feet equa- 
torial was placed upon Jupiter, and immediately after the transit 
had been secured, I went to see how matters were going on; the 
fourth satellite was at this time about the splendour of a star of 
the ninth magnitude, and of alight blue colour. The night was 
remarkably clear; I determined to remain at the instrument as 
long as the satellite continued visible, which, according to the 
Nautical, would be at least a quarter of an hour. To make my- 
self comfortable, therefore, I placed some blocks of wood upon 
the double steps, and took my seat very quietly: the lights, 
except that at the clock, were all put out ; it continued diminish- 
ing in lustre till 4" 34’ 57” per clock, at which time I could see it 
no more. I observed it of the brightness of the small star near 
a Lyre for more than a minute. 

“ Emersion of the fourth satellite (observatory darkened as 
before) at 6" 43’ 5” per clock. 

“ At 6" 45’ about as bright as the pole star. 

“ At 6" 52’ had not half the splendour of the dullest of the 
other three which were visible. Unable to spare more time, 
further observation was given up.” 

Greatly satisfied with my own observations, I was in hopes 
that the extraordinary fineness of the night would have rendered 
correspondent ones, at various stations, almost certain ; but in 
this I have had the mortification to find myself disappointed. 
The only observer who, as far as I have ascertained (and I have 
made very extensive inquiry), was similarly engaged with myself, 
is to be found in Col. Beaufoy : it is however indeed fortunate 
that it was he. My opinion of his observations of the eclipses 
of Jupiter’s satellites, has long been before the public ; so that 
I cannot now be suspected of commending his aceuracy, merely 
to suit my present purpose. 

My observations made with the five feet equatorial, the object 

glass of its telescope has 64 inches focus, and 33. inches clear 
aperture ; power 133. 
. Col. Beaufoy’s telescope has an object glass, precisely of the 
same diameter, but of 56-5 inches focal length: it is mounted 
on : EA ag stand, but not equatorially. Magnifying power 
used = ; 

Prior to observation, he excluded all light from his observatory, 
except what was sufficient to enable him to distinguish the hands 
of his clock. 


Longitude of Blackman-street observatory. ., = 0’ 21°76” W. 


Bushey. ..,.ss00es Mant canee Le 
Diff. of long. Bushey to the W, ....eeeeee52 = 0 5917 
Blackman-street Observations. Bushey Observations. 
‘Immersion 4" 35’ 3°89” Immersion 4" 32’ 27:09” 
Emersion 6 43 11°89 ' Emersion 6 43 60-46 


(Sidereal time at each station.) 


1824.) Jupiter’s Third and Fourth Satellites. 228 


Now if we add the difference of longitude to the Bushey obser- 
vation of immersivun, we shall have in Blackman-street time, the 
instant at which the phenomenon was observed at Bushey ; and 
the difference, if any, between this and the Blackman-street 
observation, will show the time by which the satellite was seen 
longer, at one station than at the other. ! 


4 32’ 27:09” = Immersion at Bushey. 
+ 59°17 = Difference of longitude. 


4 33 26-26 = Blackman-street time when the immersion 
was observed at Bushey. 
4 35 3:89 = Immersion at Blackman-street. 


+1 "37-63. = the time that the satellite was seen longer at 
Blackman-street than at Bushey. 


A mere inspection of the times shows, that the differences are 
considerable: let us see if they are reconcileable. As the tele- 
scopes at the two stations are nearly similar; as the same pre- 
caution of excluding adventitious light was employed at both ; 
we must seek for the cause of the discrepancy, either in a clearer 
atmosphere at one observatory than at the other—in a greater sen- 
sibility to minute particles of light, which one observer has than 
the other—or in the superior steadiness of the one instrument 
over the other. As to difference of atmosphere, we have no 

roof that there was any; indeed the probability is in favour of 

ushey ; ?¢ being situated far from any frequented neighbour- 
hood; while the Blackman-street observatory is surrounded by 
buildings in every direction. As to increased sensibility to small 
particles of light, we have no good grounds to suspect that one 
observer possesses this, more than the other. Hence we are left 
to the only remaining source of discrepancy, namely, the greater 
steadiness which one instrument has than the other; and this 
there can be no doubt the Blackman-street instrument possesses : 
itcan be moved inright ascension by the finger and thumb; a star 
may be kept bisected by one of its micrometer wires any reason- 
able time ; nor will any tremulous motion be communicated to 
the star, although a power of 500 or 600 be employed. Hence 
the experience of daily observation would authorize us to declare, 
ceteris paribus, that in Blackman-street the immersion ought to 
be seen /ater than at Bushey: perhaps also the trifling difference 
of focal length and magnifying power of the Blackman-street 
instrument may contribute some little to the result; which is, 
that the immersion was seen /ater in Blackman-street than at 
Bushey by 1’ 37-63.” 

But if our reasoning be correct, the emersion should be seen 
earlier in Blackman-street ; and if the weather at the emersion 
be the same at each station, as it was at the time of immersion, 
by as much as the immersion was seen later in Blackman-street, 


294 Mr. South on the Eclipses of [Marcn, 


should the emersion be seen earlier; a little allowance being 
made for error of observation: let us see if it were so. 


6" 43’ 50:46” = Emersion at Bushey. 
+ 59°17 = Difference of longitude. 


ee 


6 44 49:63 = Blackman-street time when the emersion was 
observed at Bushey. 
6 43 11:89 = Emersion at Blackman-street. 


—l 37-74 = the time that the satellite was seen earlier at 
E Blackman-street than at Bushey. 


Hence it appears that the emersion was seen earlier in Black- 
man-street than at Bushey ; and by an interval of time agreeing 
with that by which the immersion was observed /ater, to 11 hun- 
dredths of a second. 

Let us now see how far the results can be converted to prac- 
tical utility—to what degree of accuracy then, will they enable 
us to determine the difference between the meridians of the two 
observatories. 


Im. at Blackman-street = 4" 35’ 3:89” 
Bushey. ...... = 4 32 27-09 


Hence diff. of longitude = 2 36-80 Bushey to the W. 
Em. at Blackman-street = 6" 43’ 11°89” 

Bushey. ...... =6 43 50:46 
Hence diff. of longitude = 38°57 Bushey to the E. 


Now + 2’ 36:80” or W. 
— 0 38:57 or E. 


2)+ 1 5823 W. : 
Difference of longitude .... = 0 59:11 Bushey being to W. 
But known difference. .... = 0 59°17 


SS 


Error of observation ...... = 0 0:06 at the two Stations. 


Consequently the difference of longitude, between the two 
observatories of Blackman-street and Bushey, is ascertained to 
six-hundredths of a second ; a quantity therefore which we must 
consider, as the error of observation at the two stations. 

But some time since, the difference of the two meridians was 
found by the same observers, with the same instruments, and the 
results will be shown in the following table :— 


1824.] Jupiter's Third and Fourth Satellites. 225 


Difference of Longitude f my Observatory and Cot. Beaufoy’s, 
by Observations of 14 Ec 
our respective Stations. 


lipses of Jupiter’s Satellites, made at 


. Col. Beaufoy’s | Difference of 
My Observations. | Qpservations. Longitude. 


1821. 
Aug. 4j/Imm. 2 SatJ11" 5’ 26°80”11" 4’ 310’ 55 80”W 
18 Imm. 1 12 0 (809 |11 58 53 |1 15°09 


Oct. 24/Em. 3 110 35 840 {10 34 22/0 46°40 
' 28 Imm. 1 9 10 40:'76'9 9 51 0 49°76 
Nov. 4/Em. 1 ll 6 40°83 fT, 5 19 Ti “27-83 
20;/Em. 1 9 25 26:°26;9 24 34/0 52°26 
27\Em. | WY 21. 4-56 T11 “20' 19 10 45°56 
-29/Em. 1 5 49 53°60!15 49 13 |0 40°60 
29|Em. 3 6 42 49°0316 42 8/0 41:03 
Dec. 6Em. 1 7. 45 .55:10 17 §45 “20 |0°.-35°10 
1822, 
Jan. 14\Em. 1 6 23 40-48 22 af i ia to 
29/Em. 2 6 55 453016 54 15 {1 ‘30:30 
Feb, 23/Em. 3 7. Sto | 7s 7. SOE, bere 
March 1/Em. 1 6 57 3660! 6 56 27/1 9-60 
Mean differ. of long. of the two Observatories... = 0 59°34 
Known difference of the two Observatories.... = 0 59°17 
Error of observation at the two Stations ...... =0 017 


Thus it seems that 14 observations, nine of the first satellite, 
two of the second, and three of the third, gave the difference of 
longitude to seventeen-hundredths of a second, and that it was. 
the work of seven months; while in the observation before nar- 
rated, the accuracy is t/ree times as great, and is obtained in a 
few minutes more than two hours. Some perhaps will contend, 
that this accuracy is the offspring of accident; it is however at 
least as probable, that accident has had nothing at all to do with 
it; on the same supposition, and with equal plausibility, might it 
be urged that accident has prevented accuracy in each of the 
14 observations, principally of the favourite satellite; the two 
nearest of which to accuracy, are 50 or 100 times more remote 
from it, than are the results of those observations, which are the 
immediate objects of this communication. 

From this however let it not be supposed, that ] imagine 
equal accuracy will always be procured; an observer may and 
occasionally dves obtain the right ascension of a star by one 
wire of his transit instrument just as correctly as if he employ 
the five or the seven; yet he must not suppose he will always do 
it; just so with the observations of immersion and emersion | 
have alluded to; all I contend for is, provided the same care— 
the same instrument—the same magnifying power—-the same 

New Series, vou. vu. Q 


926 Eclipses of the Third and Fourth Satellites. [Mancn, 


ae wesialion same observer—the same weather—be used, 
ound, or employed, at the various stations both at the immer- 
sion, and subsequent emersion, that the results so far from 
meriting obloquy, will probably be far more accurate than 
any two eclipses of either the first or second satellites—and if 
what be stated prove true of the fourth satellite, it cannot be 
otherwise of the third. | 

But in the instance we have dwelt upon, only two observers 
were concerned; further observations therefore should be re- 
curred to—those then whose stations relatively to Green- 
wich are well settled—whose instruments are well mounted, and 
whose time is well known, will do an essential service to prac- 
tical astronomy, by observing the immersions and subsequent 
emersions of the third and fourth satellites whenever they are 
visible—they should be at their telescopes some eight or ten 
minutes before the phenomena are expected ; should take every 
possible care that the immersion and emersion be observed 
under similar circumstances—and should note at the time, how 
far the weather at the emersion coincided with that in which 
the immersion was observed ; nor will the relative splendour of 
such other satellites, as may be visible at the two periods, allow 
an accustomed eye much difficulty in deciding. 

I have dwelt upon this subject perhaps longer than some will 
say, its importance warrants—two marked instances of the 
injurious eftects of the opinions generally entertained against 
observations of the fourth satellite have however recently presented 
themselves—One individual many years an accurate and assiduous 
observer assures me, that in consequence of prejudice, he never 
looked out for an eclipse of the fourth satellite in his life.—And 
another astronomer did not. observe the very eclipse here so 
often referred to, “because of sentiments he entertained founded. 
on Delambre’s statements.”—Nor are the individuals referred to 
of any mean importance—the latter is well known as the author 
of many useful astronomical publications ; whilst to the former, 

ractical astronomy owes greater obligations, than to any person 
in existence. 

To remind observers a table is subjoined giving in sidereal 
and mean time the predicted immersions and emersions of the 
third and fourth satellites during the next two months, and should 
the weather prove favourable, I have little doubt the result 
will show; that the opinions generally entertained of the inutility 
of observations of eclipses of the Third and Fourth satellites, 
originate in PREJUDICE, and terminate in ERROR. 

Sidereal Time. | Mean Time. 


March 2. Immersion third satellite .. 8" 0’ gh 18” 
Timerdibay eek e4 eo. peor 12 30 
April 8. Immersion fourth satellite .. 9 13 8 4 
Eaiersion 21.40. ole'. eieviod sad Bob - 10 58 


It is almost needless to say that where the satellite is logt at _ 


the immersion, it may be looked for at the emersion. 
James Sours. 


SEES === eae 


1824.} Analyses of Books. 227 


ARTICLE XIV. 


ANALYSES OF Books. 


Philosophical Transactions of the Royal Society of London, for 
| 1823. Part IL. 3 vi 


(Continued from p. 147.) 


XXI. Second Part of the paper onthe Nerves of the Orbit. By 
Charles Bell, Esq. Communicated by Sir Humphry Davy, Bart. 
Pres. RS. 

The following extract from the concluding pages of this paper, 
gives the general results of Mr. Bell’s investigation of the nerves 
of the head. 

“ T hope I have now unravelled the intricacy of the nerves of 
the head, and have correctly assigned to each nerve its proper 
office. In our books of Anatomy, the nerves are numbered 
according to the method of Willis, an arrangement which was 
made in ignorance of the distinct functions of the nerves, and 
merely in correspondence with the order of succession in which 
they appear on dissection. 

“The first nerve is provided with a sensibility to effluvia, 
and is properly called olfactory nerve. 

“« The second is the optic nerve, and all impressions upon it 
excite only sensations of light. 

“ The third nerve goes to the muscles of the eye solely, and 
is a voluntary nerve by which the eye is directed to objects. 

“ The fourth nerve performs the insensible traversing motions 
of the eyeball. It combines the motions of the eyeball and 
eyelids, and connects the eye with the respiratory system. 

“ The fifth is the universal nerve of sensation to the head and 
face, to the skin, to the surfaces of the eye, the cavities of the 
nose, the mouth and tongue.* 

“ The sixth nerve is a muscular and voluntary nerve of the 
eye. 

“The seventh is the auditory nerve, and the division of it, 
called portio dura, is the motor nerve of the face and eyelids, 
and the respiratory nerve, and that on which the expression of 
the face depends. 


* “ Tn this view of the fifth nerve, I have not touched upon its resemblance to the 

inal nerves. But if we had ascended from the consideration of the spinal nerves to 

e nerves of the head, we should then have seen that the fifth was the spinal nerve of 
the head ; that it had a ganglion at its root, a double origin, and from its power over 
the muscles of the jaws and mastication, that it was a double nerve in function, being 
that nerve which bestows sensibility, at the same time that it sends branches to the 
original muscles ; that is to say, to that class of muscles which are common to animals 
in every gradation, In all these respects it resembles the spinal nerves.” 


Q 2 


228 Analyses of Books. (Maren, - 


“ The eighth, and the Accessory nerve, are respiratory nerves. 

“ The ninth nerve is the motor of the tongue. 

“ The tenth is the first of the spinal nerves; it has a double 
root and a double office ; it is both a muscular and a sensitive 
nerve. 

“ Had I taken the nerves of any other complex organ rather 
than of the eye, I should have had an easier task. If I had 
taken the nerves of the tongue, I should have been able to prove 
by experiment, and in a manner the most direct, that the three 
nerves belong to three distinct functions, and stand related to 
three different classes of parts. I could have shown that taste 
and sensibility belong to the office of the fifth nerve, voluntary 
motion to the ninth, and deglutition to the glossopharyngeal 
nerve of the tongue.” 

XXII. An Account of Experiments made with an Invariable 
Pendulum at New South Wales by Major-General Sir Thomas 
Brisbane, KCB. FRS. Communicated by Capt. Henry Kater, 
FRS. ina Letter to Sir Humphry Davy. 

The following are the results of these experiments, as given by 
Capt. Kater :— 

“< 1f the number of vibrations resulting from Sir Thomas Bris- 
bane’s experiments at Paramatta be compared with the mean 
number of vibrations made by the pendulum at London, we shall 
have 39°07696 inches for the length of the pendulum vibrating 
seconds at Paramatta; ‘0052704 for the diminution of gravity 
from the pole to the equator; and — for the resulting com- 
pression ; the length of the pendulum vibrating seconds at Lon- 
don being taken at 3913929 inches. 

“The experiments at Paramatta being compared with those 
made by me at Unst, in latitude 60° 45’ 28” north, give *0055605 
for the diminution of gravity from the pole to the equator, and 


1 : ‘ 
aaa for the resulting compression. 


“If Mr. Dunlop’s experiments at Paramatta be compared 
with those made at London, we obtain 39-07751 for the length of 
the seconds’ pendulum at Paramatta, ‘0052238 for the diminution 


l 
of gravity from the pole to the equator, and => for the com- 


pression. Or, comparing Mr. Dunlop’s experiments with those 
made at Unst, we have ‘0053292 for the diminution of gravity 


1 : 
from the pole to the equator, and 755 for the resulting com- 


pression. 

“ The compressions here deduced must not as yet be deemed 
conclusive; for it is well known that a very small alteration in 
the number of vibrations made by the pendulum would occasion 
a considerable difference in the fraction indicating the compres- 
sion. The indefatigable zeal of Sir Thomas Brisbane will, how- 
ever, no doubt soon furnish additional data.” 


1824.] Proceedings of Philosophical Societies. 229 


“P.S. I may here take the opportunity of correcting an 
error in the “ Account of Experiments for determining the 
Variation in the Length of the Pendulum vibrating Seconds at 
the principal Stations of the Trigonometrical Survey of Great 
Britain.” 

“In the first series of observations made with the repeating 
circle for the latitude of Clifton, 1’ 41:6” has been applied as the 
correction for the level instead of 141°6% = 2’ 21:6”. The 
resulting latitude, when the proper correction is made, is 
53° 27’ 44:94” instead of 53° 27’ 40-94”, and the greatest differ- 
ence between the fiye independent latitudes of Clifton 3-48” 
instead of 5:24”.” 

XXIII. On the Daily Variation ie Horizontal and Dipping 
Needles. By Peter Barlow, Esq. FRS. 

An abstract of this paper will be found in the present number 
of the Annals, at p. 163. 

XXIV. On the Diurnal Deviations of the Horizontal Needle 
when under the Influence of Magnets. By Samuel Hunter Chris- 
tie, Esq. MA. Fellow of the Cambridge Philosophical Society : 
of the Royal Military Academy. Communicated by Sir Hum- 
phry Davy. 

Our present limits will not permit us to give any account of 
this extended paper, occupying 50 pages ; but we shall probably 
devote a separate article to that purpose. 

XXV. On Fossil Shells. By Lewis Weston Dillwyn, Esq. 
FRS. Ina Letter to Sir H. Davy. 

This paper we have reprinted entire at p. 177 

(To be continued.) 


ARTICLE XV. 
Proceedings of Philosophical Societies. 


ROYAL SOCIETY. 


Jan. 15.—Messrs. J. H. Vivian, and Michael Faraday, were 
respectively admitted Fellows of the Society; and the reading 
of Messrs. Herschel and South’s “ Observations on the Posi- 
tions and Distances of Three Hundred and Eighty Double and 
4 Fixed Stars,” was resumed and concluded. 

an. 22.—Dr. C. Scudamore was admitted a Fellow of the 
Society ; and the following paper was read: 

“On a Mode of preventing the Corrosion of Copper-Sheath- 
ing, by Sea-Water, in Ships of War, and other Ships.” By Sir 
Humphry Davy, Bart. PRS. 

The attention of the President having been drawn to this sub- 
ject by the Commissioners of the Navy Board, he instituted a 


230 Proceedings of Philosophical Societies. [Mancn, 
series of experiments upon it, and has discovered a simple and 
effectual mode of remedying the evil. Copper, when immersed 
in sea-water, however pure and malleable it may be, becomes 
covered with a coat of a green submuriate, a sort of rust, which, 
when washed off, is succeeded by a similar one, and the process 
continues until the metal is completely destroyed. 

It was evident that no alteration which could be effected in the 
copper would prevent its corrosion ; the effect on different kinds 
of copper might be somewhat different, but the principal diver- 
sities must be owing to the variations in the saltness and tem- 
perature of the sea-water. 

Sir Humphry was led to the discovery, by the same principle 
which led him to that of the decomposition of the alkalies ; 
namely, that chemical affinities might be balanced or destroyed, 
by changing the electrical states of the substances: it thence 
appeared that the corrosion of the copper might be prevented by 
its being brought, by contact with another metal, into a nega- 
tively electric state ; and he had accordingly found that by the 
contact of tin, forming part of an electrical circuit, of 25th part 
the surface of the copper, the desired effect was completely 
obtained. Other metals, positive in respect to copper, may be 
employed, as lead and zinc, but tin is preferable, on account of 
its capability of being brought into complete contact with the 
copper, by means of solder, and also because its submuriate is 
easily detached from the metal. 

The experiments were made with ribbands of tin, and it was 
found that such a ribband, equal in substance to only =1,th part 
of the copper, effectually prevented the corrosion of the latter. 
They were so entirely satisfactory, that not the smallest doubt 
can be entertained of the perfect success of the method in prac- 
tice ; and the Lords Commissioners of the Admiralty have made 
arrangements for enabling the President to repeat them on the 
largest scale, on ships of war. ; 

It is probable, Sir Humphry observes, that this method, besides 
preventing oxidation, will also prevent the adherence of vegeta- 
bles and marine animals to the sheathing. 

This interesting communication terminated with some allusions 
to the great importance of the discovery it announced, in a 
national point of view, with respect to our maritime and commer- 
cial interests. 

The reading was likewise commenced of a paper, “ On the 
Development of Magnetical Properties in Iron and Steel by 
Percussion, Part Il.” By W. Scoresby, Jun. FRSE. Commu- 
nicated by Sir H. Davy. 

Jan, 29.—Thomas Amyot, Esq. VPSA. was admitted a Fellow 
of the Society, and the reading of Mr. Scoresby’s paper was ter- 
minated. 

This communication was a continuation of a former paper by 
Mr. Scoresby, under the same title, which appeared in the Phil. 


1824.) Royal Society. 231 


Trans. for 1822. (See Annals, N.S. v.) In the first part, Mr. S. de- 
‘scribes his new process for the development of magnetism, and 
ale the result of a number of experiments made with different 
kinds of iron, and under different modes of treatment. The only 
experiments at all analogous to these were performed by Dr. 
Gilbert about two centuries back, in which Dr. G., hammering 
a piece of iron in the direction of the magnetic meridian, and 
drawing it out while red-hot, gave it such a degree of magnetism 
as to cause it, when floated by a piece of cork on water, to 
adjust itself in a north and south direction. But Dr. Gilbert 
went no further. Mr. Scoresby, however, considering, that as 
magnetism in steel is more readily developed by the contact of 
magnetizable substances, and particularly if these substances be 
already magnetic, imagined, ‘ that the magnetizing effects of 
percussion might be greatly increased by hammering a steel bar 
with its lower end resting upon the upper end of a large rod of 
iron or soft steel, both the masses being held in a vertical posi- 
tion; and that if the rod were first rendered magnetic by ham- 
mering, the effect on the steel bar would probably be augmented.” 
The experiments instituted to ascertain the effect of such treat- 
ment fully proved that these opinions were correct. A small bar 
of soft. steel being hammered while resting upon a surface of 
stone or metal, not ferruginous, was rendered capable of lifting 
64 grains of iron, which was the extreme effect; but on 
being hammered while held vertically upon a parlour poker, also 
held erect, it lifted a nail of 88 grains weight after 22 blows. 

The paper now communicated to the Royal Society described 
a new arrangement and process, by which a much higher degree 
of magnetic energy was developed. In the former experiments 
of Mr. Scoresby, a single rod of iron only was used, and the 
steel bars or wires were hammered upon it, while both were 
held in a vertical position; in which case the magnetism of the 
iron, after hammering, was employed in aid of the power of per- 
cussion for the development of the magnetism of the steel bars. 
But the iron acted only on the lower end of the steel wires ; the 
magnetism of the upper end being spontaneous, or what is by 
magneticians called consequential. Hence, Mr. 8. attempted to 
supply an additional force for the development of the magne- 
tism of the steel, to act upon the upper end of the wire as well 
as on the lower, and this ie accomplished by hammering the 
wire or bar of steel between two bars of iron. The bars of iron 
he used were three feet and one foot in length, both made of 
common iron. The steel consisted of wires of about one-eighth 
of an inch in diameter. The lifting power produced in the wires 
was estimated by the heaviest of a series of nails, polished at 
the points, which the wire was capable of lifting. 

e cannot follow Mr. Scoresby through the details of his 

experiments ; but we may state a few particulars of the results 
which he obtained from his investigations. 


232 Proceedings of Philosophical Societies. [MAncu, 


1. By Mr. Scoresby’s first process (which he denominates the 
simple process, to distinguish it from the second, or compound 
process), he obtained a maximum magnetical effect’ on a steel 
wire of about six inches long, capable of lifting a nail of 186 grs. 
which effect the compound process raised up to 326 grs. In 
other cases, an equal and sometimes a superior effect was pro- 
duced. 

2. In respect of temper or degree of hardness of the wires, it 
was found that the softest wires obtained generally the highest 
power, and were most easily magnetized, but the effect soon 
went off, 

3. By using a larger bar of iron (about eight feet in length), a 
great increase of magnetical power was obtained, a wire of only 
six inches long being made to lift, by hammering by the com+ 
pound process on this bar, a weight of 669 grains, or four times 
the weight of the wire. 

4. The limit to the magnetism given to the wires, Mr. Scoresby 
considers to be determined by the magnetism of the iron bars 
employed. The bars being simply placed vertically, become 
slightly magnetic by position from the earth. This polarity is 
increased by hammering them while they remain in a perpendi- 
cular position. An increase of magnetism continues to obtain 
by repeated hammering the bars up to the extent that Mr. 
Scoresby developed. But the maximum required the bars and 
wires to be very often hammered, and the process to be conti- 
nued at intervals for a few minutes at a time, during several 
days. For a wire, however, to be made to lift its own weight 
required only afew minutes hammering, and when the bars had 
become magnetic by use, a single blow with a hammer was 
sometimes found sufficient to enable the wire to lift its own 
weight. To produce the best effect, it is important to have the 
steel wires polished at the end, and always to use the same end 
downward, which obtains north polarity ; for by this means, Mr. 
S. found that an increase of capacity for magnetism in the wires 
took place after almost any operation. 

Mr. S. conceives that the high effect obtained by percussion 
depends on the disposition that percussion gives to the ferrugi+ 
nous particles, for assuming that condition to which we apply 
the name magnetic. The particles of ferruginous substances, 
especially steel, resist this condition to a certain extent, which 
resistance percussion tends to overcome. The general law Mr. 
S. resolves into this ; that percussion on magnetizable substances 
zn mutual contact inclines them to an equality of condition. And 
this effect he illustrates, by the tendency of bodies unequally 
heated, to assume, when placed together, the same temperature. 
And from the tendency of the cooler bodies to acquire tempera~ 
ture, and the hotter to lose temperature, he explains the appa- 
rently opposite proposition, that magnetism is both developed 
and destroyed by percussion. The power of strong magnets is 


1824.) Royal Society. =~ 233 
diminished by hammering, if held in the air unsupported, or 
rested upon any body not equally magnetic ; and the power of 
very weak magnets, or bars with little or no magnetism, is 
increased, if held upon any substance that is magnetic. In all 
cases and circumstances, the hammering tends to bring the sub- 
stances in contact into a similar state, the weaker being 
strengthened, and the stronger weakened. 

A paper was also read, entitled ‘ Observations on the Iguana 
tuberculata, the common Guana.” By the Rev. Lansdown 
Guilding, BA. FLS. Communicated by Sir E. Home, Bart. 
VPRS. 

This paper was very short: it commenced with some general 
remarks on the necessity, in zoology, of describing animals from 
living specimens, and on the errors which had been committed by 
naturalists in stating the characters of certain lizards, in conse: 
quence of inattention to that circumstance; thus the gular pro- 
cess of the lizards alluded to, had been erroneously described as a 
pouch capable of dilatation. Mr. Guilding then proceeded to 
describe briefly an organ on the parietal bones of the head of the 

uana, to which he gave the name of foramen Homianum, in 

nour of Sir E. Home. | 

Feb.5.—A paper was communicated, entitled, “ A finite and 
exact Expression for the Refraction of an Atmosphere nearly 
resembling that of the Earth.” By Thomas Young, MD. For. 
Sec. RS. ; 

The reading was commenced of the Bakerian Lecture, by 
J. F. W. Herschel, Esq. FRS. 

Feb. 12.—The Bakerian Lecture was concluded, 

_ The subject of this Lecture is the phenomena exhibited by 
mercury, and other fluid metals, when placed within the in- 
fluence of an electric current transmitted through conducting 
liquids. 

Te a quantity of mercury be placed in a dish and covered 
with ‘a conducting liquid, through which an electric current is 
transmitted from a voltaic pile of moderate energy, by wires not 
in contact with the mercury, this metal will be thrown into a 
state of circulation, the force and direction of which varies 
with the nature of the liquid, the intensity of the electric 
onl used, and other adventitious circumstances. If the liquid 

e sulphuric, phosphoric, or any of the more concentrated acids, 
the circulation is excessively violent, even with weak electric 
powers, and takes place in a direction from the negative to the 
positive wire. On the other hand, under alkaline solutions, 
pure mercury remains at perfect. rest in Jike circumstances ; 
but if the least atom of potassium, sodium, zinc, or any metal 
more electro-positive than mercury, be added to it, a violent 
rotation is immediately produced, in the opposite direction 
or from the positive wire. From some trials, Mr. Herschel is' led 


234 Scientific Intelligence. [Marcu, 


to conclude, that much less than a millionth part of potassium, 
‘or a 100,000th of zinc, is sufficient to impart this singular 
property to mercury. Lead and tin act with much less energy. 

ismuth, copper, silver, and gold, not at all. A number of 
singular phenomena in the electrization of mercury and other 
metals are described; and some calculations added respecting 
the intensity of the forces acting on the molecules of the 
electrified body, which Mr. H. concludes, in his experiments, 
to have been not less than 50,000 times their gravity. 

In the sequel, Mr. Herschel notices the curious gyratory 
motions, observed by M. Serrulas, in fragments of alloy of 
potassium and bismuth, when floated on mercury under water ; 
the cause of which he shows to have been misunderstood by 
Mr. S. and which admit of easy explanation on the principles 
of this Lecture. 

For the sake of such of our readers as may wish to repeat 
these experiments, we may mention, that it is absolutely neces- 
sary to use mercury recently distilled and purified, by washing 
with dilute nitric acid, and that all the vessels employed must 
be scrupulously clean, and the surface of the metal free from 
any adhering film. A small battery of eight or ten pairs of 
single plates is sufficient to exhibit all the phenomena. 


ArTIcLeE XVI. 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS 
; CONNECTED WITH SCIENCE, 


I, Primary Forms of Sulphur. 


Our readers ay net remarked in the present volume of the Annals, 
a description by Mr. Brooke, of two primary forms of sulphate of 
nickel. A paper appears in the Annales de Chimie, for Nov. 1823, by 
Mr. Mitscherlich, announcing the discovery of two primary forms 
of sulphur. The one, that which occurs in nature, an octahedron 
with a rhombic base; the other, an oblique rhombic prison, P. on M. 
measuring 94° 5! and M. on M. 90° 32’, produced by fusing sulphur 
in a vessel, in which it may very gradually cool; when a crust is 
formed round the mass, it is to be broken, and the sulphur which 
remains fluid to be poured out; the crystals will appear lining the 
cavity. 

Mr. M. appears to consider that all substances which produce 
crystals, may likewise assume two primary forms. 

This gentleman has crystallized phosphorus from a solution of 
Bhoepluret of sulphur, the form of which is the rhombic dodecahe- 
Ton. 


1824.) ~ Scientific Intelligence. 235 


II. Uranite of Autun. 


M. Laugier has submitted the uranite of Autun to a fresh examina- 
tion; the results are: 


Bi Ee Re pa A does 210 
Oxide of uranium 
Phosphoric acid ,........... 145 
CAMBS. Ob ele opi vision 4 a secceee 46 
Oxide of iron and silica...... 3:0 
Traces of manganese and tin. 

98°] 

From this analysis M. Laugier draws the following conclusions : 

Ist, That the uranite of Autun, hitherto considered either as an 
oxide of uranium, or as a compound of the oxide of lime, is a true 
phosphate of uranium.. 

2dly, That the lime in this mineral, is for the most part, in an un- 
combined state. 

3dly, That phosphate of uranium is entirely soluble in carbonate of 

ammonia, from which it is totally precipitated by ebullition— 
(Annales de Chimie et de Physique, vol. xxiv. p. 247. Nov. 1823.) 
- The existence of phosphoric acid in the ore of uranium was an- 
nounced by me, in the Annals for December 1822. I then supposed, 
though erroneously, that the fact was new, but it had been entirely 
overlooked. In the Annals for January 1823 (p. 61), I stated, precisely 
the same opinion of the real nature of the uranite of Autun, as 
M. Laugier has announced, that it is ‘‘ essentially composed of phos- 
phate of uranium.” 

M. Laugier fairly acknowledges that he had heard of the fact of 
the phosphoric acid having been noticed in England, but only since 
the reading of this paper on the 15th of September last. —Edit. 


III. Phosphorescence of Acetate of Lime. 


(To the Editor of the Annals of Philosophy.) 
SIR, Jan. 14, 1824, 
Not being aware that the phosphorescence of this salt has been 
noticed by any chemical writer, 1 have taken the liberty to forward 
you the observations I have made on its peculiar properties in this 
respect. Dissolve any quantity of acetate of lime in water, and 
place it on a sand heat, in a wedgwood ware dish, evaporate to dry- 
ness without disturbing it. When quite dry, let the bulb of a ther- 
mometer be rested on the bottom of the dish, and when the tempera- 
ture has attained the 250th of Faht. the lime will be found to adhere 
very firmly. If light be now excluded, and the acetate strong] 
rubbed with a stiff spatula, it will become highly luminous. The high 
temperature required for producing this pppeasnge is peculiar to this 
substance and fluate of lime. am, Sir, 
Your obedient servant, NicuoLas Mitts. 


236 Scientific Intelligence. (Marcon, 


IV. Chemical Examination of a Fragment of a Meteor which fell in 
Maine, August, 1823. By J. W. Webster, MD. MGS. Lond, &c. 


This aérolite fell at Nobleborough in the State of Maine, on the 
7th of August, 1825, between four and five o’clock p.m. The only 
information which I have been able to obtain of the attending pheno- 
mena is from the papers of the day, and from a communication of 
Professor Cleaveland, which is published in the American Journal of 
Science, vol. vii. p. 170; this account he informs me was obtained 
at his request by a gentleman of intelligence in a personal interview 
with Mr. A. Dinsmore, who was at work near the place where the 
aérolite struck. ‘ Mr. Dinsmore’s attention was excited by hearing 
a noise which at first resembled the discharges of platoons of soldiers, 
but became more rapid in succession. The air was perfectly calm ; 
and the sky was clear, with the exception of a small whitish cloud, 
apparently about forty feet square, nearly in his zenith, from which 
the noise seemed to proceed. After the explosion, this little cloud 
appeared to be in rapid spiral motion downwards, as if about to fall on 
him, and made a noise like a whirlwind among leaves. At this 
moment, the stone fell among some sheep, which were thereby much 
frightened, jumped, and ran into the woods. This circumstance 
assisted Mr, D. in finding the spot where the stone struck, which was 
about forty paces in front of the place where he was standing. The 
aérolite penetrated the earth about six inches, and there meeting 
another stone, was broken into fragments. When first taken up, which 
was about one hour after its fall, it exhaled a strong sulphureous 
odour. The whole mass previous to its fracture probably weighed 
between four and six pounds ; other fragments of the same meteoric 
stone are said to have been found several miles distant from Noble- 
borough.’’—Amer. Jour. 

To the politeness of Dr. George Hayward I am indebted for a 
fragment of this meteor, 

Externally the specimen was in part covered with a thin semi- 
vitrified crust or enamel of a black colour, the surface of which was . 
irregular and marked with numerous depressions, presenting every 
appearance of having been subjected to intense heat. The crust was 
hard, yielding with difficulty to the knife. The quantity of this crust 
which the small fragment I obtained afforded, was not sufficient to 
allow of any separate analysis of it. re 

The mass of the specimen had a light gray colour interspersed 
with oblong spots of white, having the aspect of decomposed leucite, 
and giving it a porphyritic aspect. Throughout the stone minute 
points of a yellow substance, resembling olivine, were distributed, 
with microscopic points of a yellow colour, which I imagine were 
sulphuretted iron. The cement by which these substances were 
united was of an earthy aspect, and soft texture, readily broken down 
by the fingers. The general appearance of the mass was precisely 
like that of some of the volcanic tuffas. 

The specific gravity was remarkably low, being but 2°05. 

p Before the blow-pipe-it exhaled a sulphureous odour, but was not 
used. 

The specimen was reduced to powder and submitted to the action 
of a magnet of considerable power, but no attractable particles were 
separated. A portion was heated to redness on a platina spoon ; it 


1824.} New Scientific Books. 237 


emitted the sulphureous odour, and its weight was diminished rather 
more than 21 per cent.; the residue acquired a brown colour; it was 
again presented to the magnet, but nothing was attracted. 

The composition of this meteoric mass I found to be : 


DUNPMUL ose serarecmas LOO 


EC awe SS te Le cite 29°5 
Aluminat)’. os 2 eer 4°7 
[VES SEEGER fad Osea a trace 
Magnesia”. i Gid45.. 06 5 24°8 
CHFOMEe js (isos 3 Dy site ae CAPO 
Tron 353-9 Xt. os. pared (14.9 
Mickel oes ce Soe QS 
98°5 


1000 
(Phil. Mag. Ixiii. 16—19.) 


ArTICLE XVII. 
NEW SCIENTIFIC BOOKS, 


PREPARING FOR PUBLICATION, 


C. Tennant, Esq. has in the press, in 2 vols. 8vo. a Narrative of a 

Tour through Parts of the Netherlands, Holland, Germany, Switzer- 
land, Savoy, and France, in the Years 1821, 1822, including a De- 
scription of the Rhine Voyage in the middle of Autumn, and the Stu- 
pendous Scenery of the Alps in the depth of Winter. 
- Shortly will be published, by Mr. Benecke, of Lloyd’s, a Treatise on 
the Principles of Indemnity in Marine Insurance, Bottomry, and 
Respondentia, containing practical Rules for effecting Insurances, and 
for the Adjustment of all Kinds of Losses and Averages. 

Capt. Parry's Second Voyage of Discovery is nearly ready for pub- 
lication. 

Thomas Hewson, AB. is about to publish Observations on the His- 
tory and Treatment of the Ophthalmia accompanying the Secondary 
Forms of Lues Venerea. 

Moscologia Britannica, containing the Mosses of Great Britain and 
Treland, systematically arranged and described ; by W.J. Hooker, and 
Thomas Taylor, MP. is in the press. 

Mr. George Dyer is preparing “ The Privileges of the University of 
Cambridge.” 
JUST PUBLISHED. 

A Selection of the Geological Memoirs contained in the Annales des 

ines, with a Synoptical Table of Equivalent Formations, in English, 
French, and German, &c. With 11 Plates. 8vo, 18s. 


238 - New Patents. (Marcu, 
’ A Grammar of Infinite Forms; or the Mathematical Elements of 
Ancient Philosophy and Mythology ; by W. Howison. Post 8vo. 5s. 
A Compendious View of the History of the Darker Ages ; by C. 
Chatfield, Esq. 8vo. 7s. 6d. 
Prodromus Systematis Universalis Regni Vegetabilis, auctore Aug. 
P. de Candolle. Part I. Thick 8vo. J. 5s. 


ArticLe XVIII. 


NEW PATENTS. 


G. M. Glascot, Great Garden-street, Whitechapel, brass-founder, 
and T. Michell, Upper Thames-street, gent. for their improvements in 
the construction or form of nails to be used in or for the securing of 
copper and other sheathing on ships, and for other purposes.—Dec. 9. 

T. Horne, the younger, Birmingham, brass-founder, for improve- 
ments in the manufacture of rack pullies in brass or other metals.— 
Dec. 9. ' 

W. Furnival, Droitwich, salt-manufacturer, and A. Smith, Glasgow, 
master-mariner, for their improved boiler for steam-engines and other 
purposes.—Dec. 9. 

Sir H. Heathcote, Surry-street, Strand, for his improvement of the 
stay-sails generally in use for the purpose of intercepting wind between 
the square sails of ships and other square-rigged vessels.—Dec. 13. 

J. Boot, Nottingham, lace-manufacturer, for his improved apparatus 
to be used in the process of singing lace and other purposes.— Dec. 16. 

P. J. B. V. Gosset, Queen-street, Haymarket, merchant, for produc- 
ing various shapes, patterns, and sizes from metals, or other materials, 
sy of receiving an oval, round, or other form.—Dec. 18. 

. Greenwood, Gildersoun, near Leeds, machine-maker, and J. 
Thackrah, surgical mechanist, Leeds, for their improvements in pat-: 
terns and clocks.—Dec. 27. 

. J. Vallance, Esq. Brighton, for his improved methods of freezing 
water.—Jan. 1. 

- F, Devereux, merchant, Cheapside, for certain improvements on the 
mill or machine for grinding wheat and other articles, commonly 
known by the name ofthe French Military Mill—Jan. 8. _ 

J. Foot, Charles-street, Spitalfields, silk-manufacturer, for his im- 
proved umbrella.—Jan. 15. ; 

J. White, New-road, Marylebone, architect, for his floating break- 
water.—Jan. 15. 

J. Finlayson, Muirkirk, Ayrshire, farmer, for certain improvements 
on ploughs and harrows.—Jan. 15. 

Jean le Grand, Leman-street, Goodman’s-fields, vinegar-manufactu- 
rer, for certain improvements in fermented liquors, and the various 
products to be obtained therefrom.—Jan. 15. 

W. Gutteridge, Dean-street, St. Fin Barrs, Cork, musician and land- 
surveyor, for certain improvements on the clarionet.—Jan. 19. 


1824.) . Mr. Howard’s Meteorological Journal. 239 


Anticte XIX. 


METEOROLOGICAL TABLE. 


eee 
y Baromerer, THERMOMETER, 
1824, | Wind. Max. Min. Max. | Min. {| Evap. | Rain. 


ee eens | ee, ee 


Ist Mon. 
Jan. 1, W 29°49 29:46 48 36 Bs 
2N Wi) 30°31 29°49 47 32 oe 
3N WI 30°60 30°31 45 28 _e 
4S WI 3062 30°39 40 28 oe 
5S WI 30°45 30°35 40 28 eee 
6 Var. | 30°45 30°35 40 28 pie 
7N WI 30°45 50°44 38 30 ue 
8 Var. | 30:44 | 3037 | 40 | 32 | — 
9S Wi 30:37 30°29 45 34 ve 
10'S_ W| 30°39 30°21 45 | 38 _ 23 
ll] N 30°58 30°39 43 23 tera 
12S Wi 30°60 30°58 33 19 Bs 
13S W| 30°60 |: 30°53 31 23 be 
14N WI 30°53 30°48 31 26 t. 
AGING .W. . 20:67. fo-90°45: br BOol o6silcan | 
16) N 30°68 30°66 36 24 fas 
17;/N W| 30:70 30°56 38 24 = 
18iIN W| 30°56 30°38 40 31 od sz 
191 W 30°38 30°28 42 36 aa 
20IN WI 30°28 29°90 42 38 = 06 
21158 Wi 29:90 29°43 44 38 i, 31 
2255 W! 29°43 28°98 51 42 _ 15> 
23|N Wi 29°85 28°93 48 34 vas 
24IN WI 30:10 29°85 50 34 cat 
25) W 30°24 30°10 54 49 —_ 
26) W 30°24 29°99 54 Al a 
27/5 WI 29°99 29°71 54 36 = 09 
285 W\| 29°97 29°68 46 35 Ban 03 
29N WI 30:26 29:97 42 24 . 
30| W 30°26 30°16 38 26 at 
31, S 30°16 30°11 43 24 “87 


3070 | 2893 | 54 | 19 | o87| o87 
The observations in each line of the table apply to a period of twenty-four hours, 


beginning at 9 A.M. on the day indicated in the first column. A dash denotes that 
the result is included in the next following observation. 


240 - Mr, Howard’s Meteorological Journal. (Marcu, 


REMARKS. 


First Month,—1. Cloudy and fine: boisterous night. 2. Fine: much wind, but 
calm at sunset: the Cirroeumulus has prevailed these two days. 3. Very fine day. 
4, Little wind: a dense fog came on suddenly in the forenoon, and the day was misty 
after. 5—9. Fine days. 10,'Fair: some rain in the night. 11, Fine: cloudy. 
12, 13, 14. Hoar frost, with foggy nights: a great quantity of rime gradually accumu- 
lated on the trees, chiefly on the south side of the branches, presenting a magnificent 
spectacle. 15, Overcast, p.m. with a little snow: the wind having risen a little, the 
rime has fallen from the trees unmelted. 17. It is now winter under the trees, with a 
spring-like appearance every where else: the afternoon actually presented the rudi- 
ments of a thunder-cloud, sueceeded by beautiful Cirrocumuli in bars; amidst which 
the moon rose with the calm lustre of a sumimer’s evening. 19. Cirracumulis above 
Cirrostratus in light beds over the whole sky. 20. Cumulostratus: after which Nimbi 
and an overcast sky: wind, with some rain in the night. 21. A hollow wind; with 
rain, mostly in the night, 22. Overcast: showers: in the night the wind rose, and it 
blew hard towards morning. 23. Fine morning: Cirrostratus, with Cirrus aloft: 
windy. 24—27. Overcast and cloudy. 28. Showery. 29. Fine: Cumulus, with 
Cirrocumulus,. 30, Hoar frost: very clear at night. 31. Hoar frost: little wind, but 
with a hollow sound in the trees): -very fine day. 


RESULTS. 


Winds: N, 23 S,1; SW, 10; W,5; NW, 11; Var. 2 
Barometer: Mean height ~ : 


For'the month, .......esesessesecectepeececesvece SU°199 inches, 
For the lunar period, ending the 22d ........0seee0+- 30°19 
For 14 days, ending the 6th (moon south) ........... 29°874 
For 13 days, ending the 19th (moon north) .....+..,. 30°483 


Thermometers -Mean height 


"For the wiouthi: .. ccs shes cetneniece cenenpans ott eaguy Same 
For the lunar period. ....+++ere-srevesserecceraqees 37-172 
For 30 days, the sun in Capricorn.......s00.++ess++ 37150 


BiPbMaratapns To 6050 0 Fb onde ocd Fecnp ne Peers Ben anaes PS co delloce « SOF in, 


Rain. sack tnmaknebs step caine diene s> ecidiea ok” « Sect wa ae 0-87 
Results omitted by an oversight last Month. 


Barometer: Mean height 
~ For the lunar period, ending the 24th. <..sees++ee+++ 29°979 inches, 
For 15 days, ending the 10th (moon south) ,. ....-9e- 30°047 
For 13 days, ending the 23d (moon north)... ....+«+. 29°892 


* Theronmometer : ; 
For 30 days, the sun in Sagittarius. ....00. ++ «+++ AN*15O° 


Laboratory, Stratford, Second Month, 21, 18%. L. HOWARD. » 7 


ANNALS 


PHILOSOPHY. 


APRIL, 1824, 


Articce I. 


_ On Expansions, parti 
OD) 


cularly on those of Glass and Mercury. 
By Mr. Crichton. 


(To the Editor of the Annals of Philosophy.) 


SIR, Glasgow, March 10, 1824. 


A THOROUGH acquaintance with the various laws which 
regulate the expansive powers of different bodies, is of such 
acknowledged importance in all experimental researches, that 
the most eminent scientific men of this and other countries have 
their names identified with some correction, or new determina- 
tion, in this branch of knowledge. 

So late, however, as 1518, when MM. Dulong and Petit insti- 
tuted the experiments detailed in their well-known prize memoir, 
teeta in the 7th volume of the Annales de Chimie et de 

hysique, those gentlemen, though in possession of determina- 
tions by Roy, Smeaton, Deluc, Lavoisier, Laplace, and many 
others, nevertheless deemed it expedient to try anew what the 
expansions were of glass and mercury, as these were to form the 
basis of all their after investigations. 

_ They begin with finding the absolute dilatation of mercury. 
Their method of doing this is so ingenious, that very general 


reliance seems to be placed on the number they assign, iG for 
the dilatation of mercury in thermic unit from the temperature 
of ering, to that of boiling water. 
- Dulong and Petit next proceed to ascertain the appa- 
New Series, vou. Vil. R 


242 Mr. Crichton on Expansions. [APRIL, 


rent dilatation of mercury in glass, which they effect in the usual 
way, by subjecting a known weight of that fluid, contained in a 
glass vessel carefully deprived of air and humidity, to the 
increase of temperature in the same thermic unit ; then dividing 
the weight of the quantity contained in the vessel at freezing, by 
the weight of the quantity expelled by boiling, they obtain the 


quotient 64-8, and thence infer, that ree is the apparent dilata- 


tion of mercury in glass. 

These very able experimenters justly insist on the great pre- 
cision of which this method is susceptible. In trials I have 
made, with vessels holding from 200 to 500 grains, the capillary 
opening was so small, that a quantity, corresponding to less than 


a of a degree could be detached when expelled ; yet minute as 


this portion is, it was very palpably noted by the balance, which 


turned with anaes of a grain. 


Every one who knows the difficulty of obtaining tolerably 
uniform results from pyrometrical measurements, will readil 
admit the advantages of the method adopted by MM. Dulong 
and Petit, when with them we recollect, that “ dans les mesures 
directes de dilatation des solides, l’incertitude se trouve triplée 
en passant de |’expansion linéaire a l’expansion en volume.” 
An error, however, of considerable importance has entered into 
all computations from the data thus obtained, which unac- 
countably remains hitherto undetected ; for, though that portion 
of a fluid, detached by increase of temperature, from a glass 


vessel of known volume, is indeed the fraction expelled, yet this 

fraction (taking the case of MM. Dulong and Petit -_ as “le 
> 

poids du mercure qui en sortait,” does by no means denote the 

dilatation of mercury im glass ; consequently the dilatation they 

deduce as that of glass itself must be erroneous. 

To illustrate this, let us suppose that a vessel, containing 
64:8 parts by weight of a fluid, throws out one of those parts by 
increase of temperature ; it is evident that the dilatation of that 
one part has not been taken into account, for were 7 put into 
another vessel just holding it at 32°, then would another dilata- 

1 
4199-04 
this last portion must the operation be repeated, and so on to 
infinity ; the successive expansions resolving themselves into a 


tion take place of 


of the original volume, and still with — 


1 
63°8 
another view of the matter, the vessel having been heated to 212°, 
there will remain within 63:8 parts ; these cooled to 32° leave at 
top an empty space = 1, which heating to 212° will fill up; this 


i 
one part, therefore, or a, of the volume ofthe mercury, will be 


series, the sum of which is —, or real dilatation. Or, to take 


1824.] Mr. Crichton on Expansions, 243 


alternately occupied by it, or vacant, as the temperature is 32° 
or 212°; so that weighing in this experiment, serves merely to 
determine what parts the vessel contains at boiling. 

MM. Dulong and Petit having fixed the absolute dilatation of 

I 
648’ 
ceed to determine that of their vessel. But here an error has 
been committed not less important than the other; for in order 
to obtain the dilatation in question, they adopt a common but 
false assumption ; that if the absolute dilatation of a fluid, and 
its apparent dilatation in a vessel be known, the difference 
between these must represent that of the vessel itself, and of 


1 ; ; 100. 
_ mercury at 5, and its apparent dilatation in glass at pro- 


: 1 1 1 . 
course give lag = A gaz 28 the number ; the result here is 
far from the truth, and would still have been so, though the 

l : 
proper number <2, had been used instead of —— the difference, 
in neither case, giving the real dilatation which the vessel must 
have undergone, in the interval of temperature between 32° and 
212°. 

To learn the true dilatation in this instance, we have only to 
recollect, that whatever quantity is expelled from a vessel, by a 
given increase of temperature, something more would be expelled 
if the vessel itself did not expand; and that this supposed por- 
tion must be added to the quantity expelled at the higher tem- 
perature (as found by experiment), and deducted from that then 
remaining in the vessel, that each may represent what it would 
be, if the vessel were not liable to expansion: the following 
illustration will furnish a concise general formula, for all similar 
dilatations of vessels. 

To find this correcting quantity, we may take the coefficient 
of the dilatation of the vessel to express its capacity at any given 
temperature, as 32°, consequently the same coefficient, plus 
unity, will express its increased capacity at the higher tempera- 
ture, 212°. 

Now, in the case of MM. Dulong and Petit, if @ be that coef- 
ficient, g and g + 1 will respectively represent the capacities at 
the given extremes of temperature; and from what is said above, 
63-8 — a must be the corrected contents, as 1 + ts is the 
true expelled quantity at 212°, then, making the former of these 
divided by the latter = the coefficient of the absolute dilatation 
638g _ cfr, ; mas ‘ 
eran 55°5, we obtain g = 433°301, or 
ai for the absolute dilatation of the vessel used by MM. Du 
long and Petit, and not <= as in the table, Annales, p. 138 ; 


R 2 


of mercury, that is, 


244 — Mr. Crichton on Expansions. [APRIL, 
giving, besides, for elongation of a glass rod taken as 1 at freeze 
ing, et at boiling water, instead of ee 


If the above reasoning be conclusive, it necessarily follows, 
that the corrections for the expansion of glass, as applied to the 
air and mercurial thermometers, in their after detailed experi- 
ments on capacity for caloric, and the relative times of cooling, 
must, to this extent, have been defective. 

The fallacies which MM. Dulong and Petit have imadvert- 
ently overlooked, affect not only all calculations where expan- 
sion of glass should be attended to, but must have led to false 
results as to the dilatations of the metals in table 4, p. 141, ven 
though the premises in the preceding page were true, viz. that 
“le volume sorti represente évidemment la somme des dilata- 
tions du mercure et du métal diminuée de la dilatation du verre.” 
Now this formula is manifestly wrong, since the volume driven 
out does not represent the dilatation of the mercury, and that of 
the vessel we have shown to be overrated. 

By the above corrected method, the absolute dilatation of 
water, from its state of maximum density at 42°3° to 212°, was 


1 : 
found to be ==—;. This number is greater than that generally 


received; but as 39° has sometimes been assumed as the point 
of greatest density, instead of 42:3°, this circumstance, which 
is in effect the same as if 45°6° had been adopted, will, to a cer- 
tain extent, account for the variation. 

The same method gave for the dilatation of air by the increase 


, ‘ i 
2 890 4, 9190 I found —— 
of temperature from 32° to 212 > 56546 M. ussac 3666 


though by means which few will think capable of minute preci- 
sion. The vessel used in my trial was hermetically sealed at 
the extremes of temperature ; this sealing was performed at an 
opening through a capillary fibre, and to ensure complete dry- 
ness, the vessel had been long heated fully to redness just before 
making the experiment. 

In the Memoir, MM. Dulong and Petit particularly mention, 
that they found all tbe varieties of glass which they used, to have 
the same expansive power; this appears surprising, for f can 
truly afhrm, that every specimen of crystal differs more or less 

1 1 
ag *° Gp aS the 
fractions expelled, in the range from freezing, to boiling water, 
even while the mercury has undergone the same rigorous and 
repeated boilings, these fractions indicating elomgetiqns of glass 


: 1 
rods, by that increase of temperature, from 755, t0 7495- 


That crystal which is the most colourless is commonly the 
most ductile and least expansible ; but neither from its specific 
gravity, nor from its tint, as seen through the axis ofa tube, can 


from another; trials by mercury give from 


1824.) Atomic Weight of Boracic and Tartaric Acids. 245 


we estimate its expansive power ; besides, itis commonly known 
that tubes of every description, in course of time, become less 
ductile ; hence it is not improbable, that a change takes place in 
their rates of expansion. 

Having been at first induced by the highly sanctioned cele- 
brity of the Memoir to peruse it with a view to establish a 
proper graduation of the higher part of the thermometric scale, 
I may, on some future occasion, show, what that graduation 
ought to be, for the degrees above 212°, and for those below 
32°; beyond which two unalterable points, no scale hitherto 
laid down, gives indications corresponding to those of the 
degtees within the limits of the primary thermic unit. 

‘Besides, as it must be granted that an error exists in, the 
lower part of the mercurial thermometer, so must it likewise in 
that filled with spirit of wine, and probably to a greater extent ; 
as perhaps it has never been proved, that the expansive powers 
of alcohol are, for equal increments of heat, similar to those of 
mercury, particularly at the low temperatures reported by recent 
navigators, as having been observed in the polar seas. 

Indeed it would be no easy matter, except in climates where 
very low temperatures prevail, to determine the rates of the 
spirit thermometer, with reference to the mercurial one ; but to 
attempt doing this by comparing the two instruments as at pre- 
sent constructed, would lead only from one erroneous:system of 
graduation to another. 

It will have been perceived that some of the expansions stated 
above, are greatly less than those given by the best authors. 
But as the deductions are founded on the supposition that the 


absolute dilatation of mercury is really a either the legitimacy 
of these deductions, as now made, or the number itself, may be 
called in question, if any credit be due to former determinations, 
by experimenters of very high reputation. 
JAMES CRICHTON, 


Artic.e II, 


On the Atomic Weight of Boracte and Tartaric Acids. By 
Thomas Thomson, MD. FRS. Regius Professor of Chemistry 
in the University of Glasgow. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, 
In the table of the atomic weights of chemical substances 
which you inserted in the Annals for March, 1824, I perceive 
that you make the atomic weight of boracic acid 2°75, and of 


246 Atomic Weight of Boracic and Tartaric Acids. [APRit, 


tartaric acid 8375. These numbers being probably derived 
from my experiments on these acids in the New Series of the 
Annals (vol. ii. p. 131 and 138), it may be proper to state, that 
by subsequent experiments I have satisfied myself that the true 
atomic weights of these two acids are as follows : 


BOraCiC, S010) 1.0 «sine aie Py SN! Kr 
WPT EMEICLENCIEL no sik 5. 0, shbicis craahs exeliorkilhe ioe eee 


1. By turning to my experiments on boracic acid, you will 
find that I was not quite satisfied of their accuracy. I was 
anxious, therefore, to find some method which would be suscep- 
tible of greater precision, and found it last summer in fluoboric 
acid, which is a compound of 


WTMOTIE ACIGs caso tic eeste as tie saselele oa 
MII GUI so Sac aachecaen case ete ct 


poe 


4°25 


_ And its atomic weight is 4:25. I had previously determined the 
atomic weight of fluoric acid to be 125, and I knew from my 
old experiments that the atomic weight of boracic acid was at 
least as high as 2°75. It is obvious from this that fluoboric 
acid is a compound of an atom of each of its constituents, and 
consequently that an atom of boracic acid is 3. 

Davy’s analysis of the hydrated boracic acid must be nearer 
the truth than those of Berzelius and my own. I have repeated 
them again with the same result as before. No doubt some of 
the boracic acid had made its escape during the application of 
the heat. . 

2. My experiments on tartaric acid were made with the crys- 
tals of that acid. I began to suspect that these crystals, which 
are usually large, might contain some water mechanically lodged 
between their plates. I, therefore, had recourse to tartrate of 
potash, which contains no water of crystallization, and which 
may be made anhydrous by exposure to a heat of about 212° for 
a sufficient time. 14:25 grains of this anhydrous salt were dis- 
solved in water and mixed with a solution of 20°75 grains of 
nitrate of lead. After the tartrate of lead had precipitated, the 
supernatant liquid was tested by tartrate of potash, and by nitrate 
of lead, but was not affected by either. Tartrate of lead is very 
slightly soluble in water. The consequence of this is, that sul- 
phate of soda when dropped into the supernatant liquid in the 
above experiment occasions a sensible precipitate. 

The crystals of tartaric acid contain | atom of water united to 
1 atom of acid ; hence their true atomic weight is 9°375, and 
not 9:5 asI stated formerly. 

Tam, dear Sir, yours truly, 
Tuomas THOMSON, | 


1824.] 


Corrections in Right Ascension. 


247 


ArT. III.— Corrections in Right Ascension of 37 Stars of the Green- 
wich Catalogue. By James South, FRS. 


(Continued from p. 45.) 


y Pegasi 
Mean ar2n. m. s. 
1924. $0 4 11:17 
April 1]+ 0°52”\— 
2 53 
3 55 
4A 56 
5 57 
6 59 
7 60 
8 61 
9 63 
10 64 
11 66 
12 67 
13 69 
14 70 
15 72 
16 73 
17 75 
18 76 
19 78 
20 80 
21 82 
22 84 
23 86 
24 88 
25 90 
26 92 
27 94 
28 96 
29 98 
30) 1-00 
May | 02 
2 04 
3 O07 
4 09 
5 11 
6 14 
; 1 16 
8 18 
9 21 
10 23 
ll 26 
12 28 
13 31 
14 34 
15 36 
16 39 
17 42 
18 45 
19 48 
20 50 
21 53 
22) 56 
23 59 
24 62 
25 65 
26 67 
ina hd, 10 
28 13 
29 16 
30 79 
31 82 


Polaris 
b. m. s. 
0 58 2°66 


4L-51” 
A146 
Al-41 
41°36 
41°30 
41°25 
A120 
Al15 
41-10 


41-04 
40°89 
A075 
40°60 
40°46 
40°31 
40:10 
39°89 
39°68 
39-47 
39°26 
38°99 
38°72 
38°45 
38°17 
37-90 
37°57 
37°23 
36°90 
36°57 
36°23 
35°85 
35°46 
35-08 
34-69 
34:31 
33°86 
33°40 
32°95 | 
32°50 
32°04 
31-54 
31-04 
30°55 
30°05 
29°55 
28:99 
28°44 
27°88 
21°33 
26°17 
26°18 
25°59 
25°01 
24-42 
23°83 
23°18 
22°52 
21-87 
21-21 
20°56 
19-90 


a Arietis 
hem. s. 


157 16°42 9 53 5-44 


a Ceti 
‘he m. Ss. 


+ 0°62" 4 0-77! 
62 17 
62 16 
63 76 
63 76 
63 15 
63 75 
64 74 
64 74 
64 13 
64 13 
65 13 
65 13 
66 73 
66 13 
67 73 
67 72 
68 72 
68 72 
69 72 
70 72 
ve 13 
72 13 
13 74 
74 74 
15 74 
16 15 
18 75 
19 15 
80 76 
81 17 
83 78 
84 78 
85 19 
87 80 
48 Sl 
89 sl 
91 82 
92 83 
94 84 
96 &5 
98 86 

1:00 88 
02 89 
04 90 
06 92 
08 93 
10 94 
12 95 
14 97 
16 99 
19 | 1-00 
21 0g 
23 04 
25 05 
27 07 
30 09 
32 10 
34 12 
31 \4 
40 16 


4.25 50°01]5 3 42°21) 5 


Aldebaran] Capella 
hem. s. /h. m. s. 


Rigel 
h.m. s. 
6511 


digest x wiry, 
h. 


- S. 
515 1052/5 45 385° 


V4 193] 4 177" 14 115’ | + 1°64") 4 1-56” 


22 15 13 62 54 
21 13 i2 61 53 
20 va 10 59 51 
19 69 09 58 50 
18 67 07 56 48 
16 66 06 55 46 
15 64 04 53 45 
14 62 02 51 43 
13 60 ol 50 42 
12 59 00 49 Al 
1 57 | 0-99 48 39 
10 56 98 47 38 
09 54 97 45 37 
08 53 96 AA 36 
07 52 95 43 34 
06 50 93 42 33 
05 48 92 4O 32 
o4 47 91 39 30 
04 AG 89 38 29 
04 45 88 31 28 
03 44 87 36 QT 
03 43 87 35 QT 
03 42 86 35 26 
03 Al 85 34 25 
02 4O 84 33 24 
02 38 83 32 24 
02 37 83 31 23 
02 36 82 30 22 
ol 35 81 29 21 
ol 35 81 29 20 
ol 34 80 28 20 
ol 34 80 28 19 
ol 33 19 28 19 
ol 33 19 27 18 
ol 33 78 27 17 
ol 32 18 27 17 
ol 32 18 27 16 
ol 32 11 27 15 
ol 31 51 26 14 
02 31 77 26 14 
02 31 17 26 13 
02 31 77 26 13 
03 31 17 26 13 
03 31 17 26 13 
O4 31 16 QT 12 
04 32 16 27 12 
05 32 16 27 12 
05 32 16 27 iL 
06 32 16 27 il 
07 33 16 21 ll 
08 33 17 28 il 
09 34 71 28 ll 
10 35 18 28 12 
i 35 18 29 12 
12 36 78 29 12 
12 36 19 30 12 
13 31 19 30 13 
14 38 80 31 13 
15 39 80 31 13 
16 40 81 32 13 


248 Corrections in Right Ascension of [Aprin 


Sirius oe Procyon | Pollux j« Ee eer . mee é Macey 
Mean AR} h. $s. h. m. s. |h.m h. n h. h. n 
1824. J |b é'37 adh 3 ‘21-46 7 30 5°32)7 3 ‘33: 1819 1B ‘56 “uuly 38 ‘sObriti 40 Lyall 4131-86 


pe 


18 1556 07 


April 1)+ 1°47" + 2°50") + 2°07”| + 2-48”) + 2-45") 4+ 2-831 + 3:06”|+ 3:00”|+ 3-04” 


Z A5 48 05 46 44 82 06 00 05 
3 43 46 04 Ad 42 81 06 ol 06 
4 AQ 45 02 AQ Al 80 05 01 06 
5 40 A3 ol Al 40 79 05 Ol OT 
6 39 Al 1:99 39 38 78 05 02 08 
1 38 39 98 37 37 78 05 02 09 
8 36 38 96 35 36 76 04 03 10 
9 34 36 95 33 34 16 04 03 Il 
10 31 34 93 3l 33 - 75 04 04 12 
1] 29 32 91 29 32 74 04 03 13 
lg 28 sl 90 28 30 73 03 02 13 
13 26 29 88 26 29 12 03 02 14 
14 24 27 87 25 28 71 03 ol 14 
15 23 25 $5 23 27 70 02 00 15 
16 21 24 83 22 25 68 02 2°99 15 
7 19 22 81 20 24 67 02 99 16 
j 18 20 80 19 23 66 Ol 98 lq 
19 16 19 79 Lip 22 65 Ol 97 17 
20 14 17 OU 15 20 64 00 96 18 
21 13 15 76 13 19 63 2:99 96 18 
22 11 14 74 12 17 62 99 95 18 
23 10 12 73 10 16 61 98 95 18 
24 os ll 72 09 15 59 98 95 19 
25 07 09 70 07 14 58 97 94 19 
26 06; - OT 69 06 12 57 97 94 19 
| 04 06 61 04 11 56 96 93 19 
28 03 04 66 03 10 55 96 93 19 
29 ol 3 64 ol C9 53 95 92}... 20 
30} 1-00 01 63 1:99 07 52 94 92 20 
May 1| 0-99 2°00 62 98 05 51 93 91 20 
98 1-98 61 97 04 50 92 90 20 


2 

3 97 97 60 95 03 49 92 90 20 

d 96 96 59 94° 02 AT 91 89 20 

5 95 95 58 93 00 46 90 88 20 
6 93 93 5T 92 1:99 45 89 87 20 
7 
8 
9 
10 


92 92 55 91 97 A4 88 87 20 

91 91 54 90 96 43 87 86 20 

90 90 53 88 94 Al 87 85 20 

89 88 52 87 93 40 86 84 20 
11 88 87 51 86 92 39 85 83 20 
12 87 86 30 85 91 38 84 82 20 
13 86 85 49 84 90 36 83 82 20 
14 85 84 48 83 89 35 82 81 20 
15 84 83 AT 82 88 34 81 80 20 
16 84 82 AT 81 86 33 81 79 19 
17 83 $1 46 80 85 32 80 78 19 
18 82 79 45 19 84 31 79 718 19 
19 81 78 44 18 83 29 78 17 19 
20 80 17 43 17 82 28 TT 76 19 
2 | 80 716 42 76 81 27 76 15 19 
22 79 76 42 15 80 26 15 74 18 
23 719 15 Al 15 79 25 74 73 18 
24 79 75 Al 74 78 24 73 72 17 
25 78 74} 40 73 TT 23 12 71 17 
26 18 74 40 12 16 21 71 vel 16 
27 1T 73 39 71 75 20 71 10 16 
28 17 13 38 71 73 19 70 69 15 
29 76 | - 72 38 10 72 18 69 68 14 
30 16 val 3T 69 70 17 68 67 14 
31 76 7 37 69 70 16 67 66 13 


18244] Thirty-Seven Principal Stars. 249 


| Arcturus Pe a Libra: hie Bor. Ceige Antares 
Mean AR} |p, s. 


S. h. 
1s24. J 1a Fastin Mr 963 18 Bd as|)5 3 36 dr 16 188701 


a ee * ees ks ea 


iF 6 37° “3 iy 36.46: oy 193058 ‘9 1937 53°68 


— ——_. —— |_ 


April 4, +2914 verbal + 2-60" | 4 2°66"|+ 2-96"|4 217/44 ets 4 1:30" 4 141" 
93 


05 62 68 | 3-00 20 33 44 
3 94 06 64 10 03 22 is 37 AT 
4 95 0s 66 72 07 25 17 AO 50 
5 96 10 68 7A 11 QT 20 Ag 53 
6 91 iat 70 16 15 30 23 47 55 
1 99 13 73 19 19 32 25 50 58 
§| 3-00 15 15 81 22 35 28 53 61 
9 02 16 71 83 26 38 30 57 64 
10 03 18 79 85 30 40 33 60 67 
1] 04 19 81 87 33 42 35 63 70 
42 05 Qi 82 88 35 A5 38 66 13 
13 06 92 84 90 38 Al 40 69 15 
14 07 23 86 91 AO 50 43 12 18 
15 0s 25 87 93 43 52 Ad 15 sl 
16 08 26 89 95 A5 55 48 18 84 
7 09 QT 90 96 48 57 50 81 8T 
18 10 29 92 98 5l 60 53 85 89 
19 11 30 94 3:00 54 62 55 88 92 
20 12 32 96 02 56 65 58 92 95 
21 13 33 9T 04 58 67 60 95 98 
22 13 34 99 05 60 69 62 98| 201 
23 14 36 | 3-00 07 63 72 64 | 2-01 04 
24 14 87 02 08 65 14 66 04 OT 
25 15 38 03 10 67 16 69 07 10 
26 16 39 o4 11 69 18 71 10 13 
21 16 40 06 13 11 81 73 13 16 
28 17 42 07 14 14 83 15 16 19 
29 17 43 09 16 16 85 41 19 22 
30 18 44 10 18 18 87 79 22 25 

May | 18 45 ll 19 80 89 81 25 28 
2 19 46 12 20 82 91 84 28 31 
3 19 46 13 22 84 93 86 31 34 
4 19 AT 14 23 86 95 88 34 37 
5 20 48 15 24 88 97 91 31 40 
6 20 49 16 25 90 99 93 40 42 
7 20 49 18 26 92 | 3-01 96 A3 A5 
8 20 50 19 27 94 03 98 46 As 
9 21 51 20 29 96 05 | 3:01 49 51 
10 21 52 21 30 98 01 03 52 54 
1) 21 53 22 31 4-00 09 05 54 57 

12 21 53 23 32 ol 10 07 57 59 
13 21 54 93 33 03 12 09 59 62 
14 21 55 94 34 04]. 14 11 62 65 
15 21 55 25 35 06 15 13 64 68 
16 22 56 26 36 08 VW 14 67 70 
1 22 51 21 37 09 19 16 69 13 
18 22 57 27 38 11 21 i8 72 16 
19 S2 58 28 39 12 22 20 74 79 
20 22 59 29 40 14 24 22 17 81 
21 22 59 29 41 15 25 24 79, 84 
2 22 59 30 41 17 21 25 81 86 
23 21 59 30 42 18 28 QT 84 89 
24 21 60 30 43 19 30 29 86 91 
25 21 60 31 43 20 31 31 88 94 
26 19 60 31 Ad 22 33 82 90 96 
, 21 19 60 32 AA 23 34 34 92 99 
28 19 61 32 45 24 36 86 94] 3-02 
29 19 61 32 46 26 1 38 97 04 


30 19 61 33 AT QT 39 89 99 OT 
31 19 61 33 AT 28 40 40' 301 09 


250 Corrections in Right Ascension of [ApriL, 


x ape 8 ge : a Near ies a oe a Aquarii |Fomalhaut | a Pegasi '«Androin. 


Mean AR} |h. s. |b. hom. s/h. ms. [hem. s. hom. s. 
1824, ¢ 19 21° 38.1946 40° 33 0 3. i" 02 2035 26° 31 2156 44° Soha 47 54:34)22 56 0°17 23 59 18°67 
April 1/+ 1°42") + 1°42”) + 1°56") 4 0°32”/+ 0-92") 4 *81/|+ 0:59") + 0°36” 

2 45 45 59 35 95 83 62 3T 
3 48 48 62 39 97 86 65 39 
4 51 51 65 42 99 88 68 40 
5 53 53 68 46 1-01 91 RA Al 
6 56 56 70 49 OL 93 7 43 
7 59 59 73 52 06 95 77 A4 
8 62 62 76 56 08 97 79 Ad 
9 64 65 79 60 ll 1-00 82 47 
10} . 67 68 82 63 13 02 1 48 
11 70 71 85 67 15 04 77 50 
12 13 TA 88 70 18 07 19 52 
13 76 16 91 14 20 09 82 53 
14 19 "9 94 17 23 12 84 55 
15 82 82 97 81 25 14 86 56 
16 84 85 2°01 84 28 16 88 58 
V7 87 88 04 88 30 19 90 60 
18 90 91 07 92 33 21 92 62 
19 93 93 10 95 35 Q4 95 64 
20 96 96 13 99 38 26 97 66 
21 99 99 16 1-03 4l 29 99 68 
22| 202) 202 19 06 43 32 1-02 70 
23 05 05 22 10 46 35 04 72 
24 08 08 25 14 A9 38 OT 14 
25 11 11 28 17 51 Al 09 TF 
26 14 14 31 21 54 43 12 79 
27 17 17 34 25 57 A6 14 sl 
28 20 20 37 28 60 49 17 83 
29 23 23 40 32 62 52 19 85 
30 26 26 43 36 65 55 22 7 
May ] 29 29 46 AO 68 53 25 90 
32 32 50 43 71 61 28 92 

3 oo 35 53 AT 74 64 30 95 
4 38 38 56 51 77 67 33 97 
5 Al 4l 59 55 80 70 36 1-00 
6 43 43 63 58 83 i 39 02 
7 46 46 66 62 86 76 49 05 
8 49 49 69 66 89 719 44 07 
9 52 52 73 69 92 82 AT 10 
10 55 55 16 13 95 85 50 13 
1] 58 58 19 TT 98 88 53 16 
12 61 61 82 80 201 92 56 19 
13 63 63 85 84 04 95 59 22 
14 66 66 88 87 07 98 62 25 
15 69 69 91 91 10 201 65 27 
16 72 72 93 94 13 04 68 30 
17 15 75 96 98 16 08 71 33 
18 17 V7 99 2-01 19 11 TA 36 
19 80 80 3°02 05 22 15 V7 39 
20 83 83 05 09 25 18 80 42 
2) S6 86 08 12 28 21 83 45 
22 88 88 1] 16 3l 25 86 48 
23 91 91 14 19 34 28 89 51 
24 93 94 17 23 37 32 92 54 
25 96 97 20 26 40 35 95 58 
26 98 99 22 30 43 38 98 61 
27; 3-01 3:02 25 33 46 42 2-01 64 
28 04 05 28 37 49 45 04 67 
29 06 08 31 40 52 49 07 710 
30 09 10 34 44 55 52 10 13 
31 Il 12 37 AT 58 55 13 76 


1824.] | Thirty-Seven Principal Stars. 251 


y Pegasi | Polaris | Arietis} «Ceti |Aldebaran| Capella | Rigel é@Tauri |x Orionis 
Mean Ri Bo th. h. s. |h, m.s. |h. m.-s, 
1824. 


h. m. s. |b, s. |b. m. s. 
1170 58 26611 57, 16-42/2 BS 544425 Bota” 3 ay) 


Ss 


5 6 51lie 15 10-5215 45 38-9: 
June 1) 4- 1-85” —19-93/\4 1-42”) 4 1016”) 4 1-18") 4 1-41) 4 0°82”! 41-339" | 4 114" 
2 88 | 18°57 45 20 19 A3 83 34 14 
3 91 17°90 48 22 21 44 84 35 15 
4 94) 17°24 50 24 22 AB 85 36 15 
5 97 | 16°52 53 26 24 AT 86 31 16 
6 200) 15-80 55 28 25 48 81 39 16 
1 03 | 15:09 58 30 QT 49 88 40 17 
§ 06) 14°37 61 33 28 51 89 4l 17 
9 09 | 13°65 64 35 30 52 90 42 18 
10 12 12-92 67 37 32 5A 9] 43 19 
1] 16 | 12719 710 40 34 56 93 45 20 
12 19 | 11°46 73 42 35 58 94 46 21 
13 22 | 10-73 16 45 37 60 95 48 22 
14 25 | 10-00 19 AS 39 62 96 49 23 
15 29 9-24 82 50 40 63 98 BI 24 
16 32 8-48 85 52 42 65 99 52 26 
17 35 1°72 88 55 44 67 | 1:00 54 QT 
18 39 6:96 91 57 46 69 01 55 28 
19 AQ 6:20 94 60 48 val 03 51 29 
20 45 5-41 91 63 50 73 05 59 30 
21 48 4-62 | 200 65 53 16 06 6] 32 
292 51 3°83 03 68 55 18 08 63 33 
23 54 3:04 07 70 51 81 10 65 35 
24 57 2:25 10 73 59 sek 61 36 
25 60 1:47 13 15 62 86 13 69 38 
26 63 0°68 16 18 64 88 | 15 71 39 
27 67 {+ O11 19 81 66 90 16/ 173 Al 
: 98 70 0:89 23) 84 69 92 18 75 42 
29) 13 1°68 26 86 71 95 20 | 77 44 
30 76) 2-48 29) «89 73 98 |. 22)! 79 46 
oe Sirius Castor | Procyon | Pollux | a Hydre | Regulus Leonis |@ Virginis \SpicaVirg. 
ope h. -m. 8. h.m. s. jh. m. 5. {/h. m. s. |b. m h. h, 
1824, 1637 2 Dgvig 7 28 215467 30 5°32)7 34 32°18|/9 18 6449's peat 40) 479) 1 41 3186 18 15 56-07 
June 1) + 0-76\+ 1-71") 4 1°36” + 1°68”) + 1°69”) + 2°15" + 2 66"|4 2°65"|+ 3-13” 
| 2) 76| 71 36 68 68| 14 65 | 64 12 
s| 76]; 7 36| 68| 67| 13 64| 63 12 
4 16 70 35 67 66 12 63 62 1k 
5 16 70 35 67 65 11/62 62 11 
6 76 10 35 67 64 10 61 61 10 
7; «16 70 35 67 63 | 09 60 60 09 
8B} 76 69 34 66 63 08 59 59 09 
9 16 69 34 66 62 OT 58 58 08 
10 16 69 34 66 61 06 51 57 oT 
11 a7 69 34 66 61 06! 56 56 07 
12 71 69 34 66 60 05 55 55 06 
13 18 70 34 66 60 04 54 54 05 
14 78 70 34 66 59 03 53 53 04 
15 18 10 35 66 58 03 52 52 04 
16 19 10 35 617 57 02 50 51 03 
17 79 71 35 67 57 ol rt) 50 02 
18 80 71 35 67 56 00 48 49 02 
19 80 1 35 61 56 00 AT 48 vl 
20 81 71 35 67 56 | 1:99 A6 AT 00 
21 81 72 36 68 55 99 45 A6 00 
22 82 72 36 68 5 98 44 45 | 2-99 
23 83 13 37 69 54 98 43 44 98 
24 84 13 37 69 54 97 42 48 97 
25 84 14 38 70 53 97 Al 43 96 
26 85 14 38 10 53 96; 40 A2 95 
| : 21 86 15 39 71 52 95 39 AL 95 
28 86 16 39 vat 52 94 38 40 94 


12 
73 


37 
36 


[APRIL, 


252 Corrections in Right Ascension. 
Arcturus |2 a Libre a Cor.Bor.la Serpent.| Antares |aHerculis|2Ophiuchi} « Lyre | y Aquile 
y . hom. s. hem. s. . s. |b. m. gs. [h. m. 8. [h, m. 6 © 
Mook a Ni F ps3 iT oa) 18 Pas N6 35 36-47 16 183791 ty 6 3772 1798 46°34 18 1058:99)19 37 53°68 
Sa" — Lod =, \= = SSS | ——= 
June 1) + 3°18" | + 3°61] + 3°33!\+ 3-48") + 4:29’ + 3°41] + 3:42”/+ 3:03”) + 312" 
2 18 6l 33 AS 30 42 * 43 05 14 
3 17 61 Sh 49 31 A3 A4 07 17 
4 17 61 33 AQ | 32 A4 46 09 19 
5 17 61 33 A9 33 45 AT 10 22 
6 16 62 33 49 34 AT A8 12 24 
7 16 | 62 34 50 35 48 A9 14 27 
8 15 62 34 50 36 49 51 16 29 
9 15 62 34 51 | 37 50 52 18 32 
10 14 62 34 51 37 51 58 19 34 
1] 14 61 33 51 38 52 54 21 36 
12 13 61 33 51 38 52 55 22 38 
13 12 61 33 51 39 53 56 24 40 
14 ll 61 33 51 39 54 57 25 43 
15 11 60 32 51 40 55 53 26 Ad 
16 10 60 32 52 40 56 59 28 AT 
iW 09 60 32 52 Al 57 60 29 49 
18 09 59 31 52 Al 57 61 31 51 
19 08 59 31 52 AQ 58 62 32 53 
20 OT 59 30 52 AQ 58 63 33 55 
21 06 58 30 51 43 59 63 34 57 
22 06 58 29 51 43 59 64 35 58 
23 05 57 29 51 | 43 59 64 36 60 
24 04 57 28 51 43 60 65 37 62 
25 03 56 28 50 43 60 65 3T 64 
26 02 56 27 50 44 _ 61 66 38 66 
27 ol 55 QT AQ | AA 61 66 39 68 
28 00 55 26 49 44 62 67 40 69 
29; 2:99 54 25 49 45 62 68 Al 71 
30 98 53 24 49 45 62 68 42 12 
@ Aquile | g Aquila 2aCapricor| « Cygni lex Aquarii |Fomalhaut | a Pegasi jaAndrom. 
h. m. s. |h. m. s. |h. m. os. hem. s. |h. m..s. fh. m. s. jh. m,. s. [h. m.s. 
1824, 19 42 11-88)19 46 40°23.20 8 17:02)20 39 26°21 \21 56 44°67/22 47 54°34/22 56 0°17|23 59 18°67 
—_—_== —_ a | —|\"—-—__-_—- 
June 1) + 3:14”|+ 3°15”) + 3:39” |+ 2:50"\+ 2:61”) 4 2°59” |+ 2:167|/+ 1-80” 
16 17 42 53 64 62 19 83 
19 20 45 56 67 66 22 86 
21 22 48 59 val 69 25 89 
24 25 51 62 74 13 28 93 
26 27 53 66 17 76 32 96 
29 30 56 69 80 80 35 99 
31 32 59 72 84 83 38 2°03 
34 35 62 75 87 87 Al 06 
36 37 64 78 90 90 A4 09 
38 39 67 81 93 94 48 13 
40 Al 69 84 96 97 51 16 
43 AA 72 87 99 3:01 54 20 
A5 46 14 90 3°02 04 57 23 
Al A8 17 93 04 OT 61 QT 
AQ 50 19 95 OT ll 64 30 
52 53 82 98 10 14 67 34 
54 55 84 3:01 13 18 71 3T 
56 57 87 04 16 21 TA Al 
58 59 89 06 19 24 TT A4 
60 61 91 09 22 28 80 48 
61 62 93 il 24 31 83 51 
63 64 96 4 QT 35 86 54 
65 66 98 16 30 38 89 58 
67 68 4:00 18 38 4l 92 61 
69 10 02 2t 36 45 95 64 
70 ve 04 23 38 48 98 65 
72 13 OT 26 41 52 3°01 71 
14 15 09 28 44 55 04 74 
75 77 ll 30 47 58 07 vit 


1824.] M. Arfwedson on Uranium. 253 


Articxe IV. 


A Contribution to a more accurate Knowledge of Uranium.* 
By J. A. Arfwedson, 


Uranium in the state of an oxide is occasionally found native 
pretty pure, as, for example, in uran ochre and uran mica; but 
the scarcity of these minerals has prevented them from being 
employed for preparing oxide of uranium in any considerable 
quantity. Chemists have, therefore, in their researches on this 
metal, been. obliged to employ the more abundant mineral called 
pechblende, in which oxide of uranium is likewise found, mixed 
pith, several other bodies from which it is with difficulty sepa- 
rated. 

Klaproth found pechblende, from Joachimsthal, in Bohemia, 
to contain, together with protoxide of uranium, silica, oxide of 
iron, and sulphuret of lead. He extracted the protoxide of ura- 
nium in the following way : The pulverised mineral was dissolved 
in nitric acid, the silica and sulphur remaining undissolved. 
From the filtered solution was separated by crystallization in the 
first place, the lead, under the form of nitrate of lead. The liquid 
being further evaporated, the nitrate of uranium crystallized, 
which was finally decomposed by caustic potash. The oxide of 
iron remained in the mother ley. 

Bucholz prepared his oxide of uranium in this manner.—The 
pulverised pechblende was boiled with nitric acid, as long as 
any thing was dissolved. The solution was evaporated at a high 
temperature till fumes of nitrous acid were extricated, and this 
was continued for a considerable time, taking care to stir the 
’ matter continually. The salt of uranium was then taken up by 
water, while the oxide of iron remained behind undissolved. 
Bucholz found, however, that the solution contained likewise 
copper and lime; which were separated in this manner. The 
liquid was decomposed by caustic ammonia added in excess, and 
digested for some time along with the precipitate. By this pro- 
cess the precipitate was freed from copper. It was washed and 
heated to redness to drive off the whole of the ammonia, It was 
again dissolved in nitric acid, and precipitated by caustic potash, 
added as little as possible in excess. The oxide of uranium thus 
obtained retained its yellow colour after being heated to redness, 
and was considered as free both from lime and potash. 

From the knowledge of the subject which we at present pos- 
sess, it is easy to see that neither Klaproth nor Bucholz could 
have obtained a perfectly pure oxide of uranium, on account of 
the great variety of substances accidentally present in pech- 
blende, the names of which I shall state below. 


* Translated from the Kongl. Vetenskaps Academiens Handlingar, for 1822, p, 404, 


254 M. Arfwedson on Uranium. [ApRiL, 


Method of preparing pure Oxide of Uranium. 


I expected at first to have been able to obtain pure oxide of 
uranium without any tedious processes, by means of one of its 
properties which has not been known for any considerable time ; 
namely, that it dissolves with facility in carbonate of ammonia, 
and is again precipitated from the solution by boiling; for 
should some copper accompany it in the solution, the oxide of 
uranium which first is precipitated ought to be quite free from all 
admixture of that metal. 

A portion of pechblende from Johann Georgenstadt inSaxony, 
which was apparently very pure, was reduced to a fine powder, 
and digested with nitric acid till it was completely decomposed. 
After this a little muriatic acid was added, which dissolved a 
considerable portion of the straw-yellow matter, insoluble in 
nitric acid. The filtered solution was supersaturated with car- 
bonate of ammonia in great excess. A portion of the precipitate 
was again dissolved by the carbonate, but the greatest part 
remained undissolved; and this proportion continued unaltered 
though the whole was heated. The ammoniacal solution was 
separated from the precipitate, and was examined by means of 
processes which I consider it unnecessary to particularize in this 
place, and to my astonishment 1 found it to contain the following 
different substances ; namely, oxide of uranium, oxide of copper, 
a considerable proporiion of oxide of cobalt, a little oxide of 
zinc ; and the precipitate, besides all these bodies, contained 
much arsenic mixed with oxides of iron and lead. If to these 
we add the silica and sulphur not dissolved by the acids, we 
shall find that the pechblende contains no fewer than nine differ- 
ent substances. To free oxide of uranium from so many other 
bodies occasioned a great number of fruitless trials. But I at 
last succeeded in discovering the following method, by means 
of which, so far as I can see, the protoxide of uranium may be 
obtained ina state of complete purity. 

Finely pulverized pechblende is dissolved by means of a gentle 
heat in a mixture of nitric and muriatic acids. When the 
decomposition of the mineral is completed, and most of the acid 
expelled, a little muriatic acid is to be added, after which the 
liquid is to be diluted with a good deal of water. The sulphur, 
silica, and a portion of the gangue, remain finally undissolved. 
A current of sulphuretted hydrogen gas must now be passed 
through the liquid as long as any precipitate continues to fall. 
The precipitate is at first dark-brown, consisting of sulphurets of 
copper, arsenic, and lead ; but at last it becomes yellow, and 
consists of sulphuret of arsenic. The liquid is now free from 
copper, lead, and arsenic, but it contains iron, cobalt, anda 
little zinc. 

Let it be filtered and digested with a little additional nitric 
acid to peroxidize the iron. By this process the light green 


1824,} _M. Arfwedson on Uranium. 255 


colour of the liquid changes to a yellow. It must now be decom- 
posed by means of carbonate of ammonia added in excess, which 
will take up the oxide of uranium mixed with oxides of cobalt 
and zinc; but leaves a great quantity of oxide of iron undis- 
solved. Should the solution even contain a portion of earth, 
which did not happen in my experiments, almost the whole of it 
would be separated mixed with the oxideof iron. The filtered 
solution is afterwards made to boil, and the boiling is continued 
as long as the carbonate of ammonia is disengaged. A portion 
of the oxide of cobalt remains in the solution, which acquires a 
faint reddish colour; but another portion of it is precipitated 
along with the oxide of uranium; which contains likewise the 
zinc. The precipitate is collected on the filter, washed, and 
dried. It is then to be heated to redness ; by which it loses its 
yellow colour, and becomes dark-green. In this state it must 
be macerated for some time in dilute muriatic acid, which dis- 
solves the oxides of cobalt and zinc, together with a small por- 
tion of peroxide of uranium. This portion was probably united 
as an acid with the two bases. Pure protoxide of uranium 
remains undissolved. If the muriatic solution be precipitated 
with caustic ammonia in excess, we obtain oxide of uranium 
combined with oxides of cobalt and zinc. From 382 parts of 
pechblende treated in this way, I obtained about 25 parts of 
protoxide of uranium. This amounts nearly to 65 per cent. 
which is 15 parts less than the quantity stated by Klaproth. 


Metallic Uranium and Protoxide of Uranium. 


_ The experiments hitherto made to obtain uranium in the 
metallic form have been all conducted in charcoal crucibles with 
or without additions. It is consequently probable, even if the 
oxide of uranium operated upon had been quite pure, that the 
metal obtained contained charcoal, or some other substance 
derived from the fluxes employed in the reduction. In which 
ease the properties of the product might differ materially from 
those of the pure metal. Fortunately chemists have found out 
a method of avoiding these inconveniences in the reduction of 
metals; for it is now known that several metallic oxides may be 
deprived of their oxygen by means of hydrogen gas. I deter- 
mined, therefore, to try whether oxide of uranium could not be 
brought to the metallic state by this method. If I succeeded I 
obtained naturally the proportion of oxygen in the oxide deter- 
mined with the requisite exactness. 

The apparatus employed in this process was a piece of acom- 
mon barometer tube, blown into a small globe about the middle 
part. This tube was in the first place weighed, and then a 

ortion of finely pulverized protoxide of uranium which had been 
eated to redness was introduced into the globular part of the 
tube, Before determining the weight of this powder, the glass 


256 M. Arfwedson on Uranium. [Aprin, 


was heated by a spirit lamp, in order to drive off any moisture 
that might have been adhering to the powder, and this moisture 
was sucked out of the tube by the mouth. The tube was then 
placed in continuity with an apparatus from which hydrogen gas 
was extricated from a mixture of zine and dilute sulphuric acid. 
This gas was made to pass in the first place through a tube filled 
with fused muriate of lime in order to dry it. It then entered 
into the tube containing the protoxide of uranium ; and as soon 
as it had expelled the atmospheric air, heat was applied to the 
protoxide by means of an Argand’s spirit lamp. The reduction 
took place immediately, and with such violence that the matter 
became red-hot. Water was generated, and at the end of the 
process, which only lasted a few minutes, the green protoxide 
was changed into a powder of a liver-brown colour. 1187 parts 
of protoxide of uranium had lost by this process 0:042 part, 
which amounts to 3°53 per cent. In another experiment 1:468 
lost 0-052, which amounts to 3°54 percent. The experiment 
was repeated once more in a porcelain tube which was heated to 
whiteness ; but the product was the same brown powder. 

This substance remains unaltered at the ordinary temperature 
of the atmosphere ; but when heated to the commencement of 
redness, it takes fire, swells, and is converted into green oxide. 
It is insoluble in sulphuric and muriatic acids, whether concen- 
trated or diluted ; but it dissolves with facility in nitric acid with 
the evolution of nitrous gas, and the solution has a lemon-yellow 
colour. It is exceedingly probable that the protoxide of ura- 
nium is by this treatment reduced to the metallic state ; but it is 
certainly possible that I only reduced it to a lower state of oxi- 
dizement. . 

Meanwhile I undertook some experiments in order to deter- 
mine the composition of the yellow oxide of uranium, by means 
of which I expected to be able to throw some hght on the ques- 
tion, whether the substance obtained in the preceding experi- 
ments should be considered as a metal or not. If I could 
prepare a neutral salt with peroxide of uranium and sulphuric or 
muriatic acid, I should have an easy way of determming the 
quantity of oxygen in the oxide by the analysis of the salt; but 
neither of these salts could be obtained in the state of crystals ; 
for on evaporating the solutions, I obtained at last a thick syrup, 
which, when further evaporated, became - leper from 
the formation of protoxide of uranium. On the other hand, 
when I added to the permuriate of uranium a portion of muriate 
of potash, a triple salt separated on evaporating the liquid in 
small lemon-yellow crystals. Since hydrogen gas reduces the 
protoxide of uranium with such facikty, I thought it likely that 
this triple salt might also be decomposed by means of it, and 
that its analysis could be best performed in the way that Berze- 
lius proceeded with the analysis of potash-muriate of platinum ; 


1824,] .M. Arfwedson on Uranium. ‘257 


for potash-muriate of uranium may be freed from water without 
the Meant difficulty, as the salt can be exposed to a moderate red 
heat without undergoing any decomposition. it 

_ The experiment was conducted in the first place in an appa- 
ratus similar to that above described. As soon as the hydrogen 
gas began to pass, and the salt became hot, it fused and swelled 
up, muriatic acid gas was given out, and the mass became dark- 
coloured and opaque. Though the process was continued for 
nearly two hours, and the heat from the Argand’s spirit lamp 
was raised to the highest degree of intensity, vapours of muriatic 
acid still continued to pass ; a proof that the salt was not com- 
pletely decomposed. The whole being allowed to cool, the 
matter was extracted by water, which dissolved muriate of 
potash, together with a good portion of uranium salt, of a light- 
green colour. The insoluble residue was a black. crystallized 
powder having the metallic lustre, which was washed, and dried 
upon blotting paper. 

Supposing that the heat in this experiment might have been 
too weak, and that the salt, if exposed to a higher temperature, 
might have been more completely decomposed, it was again 
Tepeated with this difference, that the salt was put into an appa- 
ratus, which could be more strongly heated, and which was 
introduced half way into a small furnace heated with charcoal. 
The heat applied was so strong that the glass was almost melted ; 
yet the salt was not completely decomposed’; for after washing 
the altered salt with water, there remained the same crystallized 
matter as in the preceding experiment; but of a still more 
decided metallic appearance ; for the salt had been employed in 
greater quantity, and on that account the crystals were larger 
and more distinct. The form of these crystals as seen under the 
microscope was an octahedron very nearly regular, whose faces 
had a yery strong metallic lustre. Some of them were slightly 
transparent at the edges, and of a reddish-brown colour; and 
this colour remained even after the crystals were reduced to 
powder. These crystals were not altered by exposure to the 
atmosphere ; hut when heated, they were reduced to powder, 
increased in bulk, and were changed into green protoxide of 
uranium, which, when treated with acids, exhibited the very 
same characters as the products of the reduced protoxide. 

_ Itis scarcely possible to think, that in this experiment an 
oxidized body could have been obtained ; especially if the double 
salt employed be viewed according to the new theory of the 
nature of mutiatic acid, according to which that acid contains 
no oxygen whatever. All the circumstances taken together 
lead to the conclusion, that the crystallized body obtained was 
metallic uranium. 0°636 part of it were heated in « platinum 
vessel, and converted into green oxide. The increase of weight 
was 0°0235, or 100 parts of the metal had combined with 3:695 
parts of oxygen, For the sake of security the oxide was dissolved 
New Series, vou, vit. s arate 


258 M. Arfwedson on Uranium. [Aprit, 


in nitric acid, the solution evaporated to dryness, and exposed 
to ared heat ; but by this process no alteration whatever of the 
weight was produced. ) 

The experiment was repeated with 1:006 gramme of metal, 
which increased in weight 00375 gramme, corresponding to 
3°73 oxygen to the 100 of metal. . 

These two experiments agreeing very well with each other 
show plainly that the brown substance obtained when protoxide 
of uranium was reduced by means of hydrogen gas, must like- 
wise be in the metallic state. A hundred parts of the protoxide 
lost 3°53 or 3°54 of their weight, leaving a remainder amounting 
to 96:47 or 96:46. But 96:46 : 3°54 :: 100: 3°67, which loss 
quite corresponds with the augmentation of weight of the metal 
when heated to redness. It was formerly remarked, that the 
metal when obtained by reducing the protoxide by means of 
hydrogen gas has a liver-brown colour; while on the other hand 
the powder of the crystallized product is reddish-brown; but 
this may be owing to no other cause than a difference in the 
fineness of the two powders. 

If the result of the reduction of the protoxide be compared 
with that which is obtained by the combustion of the metal, 100 
parts of protoxide of uranium are composed at a medium of: 


Ufc sv pet 12 Oo peGae pare PUR Te mete ie Leg TY: 96°443 
CRY RERs chor h ak he ae veteiionian aan 3:°557 
100-000 


and 100 parts of uranium combine with 3°688 parts of oxygen. 
The protoxide of uranium obtained from percarbonate is a 
powder of a dirty-green colour. If the uranium salt be a second 
time thrown down by caustic ammonia, and the precipitate be 
heated to redness, the protoxide is obtained in the form ofa 
black metallic mass, the particles of which cohere together. 
This mass is exceedingly hard, and is not without difficulty 
reduced to powder. The powder has the usual green colour of 
protoxide of uranium. Protoxide of uranium after having been 
heated to redness, dissolves very sparingly in dilute muriatic or 
sulphuric acid. The concentrated acids dissolve it better, and 
when it is boiled in concentrated sulphuric acid, it dissolves 
completely, a light-green coloured saline mass is obtained, which 
dissolves in water with a deep bottle-green colour. If sucha 
solution be precipitated by caustic ammonia, the protoxide is 
separated in the state of a hydrate, in brown flocks inclining to 
purple. If these flocks be washed and dried at the temperature 
of 212°, and then heated in a glass tube, they give out a consi- 
derable portion of water, and become green. Tn general a por- 
tion of the hydrate is likewise converted into peroxide, and it 
becomes yellow before the end of the drying; and if it was 
precipitated by ammonia in great excess, or if it was washed 


1824.7 M. Arfwedson on Uranium. — 259 
with hot water, in either case we may generally expect to 
find the whole after being dried in the state of peroxide 
containing ammonia. Carbonate of ammonia throws down a 
light-green precipitate of protocarbonate of uranium, which is 
again dissolved if the precipitant be added in excess. If the 
precipitate be heated in ammonia, we obtain protoxide of ura- 
nium free from carbonic acid. The hydrated protoxide dissolves 
very easily in acids; and the precipitate by means of caustic 
ammonia is easily dissolved again if a little excess of acid be 
added to the liquid; but if the precipitated hydrate be digested 
for an hour in water, the chemically combined water is disen- 
gaged, the matter concretes into a heavy powder of small bulk, 
and is afterwards acted upon with great difficulty by acids. 


Yellow Oxide of Uranium. 

Peroxide of uranium, as is well known, has the property of 
acting sometimes the part of an acid, and at others that of an 
alkali; and it has sueh a tendency to enter into combination 
with other oxidized bodies, that I doubt the possibility of obtain- 
ing it in an insulated state. For example, if we precipitate a 
solution of this oxide in muriatic or nitric acid by means of 
caustic ammonia, the precipitate is a chemical combination of 
peroxide of uranium with water and ammonia, which last body 
cannot be removed by washing the powder. _The very same 
result is obtained, if we precipitate the peroxide by means of 
caustic potash. The hydrated uraniate of ammonia may be 
heated without undergoing decomposition to 212°, or a little 
higher. When raised to a still higher temperature, it gives out 
water, azotic gas, and ammonia, and protoxide of uranium 
remains behind. If we attempt on the other hand to heat per- 
nitrate of uranium in order to disengage the acid, the decomposi- 
tion of the salt does not cease till the whole mass is converted 
into protoxide; and this result takes place in what way soever 
we regulate the temperature. 

Considering the small quantity of oxygen in the protoxide 
of uranium, it was of the utmost importance in determining the 
quantity of oxygen in the peroxide to employ a method which 
was not liable to any uncertainty. It occurred to me that [ 
should obtain such a method if I combined peroxide of uranium 
with a basis, the proportion of whose oxygen was accurately 
known; and then, by means of hydrogen gas, deprived both 
substances of their oxygen, Knowing the proportions of per- 
oxide of uranium and basis, and the proportion of oxygen on the 
base, we should haye the oxygen in the peroxide. To enable 
me to employ such a method, some preliminary experiments 
were undertaken, by which I found that when to a solution of 
peroxide of uranium in muriatic acid any, earthy or metallic 
muriate is added, and then caustic ammonia is added to the 
mixture, in all such cases the peroxide of uranium is precipitated 

$2 


260 M. Arfwedson on Uranium. [APRiL, 


in combination with the earth or metallic oxide in the form of a 
uraniate, even when the base consists of a substance which, 
when in an insulated state, is not precipitated by ammonia ; for 
example, when it is lime or barytes; and in this way a whole 
series of uraniates may be obtained, which, however, do not 
resemble other salts in their composition, as will be seen more 

articularly hereafter. When peroxide of uranium is united toa 
bias capable of withstanding the fire, it can resist a high tempera- 
ture without losing any of its oxygen. When, on the contrary, 
1 examined a uraniate having an easily reducible basis, the com- 
position of which was known before, I in that case first reduced 
the salt by means of hydrogen gas, which gave me the quantity 
of oxygen contained in both oxides ; then determining the quan- 
tity of oxygen in the basis I had that in the peroxide of uranium, 
I employed for this purpose uraniate of lead as most suitable to 
this kind of investigation. 


Analysis of Uraniate of Lead. 

The salt was prepared in this manner. Solutions of pernitrate 
of uranium and nitrate of lead were mixed together, and precipi- 
tated by caustic ammonia. The precipitate thus obtained was 
washed, and exposed to a red heat. It probably contained an 
excess of oxide of lead, in the form of subnitrate, as the nitrate 
of lead had been added in considerable excess ; but this was of 
no consequence. The precipitated compound after being heated 
to redness and pulverized, had a cinnamon-brown colour, and it 
gave a full lemon-yellow solution in muriatic acid ; showing that 
the peroxide of uranium had lost none of its oxygen. 

1-969 gramme of uraniate of lead was reduced by means of 
hydrogen gas in the same way as the analysis of the protoxide of 
uranium was performed. As soon as it began to be red hot, it 
gave out much water, and when this ceased the process was 
stopped. The product consisted of a dark-brown powder, 
which weighed 0-127 less than the uraniate of lead. But this 
difference in weight could not be determined with accuracy, 
because the apparatus while weighing was constantly increasing 
in weight. The reduced mass became at the same time hot, and 
when thrown upon paper, it took fire, and became quite ignited, 
leaving uraniate of lead as a residue. 

This singular phenomenon, owing probably to the rapidity 
with which the alloy of uranium and lead absorbed oxygen, was 
so much the more unlooked for, as these metals, when in a 
separate state, do not undergo any change in the common tem- 
perature of the atmosphere. There might, in this case, have 
been produced an electro-chemical process between them, which 
occasioned their combustion. Meanwhile no accurate conclu- 
sion could be drawn respecting the oxygen which the two metals 
contained. The experiment, therefore, was repeated, with this 
alteration, that the water was collected in a receiver, filled with 


1824,] M. Arfwedson on Uranium. 261 


fused muriate of lime, previously exactly balanced to determine 
its weight. 

From 2°3 grammes of uraniate of lead, previously heated to 

redness, were obtained in this way 0°164 gr. of water, equivalent 
to 0°1459 oxygen.* 
' 0°628 gramme of uraniate of lead, prepared at the same time, 
were dissolved in nitric acid. The solution was mixed with 
sulphuric acid in sufficient quantity to saturate the oxide of 
lead, and then evaporated almost to dryness. I found it neces- 
sary to dissolve the uraniate of lead in the first place in nitric 
acid ; for if it be decomposed directly by sulphuric acid, it is not 
possible to obtain the sulphate of lead white, and quite free from 
oxide of uranium. The mass was finally digested in alcohol, 
which dissolved the sulphate of uranium, and left the sulphate 
of lead. This last salt was collected on a filter, and washed 
with alcohol. After being heated to redness, it weighed 0°485 
gr. which corresponds with 0°357 protoxide of lead. The 
remainder of the 0°628 amounting to 0°271 was of course per- 
oxide of uranium. Thus it appears that 2°5 uraniate of lead 
consist of 1:307 protoxide of lead, and 0:993 of peroxide of 
uranium. The oxygen in the former of these constituents is 
0-0957 ; but the oxides of lead and uranium had together lost 
0-1459 of oxygen; and consequently 0°0522 of oxygen must 
have belonged to the peroxide of uranium. It follows ultimately 
that 100 parts of peroxide of uranium contain 5°252 of oxygen. 

The experiment was repeated with a uraniate of lead of 
another preparation ; because all the first stock was exhausted. 

1-26 gr. reduced by means of hydrogen gas, gave 0-0785 
water, corresponding with 0:0698 oxygen ; 1:258 gr. of the salt 
was decomposed by sulphuric acid, and was found to be a com- 
pound of 0°173 protoxide of lead, and 1-085 peroxide of uranium. 
1:26 gr. of the uraniate of course consist of 0°1733 protoxide of 
lead and 1-0867 peroxide of uranium; which together contain 
0:0698 oxygen; but 0°1733 protoxide of Jead contain 0-0124 
oxygen. Thus it appears that the oxygen in 1-0867 peroxide of 
uranium is 0°0574; and 100 parts of peroxide of uranium con- 
tain 5°282 oxygen. The preceding experiment gave 5°252; the 
mean of both is 5°267. From this it follows, that 100 parts of 
uranium, in order to become peroxide, must combine with 5°559 
oxygen. f 

ut that the whole might not depend upon a single set of 
experiments, I determined likewise to analyze 


Uraniate of Barytes. 
-_ It was prepared in this manner. A mixture of the solutions 
of “sop ciom of uranium and muriate of barytes, both previously 
boiled, was precipitated by caustic ammonia. The precipitate 


* The oxygen in the water was reckoned 88°94 per cent, according to the experi- 
ments of Berealiue and Dulong. 3 he . 


262 M, Arfwedson on Uranium, [APRIL 


was collected on a filter, and hastily washed with fresh boiled 
water, to prevent any mixture of carbonate of barytes. The 
uraniate of barytes, after being dried and heated to redness, had 
a fine yellow colour, which became lemon-yellow when the salt 
was reduced to powder. 

1:343 gramme of uraniate of barytes previously heated to 
redness, being dissolved in nitric acid, and decomposed by 
means of sulphuric acid, gave 0-295 gr. of sulphate of barytes, 
or 0°194 barytes. The solution which contained the peroxide of 
uranium was evaporated to dryness, and the dry salt heated to 
decomposition in a platinum crucible; for this a strong and long 
continued heat was required to drive off the last portion of the 
sulphuric acid. The residue was protoxide of uranium, which 
weighed 1-121. When dissolved in nitric acid, no turbidness 
appeared indicating the presence of any sulphate of barytes: 
1-343 uraniate of barytes had thus given 0°194 barytes, and 
1-121 protoxide of uranium, making together 1-315. The loss, 
amounting to 0°028, must of course be the difference between 
the quantity of oxygen in the protoxide and peroxide of ura- 
nium; but 1-121 : 0-028 :: 100: 2:5; consequently 100 protoxide 
of uranium, in order to become peroxide, must combine with 2°5 
oxygen. 

1-456 gr. uraniate of barytes of another preparation gave 
0-364 sulphate of barytes (equivalent to0°239 barytes), and 1-186 
protoxide of uranium. The oxygen driven off in this experi- 
ment is 0:031 with 1-186 protoxide; this to 100 parts is equiva- 
lent to 2°61. The mean of 2°50 and 2°61 is 2°55; and 100. 
parts of peroxide of uranium ought, according to these experi- 
ments, to contain 5:96 oxygen, and 100 of the metal combine 
with 6:34 oxygen, in order to become peroxide. 

Although the uraniate of barytes was formed in both cases 
in the same way, so that the liquid from which it was prepared 
contained always a quantity of uncombined ammonia; and 
although a quantity of muriate of barytes in both cases remained 
unprecipitated in the liquid, yet we perceive that the uraniate 
of barytes first prepared contained a considerably smaller pro- 
portion of basis than the second. It is possible that the peroxide 
of uranium, being a weak acid, may undergo some modification 
in its capacity of saturation, according as the muriate of barytes 
is present in a greater or smaller proportion relative to the 
muriate of uranium. 


Analysis of the Sulphate of Uranium and Potash. 


This double salt being less soluble in water than the muriate 
of uranium and potash, crystallizes more readily, and may, by 
means of crystallization, be completely freed from any excess of 
the salt of potash, I consider this salt on that account as more 
suitable for analysis than the muriate. : 
~ Potash-sulphate of uranium is obtained by. evaporating a 


1824.] M, Arfwedson on Uranium. 263 


solution of sulphate of uranium to which some sulphate of potash 
has been added. It forms a confused crystallized mass of an 
exceedingly beautiful lemon-yellow colour. When heated, it 
gives out in the first place water, and when the heat is aug- 
mented melts, and flows into a liquid. The fused salt is green= 
ish-yellow, and therefore has probably undergone a partial 
decomposition; although it gives a full }emon-yellow solution in 
water; but if the salt be heated only to a commencement of 
fusion, it retains its yellow colour completely. 

A solution containing 2°172 grs. of crystallized and anhydrous 
potash-sulphate of uranium was precipitated by muriate of 
barytes. ‘The sulphate of barytes being separated, washed, and 
heated to redness, weighed 1-814 gr. corresponding to 0-623 
sulphuric acid. —- 

The filtered liquid was saturated with caustic ammonia, which 
precipitated uraniate of barytes. It was collected on the filter 
and weighed. The residual liquid was mixed with a sufficient 
quantity of sulphuric acid both to separate any barytes that 
might remain, and in order finally to obtain a sulphate of potash: 
quite free from muriatic acid. After this the whole liquid was 
evaporated to dryness ; the dry salt was heated to redness in a 
weighed platinum crucible, by which the ammoniacal salts were 
volatilized, and sulphate of potash remained, which was rendered 
neutral by the fumes of carbonate of ammonia. It weighed 
0°533 gr. equivalent to 0°288 gr. of potash. The salt dissolved 
in water without residue, and the solution was neither rendered 
turbid by ammonia, nor by nitrate of silver; showing that it 
contained neither oxide of uranium nor muriaticacid. The sule 
phurie acid and the potash were thus determined; what is 
wanting to make up the original quantity of salt employed must 
be peroxide of uranium. It follows that the constituents of the 
double salt must be: 


Sulphuric acid ..ceeecceccecesesees 0623 
Potash *®eerereeer eo eeeeeeeeoeeveeereeee 0:288 
Peroxide of uranium. ......eeseee05 1261 
Piet 

Or in 100 parts : 
Sulphuric acid ...656.. ice ceceeees 98°68 


Potash ... see eevee eee eect eeseeeenes 13°26 
Peroxide of uranium, .....44....... 58°06 
100-00 


13:26 potash are saturated by 11-26 sulphuric acid. There 
remain 17:42 acid which belong to the 58-06 of peroxide of ura- 
nium; but 17-42 sulphuric acid saturate a quantity of basis 
containing 3-477 oxygen; 100 parts of peroxide of uranium 


264 M. Arfwedson on Uranium, [APRIL, 
consequently contain 5°99 oxygen ; or 100 parts of the metal, in 
order to be peroxidized, combine with 6°37 oxygen. 

The oxygen of the potash is to that of the peroxide of uranium 
as 2 to 3; for the oxygen in 13*26-potash is 2°248, and in 58°06 
of peroxide of uranium 3:477. Now 2-248 : 3:477 :: 100: 
154:7. . 
If we now collect the results of all these experiments to deter- 
mine the quantity of the oxygen in the peroxide, we shall find 
them as follows : 

100 parts of uranium take up, according to the analysis of 


Oxygen. 
Uraniate, of.lead ... esieitsé s basieewes on -D°DO9 
Uraniate of barytes........ sition» dg 


Potash-sulphate of uranium. ........ 6370 


The number 5:559 has almost the same ratio to the oxygen in 
the protoxide that 3 has to 2; for in the protoxide 100 parts of 
uranium are combined with 3-688 parts of oxygen, which, mul- 
tiplied by 11, = 5-532; but the last two numbers lie between 
1+ and twice 3°688. It is difficult to determine which of these 
numbers come nearest the truth. The last two, although 
obtained different ways, accord in a remarkable degree; and 
have in consequence some claim to be considered as accurate. 
But on the other side it is clear that the experiments made with 
uraniate of lead ought to come out with greater precision ; 
because the analytical method followed with respect to it puts it 
in our power to attain a higher degree of accuracy than is likely 
in the two following experiments. I must in the mean time 
acknowledge that these experiments do not furnish us with the 
knowledge of the composition of the oxides of uranium with that 
degree of accuracy which chemists have a right to require. At 
the same time it may be admitted as most likely that the oxygen 
in the peroxide of uranium is 1+ times as great as in the protox- 
ide; unless we were to admit that the second composition, such 
as it was found, can be completely depended on ; and this there 
is not much reason to do, as both the oxidizement of the metal 
and the reduction of the protoxide, give the same composition of 
the oxide. . ; 

According to M. Schonberg’s experiments on the composition 
of the oxides of uranium,* the oxygen in the protoxide is to that 
in the peroxide as 2 to3 ; for he found the protoxide to contain 
6, and the peroxide 8-73 per cent. The oxygen in the protoxide 
was determined by analysing the protomuriate of uranium; and 
the composition of the peroxide was determined by the loss of 
weight which it sustained when heated to redness, by which it 
was converted into protoxide. But it appears from my experi- 
ments, that the protomuriate can never be obtained neutral and 


* De conjunctione chemica ejusque rationibus, Upsalie, 1813. 


1824.] M. Arfwedson on Uranium. 265 
free from peroxide without undergoing decomposition. It is 
probable, therefore, that M. Schonberg’s experiments were made 
upon a salt containing an excess of acid, in which case it is 
obvious that he must have overrated the quantity of oxygen con- 
tained in the basis. The peroxide employed in his second deter- 
mination was obtained by decomposing pernitrate of uranium by 
means of heat; but this mode of experimenting cannot be deci- 
sive, as from what has been stated it must be evidently impossible 
to drive off the nitric acid completely from this salt without con 
yerting the basis partly into a protoxide. 

100 parts of uranium to form the protoxide combine with 
- 3°688 oxygen. If this represents two atoms of oxygen, as is 
probable, then an atom of uranium will weigh 5422°99. Peroxide 
of uranium precipitated by a caustic alkali is insoluble in an 
excess of the precipitating substance, and always contains a 
little alkali, which cannot be washed out, but is found, together 
with an earthy or metallic salt in the water, as the peroxide of 
uranium is precipitated in combination with an earth or metallic 
oxide. In alkaline carbonates, and in particular with carbonate 
of ammonia, peroxide of uranium is easily soluble. The solution 
has,a strong lemon colour, and even an inconsiderable portion of 
peroxide of uranium is capable of giving that colour to water. 
By boiling, the peroxide of uranium precipitates in the state ofa 
pale-yellow powder, which contains carbonic acid, and even 
some ammonia. We must not, however, reckon upon obtaining 
the whole oxide ; because however pure it may be, there always 
remains a little in the water; and ate the carbonated oxide is, 
put upon the filter and washed, the water employed in the edul- 
coration, especially towards the end, contains a good portion of 
oxide in solution, which again falls when the liquid comes to be 
mixed with the saline solution. The peroxide precipitated by 
caustic ammonia acts in precisely the same way. Peroxide of 
uranium, therefore, may be considered as slightly soluble in 
water. This solubility is partly, but not entirely prevented by. 
washing it with water containing sal ammoniac dissolved in it. 
On the other hand, if peroxide of uranium be united to an earth, 
or a metallic oxide, it 1s not in the least soluble in water. 

According to what has been already stated, peroxide of ura-~ 
nium unites with the other earths and metallic oxides into a kind 
of uraniates, in all cases, when the mixed solutions of both are 
precipitated by caustic ammonia. These compounds may be 
reduced by means of hydrogen gas to the state of alloys of 
uranium, and the basis of the earth or oxide employed, even 
when the earthy basis is barytes. These alloys again absorb 
oxygen at the common temperature of the nerteoephansy and the 
oxidizement is accompanied by combustion. ‘They constitute, 
therefore, a peculiar ind of pyrophori not inferior to those 
already known. The alloy of uranium and lead has been already 
mentioned. An analogous body is obtained when uraniate of 


266 M. Arfwedson on Uranium. [ApriL, 
barytes is reduced ; and the alloy of uranium and iron burns still 
better than either of the others. fades 

Uranium appears to have a very weak affinity for sulphur. 
The sulphuret may be obtained by the moist way, as is already 
known, if a solution of uranium be precipitated by an alkaline 
hydrosulphuret ; but I have not been able to succeed in forming 
sulphuret of uranium by the dry way. When dry sulphuretted 
hydrogen gas is passed over red-hot protoxide of uranium, the 
oxide is reduced immediately, water and sulphur exhale, and a 
body remains in all respects similar to the metallic uranium, 
and which contains only 1°61 per cent. of sulphur. 


Salts of Uranium. 


_ The protosalts of uranium in a state of purity are not easily 
prepared. If we dissolve protoxide of uranium in concentrated 
sulphuric or muriatic acid (which, in the second case, goes on 
very slowly), the solution at first is dark bottle-green; but it 
becomes gradually lighter, and at last assumes a greenish-yellow 
colour from the formation of peroxide. The sulphuric acid solus 
tion when evaporated deposits a hght green confusedly erystal- 
lized mass which contains a mixture of protoxide and peroxide 
of uranium. The muriatic acid solution may be evaporated to 
dryness without the deposition of any crystals. 

Persalts.—The persulphate of uranium is formed, when nitrie 
acid is added to a solution of protosulphate of uranium: This 
addition, the green colour speedily passes to yellow, even with 
out the assistance of heat. 

The salt does not crystallize even when evaporated to the cons 
sistence of a syrup. If we continue the application of the heat 
after the salt has become dry, the oxide loses a portion of its 
oxygen, and the mass acquires a greenish-yellow colour. 

Pernitrate of uranium is formed when the protoxide is dis= 
solved in nitric acid. The solution goes on with rapidity, espe- 
cially if assisted by heat. Nitrous gas is disengaged, and we 
obtain a yellow liquid, which, when evaporated, shoots into lone 
prismatic crystals of a fine yellow colour. The salt dissolves 
readily in water, and is decomposed in a comparatively low tem- 
perature; oxygen gas is also disengaged, and pernitrate of 
uranium formed. When heated just to redness, it is decomposed 
completely ; nitrous acid is driven off, and protoxide of uranium 
remains. 

Permuriate of uranium is formed in the same way as the per- 
sulphate. It does not crystallize, though evaporated to the 
consistence ofa syrup. The dry saltis very deliquescent. 

Percarbonate of uranium has been already described. 


Double Salts. 


Peroxide of uranium seems to have a great disposition to form 
double salts in combination with other bases, It has been 


1824.] On the Oxidum Manganoso-Manganicum. 267 


already stated that a solution of persulphate or permuriate of 
uranium does not crystallize ; but if a portion of sulphate or 
muriate of potash be added to the solution, we obtain by evapo- 
ration a uranium salt in combination with the alkaline salt. 
Potash-persulphate of uranium forms a granular crystallized 
mass, of a very fine lemon-yellow colour. The salt dissolves 
pretty easily in water. By alcohol it is decomposed in such a 
way that the persulphate of uranium is dissolved, and the alkaline 
salt remains behind undissolved. When heated, it loses its 
water, melts at a low red heat, and begins in this temperature to 
undergo decomposition ; for it acquires a green colour 3, butthe 
decomposition is very inconsiderable, for even after being eom- 
pletely fused, it dissolves again in water with a lemon-yeliow 
colour. Before it begins to melt it is not altered in the least. 
The constituents of this salt in an anhydrous state have beet 
given above, 
Ammonia-persulphate of uranium crystallizes like the preced- 
ing salt. It is easily soluble in water, and in a higher tempera= 
ture it is decomposed, leaving protoxide of uranium. 
Potash-permuriate of uranium crystallizes likewise, if we add 
a considerable proportion of muriate of potash to the solution of 
peroxide of uranium in muriatic acid; but unless this be done, 
the double salt crystallizes very slowly. It forms small crystals, 
sometimes in prisms, sometimes in grains. They are transparent 
and yellow, and have aregular form ; but are mechanically mixed 
with muriate of potash ; from which however they may be picked 
out quite pure; but the process is very tedious, as the crystals 
are small. The mixed muriate of potash cannot be separated by 
crystallizing again, foras it is just as soluble in wateras the double 
salt, they both crystallize at the same time. When heated, the 
double salt gives out water without being decomposed. It melts. 
when it begins to be red-hot, giving out chlorine gas. . It 
becomes green, and is decomposed, though only partially. 
I have not examined any other double salts, though it is likely 
that more of them might be easily obtained. 


ARTICLE V. 
Examination of the Oxidum Manganoso-Manganicum, a hitherto 
unknown Chemical Compound of the Protoxide and Deutoxide 
of Manganese. By Aug. Arfwedson.* 


In consequence of the experiments which have been made 
upon the oxides of manganese, it has been concluded that the 


|| Prandlated from the Athandlingar i Fysik, Kemi, &c. vi, 22% 


368 . \M. Arfwedson on ‘sO | [Aphyt] 
products formed, when protoxide of manganese is heated to 
redness in the open fire, and when nitrate of manganese is 
exposed to a red heat, constitute one and the same oxide; and 
that the different colours (for the former is brown and the latter 
black) are owing to the different states of mechanical division in 
which the two bodies are. But I have always obtained these 
two products, very different from each other in appearance, even 
when both were reduced to powders of the same fineness. The 
former always gives with sulphuric acid a weak amethyst-red 
solution ; while the latter forms with the same acid a solution 
having a deep grass-green colour. These different properties 
appeared to require a more accurate investigation of the chemi- 
cal constituiion of these two bodies. With this view | have, at 
the desire of Prof. Berzelius, made a set of experiments, of which 
I shall now give a short account. 

(1.) A neutral solution of pure muriate of manganese was pre- 
cipitated by bicarbonate of potash. The carbonate of manga- 
nese obtained was snow-white. After being washed with boiled 
and cold water, and dried in the vacuum of an air-pump with 
sulphuric acid, it remained without any change in its colour. 

_ The carbonate of manganese thus prepared was put into a 
spherical cavity blown in the middle of a barometer tube, 
through which a current of hydrogen gas was made to pass. As 
soon as the gas had driven out all the atmospherical air, the 
manganese was heated by applying a spirit-lamp to the glass 
ball containing it; and the heat was continued as long as any 
water and carbonic acid gas continued to be evolved. The 
powder by this process acquired a fine pistachio-green colour, 
which continued till the apparatus had cooled, and the atmo- 
spherical air was admitted to it, when it became greyish-green. 
A little portion of this powder treated with muriatic acid dis- 
solved without the least effervescence, showing that the carbonic 
acid had been completely expelled. 

. A gramme of protoxide prepared in this way was heated in a 
glass capsule over a spirit-lamp. The matter immediately took 
fire, and burnt to a dark-brown oxide, which weighed 1:0735 
gramme. Thus the increase of weight on 100 parts of protoxide 
was 7°35; and as the prctoxide is considered as containing 
219 per cent. of oxygen, the brown oxide must be a com- 
pound of 


Manganese ........ 72°784 ...... 100-00 
Oxypenaiy rs Vor 2FHQ1G 139 24) B79 


100-000 137-39 


.'The 1:0735. gramme of brown oxide was boiled with nitric 
acid to dryness, and heated to redness. The brown colour of 
the oxide gradually changed to black, with a copious evolution 
of nitrous gas, and. the weight of the powder became 1-195 


1824.) the Oxydum Manganoso-Manganicum. 269 


gramme. Exposed to a stronger heat in a platinum crucible 
over a charcoal fire, the weight was reduced to 1:100 gramme. 
Thus 100 parts of protoxide by this treatment increase 10 parts 
in weight ; and according’ to the preceding statement of the 
constitution of the protoxide, this black oxide is composed of 


Manganese. .....+... o Tee o9,0.2 9, 100-00 
ORV ON i oie sapere « 58-8 pace 7! a . 40°84 
100 140-84 


(2.) 1-192 gramme of protoxide of manganese, prepared as 
before described, left, when burnt in the open fire, 1-383 gramme 
of brown oxide. According to this experiment 100 parts of 
protoxide took up 7-043 oxygen, and the constituents of brown 
oxide are : 


2 gah Needle arpa pho eat ti Me 100:00 
Ue wlan fc ia-s\2 eRb ois 2» 37°45 
137-45 


The 1-383 gramme of brown oxide was boiled to dryness with 
nitric acid, and exposed to a strong red heat in a platinum 
vessel. The matter had acquired a shining black colour, and 
weighed ] 398 gramme. The increase of weight this time was 
so inconsiderable that it seems probable that some disoxygena- 
tion had taken place. It may be presumed, therefore, that the 
black oxide when exposed to a violent heat may be completely 
reduced to the state of brown oxide. The heat was continued 
for nearly an hour, and was as great as could be applied. The 
powder now resumed its former brown colour, and very nearly 
its original weight. The excess amounted only to two mille- 
grammes. 

To ascertain whether the black oxide can be prepared by 
means of a smaller determinate degree of heat so as to give 
constant results, the oxide of manganese already heated to red- 
ness was again treated with nitric acid, and heated over a spirit- 
lamp five different times, and the increase of weight was noted 
each time. The following little table shows the result. 

100 parts of protoxide had taken up 


it $C econ mes xh weer 14:4 parts of oxygen, 
PE TAD a1). har ute wean bsp 13°93 

BALI iviniya'ntuorns sR 10°52 
RR 4 dino nie hOrB7, 

er ais x kins o's acs b 4 10°13 


The smaller augmentation of weight in the last three experi- 
ments was owing tua further evolution of nitrous gas. The expe- 
riments show that the true increase of weight lies between 10:52 
and 10°13. We may, therefore, consider the increase of weight 


270 | M. Arfwedson on [Aprit, 


of. 100 parts of protoxide, when converted into black oxide, to 
be 10°4; so that black oxide is composed of 


Mancanese «4929 sme re0gans.nnan OOD 
Oxygen eoeerepeevrperer ee eereseeeevneeen ee 41°35 


{ conceive that I may conclude from these experiments, that 
we always find the weight of oxygen in the black oxide of man- , 
ganese prepared by means of nitric acid, a circumstance which 
is often of considerable importance in the analysis of minerals, 
in which the question often is to determine the composition of a 
given quantity of oxide. Perhaps the best method of proceed- 
ing may be to expose the oxide to a strong red heaf till it is 
converted into brown oxide, the composition of which is always 
uniform; and of course the quantity of oxygen in it may be 
known with great accuracy. 

According to the preceding experiments, the quantity of oxy- 
gen in the protoxide is to that in the black oxide as 1 to 1+; for 
100 parts of the metal combine in the protoxide with 28°107 
parts of oxygen, and this quantity multiplied by 11 makes 
42/160. The brown oxide, on the other hand, appears from the 
quantity of its oxygen to be intermediate between the protoxide 
and black oxide; but the oxygen constitutes no multiple either 
of the oxygen in the protoxide or black oxide. It must, there- 
fore, be a combination of these two oxides. If this compound, 
like the oxydum ferroso-ferricum be supposed so constituted 
that the oxide contains twice as much metal, and three times as 
much oxygen, as the protoxide, then it will be a compound of 


Manganese. .... sip wren a4 cows bear (end SIO 
Oxygen, Stand <ewasd eounrot dvi-dawbedes BE t 
100-00 
Direct experiments have given us 
Manganese. .........0-- tReet one 72°784 
Payoesd*yt », eta iee 10.8 2A S01 BBG 
100-000 


numbers which correspond as nearly with the calculated quan- 
tities as could be expected. On the other hand, we find that 
this compound by calculation may be composed of 


Black oxide of manganese. ........ 68°932 
Protoxide of MANGANESE. eeeeeeeees 31-068 


100-000 


T have called this oxide oxidum manganoso-manganicum, on 
account of its resemblance to the oxidum ferroso-ferricum, the 
constitution of which has been explained by Prof. Berzelius in 


1824.) the Oxidum Manganoso-Manganicum. 271 


his Attempt to lay the Foundation ofa new scientific System of 
Mineralogy, p. 92. 

{t remains now to ascertain how far the so called grey ore of 
manganese and the crystallized varieties of that mineral usually 
consist of manganese in the form of superoxide, or if they may 
not consist of black oxide, which we have seen gives out oxygen 
gas also when heated to redness. 


I. Crystallized Grey Manganmalm, from Udenas, in West 
Gothland. 


_ 5035 grammes of the pure crystallized ore was heated over a 
spirit-lamp in a small retort, to the beak of which was luted a 
glass tube filled with dry chloride of calcium, The matter, as 
soon as the heat was applied, gave out much water, which by 
degrees passed over, and was absorbed by the chloride. The 
heat was continued as long as any moisture was perceptible in 
the beak of the retort. The apparatus being now allowed to 
‘cool was weighed, and the loss of weight amounted only to two 
millegrammes, a loss so small that it may be overlooked. Thus 
no gas had been extricated. The mineral by this exposure to 
heat had lost 0°:508 gramme, which may, therefore, be reckoned 
the weight of the water contained in the specimen. The residue 
amounted to 4527 grammes; of this 4°504 grammes were 
exposed to a strong red heat ina platinum crucible: the loss of 
weight amounted only to 0°022 gramme. Being exposed a 
second time to as high a temperature as the fire could pire, the 
loss of weight was increased by 0°139 gramme. A third heating 
diminished the weight by 0°016. When heated for the fourth 
time no further loss of weight was sustained. The crystals still 
retained their shape; but the colour had been changed from 
black to reddish-brown, and the powder had a cinnamon-brown 
colour exactly similar to the above described oxidum manganoso- 
manganicum. The whole loss of weight amounted to 0:177 
gramme. This, though only from 4°504 grammes, may be 
taken without sensible error for the whole loss from 4527 
“bane as the error only begins to be perceptible in the fourth 
ecimal place. 
Thus the mineral had given 


Water. ...............6. 0°508 or 10:08 


Oxygen deck oved istveus tie be 0:177 3°51 
Oxidum mang.-manganicum. 4350 86°41 
5°035 100°00 


The small quantity of oxygen gas obtained shows evidently 
that the mineral under examination cannot be a superoxide of 
manganese ; and it seems plain that the manganese is in the 
state of black oxide ; for we find by an easy calculation, that 
the 86°41 parts of oxidum manganeso-manganicum obtained 


272 M. Arfwedson on... 5. [ApRit, 


require very nearly 3°51 parts of oxygen to be converted into 
black oxide. The constituents by calculation in 100 parts are, 


Oxidum manganoso-manganicum.... 86°85 


1c go SL AIPIUR EGY,  OSOF 
Water. . eeeeeerece IGE SHS SE oe ERAIOOE 
100-00 


Now the 86°85 parts of the oxidum manganoso-manganicum 
contain 23°6 parts, and 10°08 parts of water contain 8-895 parts 
of oxygen. Thus it appears that the oxygen in the oxide which 
has been heated to redness is not a multiple of the oxygen in 
the water; but if we add the 3:07 parts of oxygen driven off by 
the red heat to the 23°6 which are found in that oxide, then the 
unheated mineral will be a chemical compound with water, 
whose oxygen is just one-third of the oxygen in the oxide. The 
hydrogen of the water driven off and its oxygen, added to the 
oxide, make up the constituents of the superoxide. 

It is plain from the preceding experiments that the mineral 
just examined is a hydrate of manganese-oxide, whose oxygen 
contains three times as much oxygen as that in the water. The 


formula for this compound is Mn Aq. 


II. Common Grey Ore of Manganese. 


a. 5:03 grammes of this mineral in powder freed from water 
mechanically lodged in it were put into a small glass retort, to 
the beak of which was luted a glass tube filled with dry chloride 
of calcium. The retort was heated over a spirit-lamp as long as 
any moisture was disengaged. The apparatus being allowed to 
cool was found to have lost 0°143 gramme of its weight ; this 
was gas disengaged. The chloride of calcium had increased in 
weight 0:077 gramme, which was water. The residue weighed 
4:310 grammes. 

6. Three grammes of the powder thus freed from water and a 
portion of gas were exposed to a strong red heat in a platinum 
crucible. After three repetitions of this process, the loss of 
weight was 0-286 gramme ; and the blackish-grey colour of the 
mineral was changed into brown, A fourth exposure to heat 
was tried without any diminution of weight. Since 3 grammes 
by this treatment lost 0:286, it is evident that if the whole quan- 
tity had been thus treated, it would have lost 0°458 gramme. If 
to this we add the 0-143 lost over the spirit-lamp, we see that 
the 5°03 grammes of the mineral had lost 0°601 gramme of oxy- 
gen and 0:077 of water. 

c. The 3 grammes employed in the preceding experiment were 
dissolved in muriatic acid. The solution was evaporated to 
dryness, and the dry mass again dissolved in water acidulated 
with muriatic acid. There remained undissolved silica and 
earthy matter, which, after being washed and heated to redness, 


1824.) the Oxidum Manganoso-Manganicum. 273 


weighed 0:442 gramme. The filtered solution was digested with 
au excess of caustic potash ; the precipitate formed was collected 
on the filter and washed. The alkaline ley which passed through 
was examined by the usual reagents, but it was not found to 
contain any thing in solution. The precipitate by the caustic 
potash was dissolved from the filter in muriatic acid. The solu- 
tion, after being neutralized by ammonia, was mixed with some 
drops of oxalate of ammonia, but the liquid continued clear. It 
was afterwards mixed with succinate of ammonia as long as any 
precipitate fell. The succinate of iron thus obtained was sepa- 
rated and washed. Being heated to redness the residual oxide 
of iron weighed 0°124 gramme. 

As this 0-124 gramme of oxide of iron, together with the 
0-442 gramme of silica and matrix, must be separated from the 
3:grammes of the mineral examined, the residual pure oxide of 
manganese amounts to 2-434 grammes ; and consequently the 
4-81 grammes of the heated mineral in a contained 3-902 
grammes of pure oxide. If to this we add the 0°22 gramme of 
gas and water driven off in a, the whole quantity of the mineral 
freed from foreign matter was 4:]22 grammes, and its consti- 
tuents were, 


— 0-601 ...... 14:58 
Wotetia iis) '.* Ae is is A MN hes 
Oxidum man.-mangan. 3°444 ...... 83°56 


4:122 100-00 


The small quantity of water may be considered as mechani- 
cally lodged in the mineral. 83°56 parts of oxidum manganoso- 
manganicum contain 22°71 parts of oxygen. Thus the remaining 
60°85 parts of manganese had been united with 22°71 + 14:58, 
or 37°29 parts of oxygen, which for 100 parts amounts to 61°45. 

The superoxide of manganese is considered as a compound of 
100 metal and 56°213 oxygen. The oxygen found in the mine- 
ral, therefore, is too high; but this is probably owing to some 
error in the analysis, the principal object of which was not to 
determine the constitution of the superoxide, but only to ascer- 
tain if the mineral was in this higher state of oxidizement; and 
the result shows clearly that the manganese was in the state of a’ 
> tenia 

ineral superoxide of manganese is easily distinguished from 
the hydrate by the different colours of their powders. The pow- 
der of the superoxide is-a full black, while that of the hydrate on 
the other hand is yellowish-brown, We have only to scrape the 
minerals with a knife;. the difference is immediately seen. 


Protoxide of Manganese. 


A globular cavity was blown in the middle of a barometer 
ew Series, vol. Vil. T 


274 On the Oxidum Manganoso-Manganicum. [Apnrit, 


tube, which was filled with pure carbonate of manganese, and a 
current of muriatic acid gas was passed through it. The extri- 
cation of gas took place without any evolution of heat till the 
salt appeared completely decomposed. The salt was now 
heated by a spirit-lamp at first slowly, but at last the greatest 
possible degree of heat was given. The muriate thus formed 
was rose-red, and it retained its colour, though the muriatic acid 
gas driven over was at last mixed with hydrogen gas. The salt 
thus obtained weighed 1°52 gramme. Being dissolved in water 
there remained behind 0-012 gramme of oxide of manganese. 
The remaining 1°508 was a neutral salt. The solution was quite 
colourless. The muriatic acid was thrown down by nitrate of 
silver, and gave, after the usual treatment, 3-408 grammes of 
horn silver, which contains 0°650 gramme of muriatic acid. 
This acid was combined with 0:858 gramme of protoxide of 
manganese ; but 0°65 muriatic acid saturate a quantity of base, 
whose oxygen amounts to 0191; consequently the 0-858 
gramme of protoxide and manganese contain this quantity of 
oxygen, The experiment gives us 100 parts composed of 


Manganese......+- 77°856 ...... 10000 
Oxygen. cc ccccceee JIG oe esis oti 2B44 
100-000 128-44 


John, by direct analysis of neutral sulphate of manganese, 
found the protoxide of this metal to contain 21-875 per cent. of 
oxygen. The oxygen, according to my experiment, is a little 
more ; but I have reason to conclude that a small quantity of 
black oxide existed in the muriate of manganese which I 
examined. The result of my experiment, therefore, may, per- 
haps, be the less to be depended on. 


eB 


Appendix. 


That the English reader may fully understand the preceding 
paper, a few observations may be necessary. 

1. The atomic weight of manganese is 3°5, and the atomic 
weight and constituents of its oxides are as follows : 


Composition. 
Atomic weight. Metal. Oxygen, 

1. Suboxide . ..6..00. 410 «oa. BD + 05 
2. Protoxide, s.cssese 45 seer 35 + 1 
3. Deutoxide ........ 50 «6... 35+ 1 
4 APTILORIMES |. 00 eas mn OD és pagal os 
5. Manganesous acid. . 6°5 J5 +3 
6, Manganesic acid. ., 7°5 w1.4 35 + 4 


1824.] Mr. Levy on a new Mineral Substance. 275 


2. The oxidum manganoso-manganicum of Arfwedson is a 
compound of | atom protoxide and 2 atoms deutoxide. 


1 atom protoxide. .....ceeeeeseusves 45 
2 atoms deutoxide....sseccccceeesee 100 


3)145 


——_— 


4-833 


so that its atomic weight (reduced to the lowest terms) is 4-833. 

3. According to Berzelius the atomic weight of manganese is 
7-1157, and the names and constituents of the different oxides 
are, according to him, as follows : 


Composition. 
Atomic weight. Metal. Oxygen. 
2. Oxydule .... 9:1157 .... 71157 + 2 
Ds CIRIGEs 0 dys 0s 10:1157 .... 771157°4+'3 


4, Superoxide... 10°1157 .... 71157 + 4 


4, Berzelius represents these three oxides by the following 
symbols: 


1. Protoxide Mn. 
2. Deutoxide Mn. 
3, Tritoxide Mn. 


denoting the number of atoms of oxygen by the dots above the 
letters Mn. 


TT ET 


ArticLe VI. 


Account of a new Mineral Substance. By M. Levy, MA. 
in the University of Paris. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, March 12, 1824. 
Uron a specimen from Arendal, belonging to Mr. Turner’s 
collection, £ haye lately observed with cleavelandite,* flesh- 
coloured felspar, and green am hibole, some small brilliant black 
crystals, the description of which I now send you, because I 
believe they belong to a new mineral species. Their form is 


* The substance I call here cleavelandite forms the greatest part of the specimen ; it 
has much the appearance of cleavelandite, but however I have not been able under the 
small particles I have detached to obtain cleavage sufficiently brilliant for measurement, 

T2 


276 Mr. Levy on anew Mineral Substance. [APRit, 


Fig. 2. 


represented by fig. 2; in some of them, however, the plane m 
and its opposite are wanting, so that the prism is then six-sided. 
instead of being eight-sided. These crystals cleave easily with 
. brilliant surfaces parallel to the planes p and ¢, fig. 2. There is 
also an indication of cleavage parallel to the plane m. All the 
natural planes, as well as those obtained by cleavage, are sufli- 
ciently brilliant to allow the use of the reflective goniometer for 
the measurement of their incidences. From the measurements 
I have taken, and the cleavages already mentioned, I am induced 
to take for the primitive form of this substance a doubly oblique 
prism, fig. 1, in which the incidences of p on m and ¢ are respect- 
ively 92°34’ and 88°, that of m on ¢ 112° 30’, and in which the 
three edges d, f, h, which meet at the solid angle o, are to each 
other nearly as the numbers 13, 20, 11: The incidences of p on 
m and ¢ are nearly supplement of each other, the only difference 
being 34’, hence the primitive form differs but little from an oblique 
rhombic prism; for if these two angles were exactly supplement 
of each other, then the incidences of p on m, and on the face 
behind parallel to ¢, would be equal, and consequently the pri- 
mitive would, at least so far, have the character of an oblique 
rhombic prism. There is another incidence which might, 
without a proper attention, lead to the same conclusion respect- 
ing the nature of the primitive. It is the incidence of the planes 
h' and g°, fig.2, which is equal to 89° 20’ ; that is to say, very near 
a right angle.. Now if the planes g? and h' were considered as 
the diagonal planes of a rhombic prism, they should be perpen- 
dicular to each other. These indications of an oblique rhombic 
prism, as the primitive form of this substance, are, however, car- 
ried no further, and are entirely destroyed by the want. of the 
symmetry which should accompany them. The faces h', 9’, if 
the diagonal planes of a rhombic prism, should be equally inclined 
upon the two lateral planes which they meet ; and here we find 
that the incidences of h', with the planes m and ¢, as well as 
those of g? with m, and the plane parallel to ¢, differ widely from 
each other. The occurrence of the plane d' without being 
accompanied by a plane replacing the edge of intersection of 
plane p with the plane parallel to ¢, is also incompatible with an 
oblique rhombic prism. No doubt can remain, therefore, as to 


1824.] Mr. Children’s Examination of Babingtonite. 277 


the primitive form being a doubly oblique prism. I have 
thought it would not be useless to place here the discussion of 
the observations which might lead to assume another form as 
the primitive, on account of the ambiguous characters of this 
remarkable form. The incidences of the planes of fig. 2 are as 
follow : 


(p, m)= 92° 34’ (p, t) = 88° (m, f) = 112° 30’ (m, h') = 137° 5’ 
(é, h') = 155° 25’ (p, d') = 150° 25’ (g?, m) = 132° 15’. 


These crystals scratch glass easily. This substance I propose 
to call Babingtonite, in honour of the late President, and one of 
the founders of the Geological Society of London. His claims 
to have his name thus recorded in mineralogy, are too many, and 
too well known to every well-wisher of this science, to require 
any comment by me. . 

In Mr. Turner’s catalogue, I had given the same name to a 
substance from Freyberg ; but I find that Mr. W. Phillips, in 
his last work on Mineralogy, has noticed the same substance, 
and designated it under the name of sulphuret of silver and anti- 
mony, which name there is not the least ground to change. 

Mr. Children has kindly undertaken to examine with the 
blowpipe a small quantity of babingtonite. - 


ew Oe 


Articre VII. 


Examination of Babingtonite by the Blowpipe. 
By J. G. Children, Esq. FRS. &c. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, March 14, 1824. 


In glass matrass, the Babingtonite decrepitates very slightly, 
and gives off a dense vapour, which soon disappears. A thia 
film of pure water condensed on the sides of the tube. Appear 
ance of the assay not altered. 

Alone, in forceps, fuses on the surface, pretty readily, into a 
black enamel. 

With soda, on platina wire, in the oxidating flame, the assay 
gives a dark-green opaque globule ; the addition of nitre height- 
ens the colour. 

In the reducing flame, the colour changes to dark-brown, or 
nearly black ; globule opaque. 

ith borax, P.W. InO.F. deep amethyst-coloured glo- 
bule ; in R. P. colour changes to bluish-green ; globule perfectly 
ay her in both flames. 

uth saltof phosphorus. P.W. In O.F. scarcely any action 


278 Col. Beaufoy’s Astronomical Observations. [APRit; 


ona minute fragment of the assay ; globule transparent, orange- 
yellow, while hot; when cold, colourless. In R. F. the same, 
but colour greenish while hot. . 

With the same flux, and the assay in fine powder; in O. F. 
solution more easy ; but a considerable silica skeleton remains 
undissolved: colour as before, but deeper. In R. F. nearly 
colourless, hot; when cold, slightly inclining to an amethystine 
colour. . By the addition of a morsel of tin foil, the amethyst 
colour a very little deeper. 

With nitrate of cobalt, black mass, without any indication of 
alumina. 

In addition to the silica, iron, and manganese, clearly indicated 
by the preceding experiments, I obtained, via humida, a consi- 
derable proportion of lime. By the action of the salt of phos- 
phorus, in the reducing flame, there appears to be a minute 
portion of titanium present, but want of time, and a larger quan- 
tity of the assay, prevented my obtaining any very decisive 
results in that respect by operating in the moist way: though 
they tended to strengthen the probability of its being contained 
in the mineral: its quantity however must be very minute. 


ArticLte VIII. 


Astronomical Observations, 1824. 
By Col. Beaufoy, FRS. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, 

I sna be much obliged to any of your astronomical corre- 
spondents, if they will favour me with their observations on the 
eclipse of Jupiter’s third satellite, which occurred on the 26th of 
last January, as I think it is probable I committed an error by 
mistaking one satellite for another, in the observations published 
inthe Annals for March. 

I remain, dear Sir, yours very truly, 
Mark Bravuroy. 
—<=_—— 


Bushey Heath, near Stanmore. 
Latitude 51° 37/ 44:3” North. Longitude West in time 1’ 2093”, 


Feb. 21. Emersion of Jupiter’s first § 9h 39’ 02 Mean Time at Bushey. 
Reread ste aise setae I as 9 AO 23 Mean Time at Greenwich, 
March 3. Enmersion of Jupiter’s second §11 O08 36 Mean Time at Bushey. 


BAMIMECU ten Dar Oe a cms cesa’ 11 09 57 Mean Time at Greenwich. 
March 8. Emersion of Jupiter’s first ¢ 7 58 22 Mean Time at Bushey, 
Sateliate i tap trciee ea we Risin 7 9 A383 Mean Time at Greenwich, 


March 12. Occultation of « Leonis by the : ‘ 5 
moon, Imimersion......0. ' T Rit 12 ean Time at Bushey. 


279 


Meteorological Register for 1823. 


1824.] 


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280 Meteorological Registers for 1823. [Aprit, 


Jan.—The snow continued 12 days, which is much longer 
than usual. 

Feb.—A very wet month. 

March 4 and 5, very stormy. The gusts of wind were extremely 
sudden, with wind to the NW. 

April——On the morning of the 5th, the wind changed sud- 
denly from the SW to NE, and continued very boisterous till 
noon: 26. Heavy hail shower, with distant thunder. 

May.—A cold month, except the few last days, which were 
remarkably fine. 

June.—Very cold. Fires required by many in the evenings : 
some thunder. : 

July.—Remarkably cold, wet, and boisterous; scarcely two 
days fine successively. . 

August—A wet month; much thunder and lightning on the 
22d and 24th ; about two inches of rain fell in the morning of 
the 24th in the course of six hours. 

Oct.—The wind rose suddenly in the evening of the 30th to a 
perfect hurricane, which continued throughout the night. The 
barometer fell about 1 inch in about 24 hours, 


Dec. 29.—Much lightning. 


7 


2. By Mr. Edward Collins Giddy, at Penzance, Cornwall. 


; Night and|Common 
1823 Barometer and Attached Thermometer. Day Ther. | Therm. 


Mean of the|True mean| Attached | Attached |Mean of the|Mean of 
month, jofthemonth.|therm. max.|therm. min.| month. month. 


January ...| 29°435 29°396 52 38 39°0 40-0 
February...| 29°355 29-311 52 42 43 0 43:2 
March..... 29°715 29°665 52 45 46-0 45°1 
April......| 29-700 29-638 56 A8 AT‘0 AT+2 
May...... 29-740 29°662 62 54 55:0 56:2 
June.....-| 29°765 29°682 62 56 555 57-1 
July ...26-| 29°T10 29°621 64 58 59-0 59-1] 
August....| 29°745 29°652 64 60 59-5 60-2 
September .| 29°840 29°750 66 56 57°5 58-0 
October....| 29°540 29-468 62 48 515 53-0 
November..| 29-900 29'841 58 48 ° A8-5 49-0 
December..} 29°645 29°589 58 48 46-5 AT-0 
Annual 
means, &c.| 29:670 29°606 66 38 50-0 51:0 
Ditto 1822 | 29-760 29°694 72 40 52°5 53-6 


Barometer, 1823. Highest, Dec. 7, Wind, NW. 30°38; Lowest, Feb. 2, Wind, 
NE. 28°45.—Day and Night Thermometer. Highest, May 29 and July 20, Wind, 
S. T0°; Lowest, Jan, 16, Wind, NE, 27°. 


1824. Meteorological Registers for 1823. 281 


3. By Col. Beaufoy, at Bushey Heath. 


Janu 0-916 0°310 
February 2°537 1-360 
March..... 0-758 3:020 


August....} 2°450 3°330 
September. .| 2°509 | . 3-790 
October....| 3°076 1-890 
November..| 1644 1-200 
December -.| 2°258 1-280 


Total| 25:°282 | 32-430 


4, By Mr. James Stockton, at New Malton, Yorkshire. 


Barom, | Ther. 
Mean. | Mean. 
January ...| 29°574 | 31:887° 


February...| 29°184 | 35-785 
March, ....| 29°706 | 40-209 


April...... 29°856 | 44-033 
May.......| 29°895 | 54-419 
June...... 29-990 | 54-916 


July...... | 29°T1L | 58774 
August....| 29°T80 | 57°645 
September. .| 29°868 | 52-516 
October. ...| 29°680 | 45°T41 
November. .} 30-083 | 42750 
December..| 29°514 | 36-710 


Annual 
means, &c.| 29732 | 46-282 


ANNUAL RESULTS. 


Barometer. 

Inches. 
Highest observation, Noy. 10. Wind NE........... 30°880 
Lowest observation, Oct. 11. Wind SE............ 28350 
Range of the mercury .........sssceccerereceseses 2530 
Mean annual barometrical pressure ....-+.++e00++++ 29°732 
Greatest range of the mercury in October. .........+  2°180 
Least range of the mercury in July. ......-.++++ee04 0°900 
Mean annual range of the mercury. ......+eeeeeee4- 1597 
Spaces described by the mercury .......+eee+eeeeee 99°180 
Total number of changes in the year. ....+++++++++ 154000 


282 Meteorological Registers for 1823. [Aratt, 


Six’s Thermometer. 


Greatest observation, May 7. Wind, variable. ...... 77°000° 
Least observation, Jan. 18. Wind, NW.......++...+ 9°000 
Range of the mercury in the thermometer.,......+... 68°000 
Mean annual temperature. ...0+.ceceeesrsceecseces 46°282 
Greatest range in May.) jo escses ewsesdesitcos cesses GO U00 
Least range in February . ...+--csesovnsgecceseres 22 000 
Mean amnual range .° oe oe feccccep ss cpesibocvescces SpOtO 


Winds, 
Days. 
Worth and Bast <.'.< canis +4 siamwate so ssideatd > 3.90 bale wile 
North-east and South-east... .cccccecsccceccsecess 79°000 
South and ‘Weat: 0.508075 essa ee aan cite den Gd OD 
South-west and North-west. .......ccececsesececes 112000 
Marable oti al. Suk. de lncilis Saeerearr eid alike ee eee 25-000 


Rain. 
Inches, 
Greatest quantity, in February .......seeeeeeeeee0. 7°040 
Least Quantity, 18 Apt) nq0p-s-s-oremdcomep-scane os.0eenes) ae 
Total amount for the: yea... ii. Vs eas BV Neer eee ces 42°400 


Observations. 


Pressure-——The mean annual barometrical pressure (notwith- 
standing the extraordinary wetness of the period, is greater than 
that for many years past. 

Temperature.—The mean annual temperature fully confirms 
what has been before advanced, that wet summers are generally 
cold; the whole of the monthly means, with the exception of 
May and December, are unusually low. Indeed the actual defi- 
ciency as to the annual amount exceeds 21 degrees. 

Winds.—These nearly agree with their respective numbers in 
1822, and what is more strikingly remarkable, those of the SW 
exactly correspond. 

‘Rain.—As to rain and snow, the amount is nearly unprece- 
dented, and for the last three years it has been rapidly increasing, 


1824.) On the Transitission of Electricity through Fluids, 283 


ARTICLE X. 


On the Effects of transmitting the Electrical through other Fluids. 
By Mr. C. Woodward. 


(To the Editor of the Annals of Philosophy.) 


SIR, March 12, 1824. 


As every subject connected with electrical science is daily 
assuming a more important feature, the following experiments 
and observations may not be uninteresting to some of your 
readers. 

Place a piece of glass on the table of the universal discharger, 
and bring the pointed wires nearly in contact upon the surface 
of the glass ; over the intersection formed by the wires, strew 
some loose gunpowder, and pass through it the charge of a jar 
containing about a square foot of coated surface, when it will be 
found that the powder will be invariably dispersed without 
inflammation. 

Take a glass tube six or eight inches long, and about a quarter 
of an inch in diameter, fill it with water, and insert a cork at 
each end; through the corks pass pieces of wire so as to form a 
conducting communication with the water; place some loose 
gunpowder on the glass of the universal discharger as before, 
insulate the tube, and let it form part of the circuit; pass the 
charge through the water, and the gunpowder will be inflamed. 

The small degree of intensity of charge required to produce 
the inflammation of gunpowder, when transmitted through a 
tube of water, is surprismg; as the discharge of a quart jar 
indicating only an intensity of from 10 to 15 degrees is generally 
sufficient, and there appears to be little or no difference in the 
effects of tubes varying from 3 to 18 inches in length. 

In prosecuting my inquiries to ascertain the cause of this sin- 
gular effect, I found that the charge of a jar, which, when 
transmitted by good conductors, was sufficient to produce the 
fusion of 12 inches of iron wire, did not affect a single inch of 
the same wire, when passed through the tube of water; from 
which J concluded, that the intervention of the water tube, must 
have produced or prevented some mechanical effect. 

I then pasted on a board, about three feet long, a narrow slip 
of tin foil, in which, at equal distances, four intersections, about 
one-eighth of an inch each, were made. I insulated the board, 
and placed over one of the intersections some loose gunpowder, 
and over each of the others six or eight wafers. On transmit- 
ting in the common way a charge through the tin foil, the pow- 
der was scattered, and the wafers blown three or four feet from 


284 On the Transmission of Electricity through Fluids. [ArRi1, 


the surface of the board; but on repeating the experiment with 
a tube of water, the powder was inflamed, and the wafers 
remained without any perceptible motion. This experiment led 
me to suppose, that a sufficient degree of heat under each cir- 
cumstance was produced by the electrical fluid to inflame the 
powder; but when it passes through good conductors, the air is 
so suddenly and violently expanded, that the powder is scat- 
tered before it can be inflamed, as is the case with some of the 
grains when a musket is let off (for if it be fired over snow, a 
considerable portion of unconsumed powder will be perceived), 
‘but water being a less perfect conductor than the metals, by 
opposing a resistance to the passage of the electrical fluid, 
retards tts velocity, and thus prevents the sudden expansion of 
the air, which would have scattered the powder before inflam- 
mation could have taken place. 

This theory explains the circumstance of the charge having 
no effect upon the wires when transmitted through a tube of 
water. Itis well known that intensity of charge is of the great- 
est importance in the fusion of wires. Now as intensity is 
velocity, it must follow, if the velocity of a charge be retarded, 
the intensity must be diminished ; and hence no experiment 
requiring intensity of charge can be performed when the water 
tube forms part of the circuit. 

If the tube be filled with other fluids, it will be found that the 
nearer the transmitting medium approaches to a good conductor, 
the greater will be the expansive effects ; and as the expansive 
effects increase, the difficulty of inflaming the powder will 
increase also. 

If the tube be filled with ether or alcohol, and placed in the 
circuit, the powder will be inflamed. Ifit be filled with sulphuric 
acid, which is a better conductor, the powder will be scattered 
and not inflamed, but the dispersion will not be so great as when 
metals only form the circuit. The same effect will be produced 
by transmitting the charge through the animal economy, or 
through water mot inclosed in tubes, in which case the water 
does not appear to oppose a sufficient resistance to the passage 
of the fluid. 

_ But the most remarkable circumstance attending these phe- 
nomena is, that itis immaterial whether the tube form part of the 
circuit before the electrical fluid passes the gunpowder, or a/ter- 
wards. If the tube be placed on what I will call, for the sake of 
distinction, the negative side of the powder, either in immediate 
contact with the powder, the coating of the jar, or in any part 

of an interval in 20 yards of chain, the powder will be invariably 
inflamed when the charge is passed. 

In this experiment the effect appears to precede the cause ; 
and it may be asked, does it not prove the existence of two 
fluids ? Some would no doubt answer in the affirmative, but so 


1824.) Mr. W. Phillips's Hints to.an Edinburgh Reviewer. 285 


many difficulties attend the introduction of two fluids, and so 
many experiments militate against it, that I would refer to some 
other cause for an explanation of the fact. 
Every substance which may be used as a conductor possesses 
a certain quantity of electricity, which, unless disturbed, remains 
in a dormant or a latent state. When a charge is passed 
through conductors, I conceive their natural quantity of electri- 
eity is driven offin the same way as water forced through tubes 
filled with the same fluid expels the water contained in them 
before any more can enter; and if an impediment were placed 
’ in any part of such tubes, the obstruction would be immediately 
felt throughout. So with the electrical fluid; the obstruction 
made by the introduction of water, which is a less perfect con- 
ductor than the metals, instantaneously affects the whole line of 
the circuit in whatever situation the tube may be placed; and 
by retarding the velocity with which the electrical fluid moves, 
prevents the expansive effects which the charge would otherwise 
have produced. 
I am, Sir, your obedient servant, 
; CuarLes Woopwarp, 


ARTICLE XI. 
‘Hints to an Edinburgh Reviewer. By W. Phillips, FLS. &c, 


Ix the Edinburgh Review for January last, the concluding 
article is headed by the title page of the third edition of my 
Elementary Introduction to Mineralogy; but the “ running 
title” is, with more propriety, ‘‘ Mineralogical Systems.” At 
the conclusion of the article, however, the Reviewer has bestowed 
on my little book half a page ; and though not acquiescing in 
the correctness of all his observations, I have nothing to object 
against the tone and manner of the criticism. 

But “there is a circumstance which merits attention, as it 
affects the degree of confidence which we can place in crystal- 
lographical indications” (p. 495), as reported by the Reviewer, 
who proceeds thus: “ Similar cleavage planes in different indi- 
viduals of the same species, meet in some cases under angles of 
different values. These differences are stated by the author of 
the work before us, as amounting even to forty minutes of a 
degree.” 

ow we might expect that a Reviewer should possess the 
several qualifications essential to the elevated position 
he voluntarily occupies, when he undertakes the task of 
criticising the works of others. First, that he should under- 
stand the subject ; secondly, that he should read the work he 
criticises ; and thirdly, that he should quote faithfully and accu- 


286 Mr. W. Phillips’s Hints to an Edinburgh Reviewer. [Arnri1, 


rately ; but really I am compelled, though with regret, to con- 
clude, that the RAvibwer in question must be deficient in all 
these requisites, and he must excuse me if I proceed to the 
roof, 

m Supposing that the “ author of the work before us,” as the 
Reviewer has it, had not known better than to’ assert that the 
“ cleavage planes of different individuals of the same species 
meet in some cases under angles of different values;” the 
Reviewer ought himself to have known enough of the subject to 
have enabled him to contradict the assertion, and to set the 
author and his own readers right, instead of building upon’ so 
unfounded a position, as the Reviewer has done, a sort of battery 
against ‘ crystallographical indications ;” which, indeed, as the 
case stands, is avery harmless one. But the Reviewer could 
not have been aware of the fact, that the planes of cleavage of 
different individuals of the same species do always meet at the 
same angles, if the cleavages and the selection of the minerals 
be made with proper care ; and I cannot refrain from advising 
him to convince himself of this fact, by beginning with calca- 
reous spar, sulphate of barytes, or any other of the several mine- 
rals which are commonly chosen for the first attempts of the tyro 
in this important and interesting department of the science. 
Let him give only an hour or two to cleavage and the reflective 
goniometer, and he will not fail to convince himself that if I 
had said what he attributes to me, I should have mis-stated a 
fact; but as he must be unacquainted with that well-known 
fact, I think it is sufficiently apparent that he must be deficient 
in the first requisite+a knowledge of the subject; that is, of 
mineralogy. 

The existence of the second and third requisites may be discuss- 
edtogether. The place in which I have mentioned an occasional 
variation of 40 minutes in angles obtained by the reflective gonio- 
meter, andI believe the only place, is in the second page of the 
advertisement to the third edition. Now if the Reviewer had 
given a reasonable attention to the former part of the paragraph 
in which that observation occurs, he would have found out that 
I was speaking of the natural planes, not the cleavage planes ot 
crystals. My words are, ‘the measurements of the crystalline 
forms, and especially of the secondary planes, are not precisely 
exact, do not on all occasions relatively agree —It has been 
ascertained by a comparison of the measurements taken from 
similar and brilliant planes of different crystals,” [the planes of 
crystals can be no other than their natural planes] “ that, owing 
to some natural inequality of surface, the same precise angle is 
rarely obtained—that the limit of error is considerably within 
one degree—that it rarely exceeds 40 minutes, and that it is 
frequently confined to a minute or two.” And if the Reviewer 
had read a few more lines of the same paragraph, he would have 
been convinced, even if the above quoted words had not served 


1824.) On the Crystalline Forms of Artificial Salts. 287 


to-convince him, that the exceptions related solely to natural 
planes ; for he would have perceived that I have said, “ The 
measurements obtained from planes produced by cleavage, may 
be considered as approximating the truth much more nearly, 
than those taken by means of the watural planes.” And if the 
Reviewer had condescended to peruse page xxix of the Intro- 
duction, he would have found this remark ; “* But if we cleave a 
crystal, carbonate of lime for instance, if it be pure and transpa- 
rent, we shall find, by the help of the reflective goniometer, that 
the planes of the primary nucleus which will be extracted, meet 
invariably under angles of 105° 5’ and 74° 55’.”. The carbonate 
of lime is here quoted as an instance, that if we cleave a crystal 
[of any substance which is pure] the planes of cleavage will 
meet under constant angles. 

I am now content to leave the reader and the Reviewer him- 
self to judge whether he possesses or not the second and third 
requisites for his office. I wish, however, that he may be dis- 
posed to take these hints for his future government, and believe 
the fact, that personal feeling is concerned in them only in so 
far as belongs to the regret necessarily accompanying a mis- 
statement of one’s own words. It is for the credit and utility of 
cleavage and the goniometer principally, that 1 am induced 
thus publicly to expose the fallacies of. a Reviewer whose 
dicta on mineralogical systems ought to be received with 
caution, since he has attributed to an author an error of his 
own, and which if he had understood the science (he must excuse 
me) could not have been written. 

It might not, perhaps, be very difficult to point out some 
inaccuracies (to speak gently) in the Reviewer’s review of the 
Systems ; but with these I do not meddle. In line 21, p. 491, 
there is, however, one error that must be noted for the benefit of 
the Reviewer’s reader. For brimstone read limestone. This 
error is somewhat odd, considering the locality of its origin, and 
must be ascribed to the printer, or rather one would think, to the 
“ printer’s devil.” 


ArtTicLe XII. 
On the Crystalline Forms of Artificial Salts. 
By H.J. Brooke, Esq. FRS.° - 
(Continued from p. 162.) 
Hydrate of Strontia. - 


From the measurement and cleavage of some crystals of this 
substance received from the laboratory of the Royal Institution, 
I find its primary form to bea right square prism. The cleavage 


288 On the Crystalline Forms of Artificial Salts. [ApriL, 


parallel to P is very easy, and the planes 
bright; that parallel to M and M’ is less 
determined, although sufficiently apparent. 


Pt My Or MM, ko sane. ce. 0 


Be ORL och n woae tak + 4p 
Wi on. I .., .erssve’s ahaa sack 90 O 
TN UR a oly al with s «9 i352 . 12 


Acetate of Strontia. 


The crystals I have obtained of this salt from a solution of the 
carbonate in acetic acid are very small, with rather imperfect 
planes, and have not afforded distinct cleavages parallel to any 
ofthese. There is, however, an appearance of cleavage parallel 
to the plane M of the annexed figure. 
From the general character of the crystals 
and from measurement, a sight oblique- 
angled prism may be regarded as their pri- 
mary form. The crystals are very efllores- 
cent. 


Mronids cause -» 96° 10’ 
Moni. |. Jedi... 107 33 
WE OP aie oh 5 AG ows 129 20 
Miomeci. .wi.ot.t cota L6Bivth2 


Ponies. is. sadiua Jes 2122 i068 
mde! of). saeies ov. bd2k be 


Nitrate of Strontia—Anhydrous. 


The primary form is a regular octahedron. The crystals gene- 
rally pperbne those of nitrate of lead, given in the number of 
the Annals for January last. 


Hydrous. 


A very efflorescent salt, and not affording any distinct cleav- 
age that I have been enabled to discover. We may assume an 
oblique rhombic prism as its primary form. The crystals are 
sometimes considerably lengthened, and 
present only those planes which are marked 
as the primary. 


P on M, or M’........ 103° 40’ 
P ON 6, GP At wicsin in Gis ie LAIe 


Monk... . co. (t-2 OD 
M oni... eeeeeeveeert 150 10 
RE asin ub tintin» 0 baay: 0 


1824.] Mr. Cooper on the Nitrates of Strontia. 289 


ArTICLE XIII. 


Analysis of the Nitrates of Strontia, described in the preceding 
Paper. By Mr. J. T. Cooper. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, . March 20, 1824. 


Ar the request of Mr. Brooke, who observed the difference 
in the primary forms of the crystals of this salt, | have under- 
taken its analysis, and for this purpose I exposed 50 grains of 
the prismatic variety to a heat of 240° Fahr. for a considerable 
time until it ceased to lose weight ; the quantity of water lost 
was 13-9 grains, leaving 36:1 of dry nitrate; the dry nitrate was 
then dissolved, and solution of carbonate of potash added (of 
known strength) until it ceased to precipitate carbonate of stron- 
tia; it required a quantity of the solution equal to 23-8 of 
dry carbonate of potash ; the fluid portion now showed no trace 
of the alkali, or the earth. The carbonate of strontia, when dry, 
weighed 25-7, and the fluid portion evaporated to dryness left 
34-7 of nitrate of potash. 

From the above, it is evident the composition of prismatic 
nitrate of strontia is in 50 grains 


PE, cus te sale teas OS OF 1 t0n oor 


Page yy, 88, Sek PP? 35:4 
Rater 5); cts as bvscs) LOW 27°8 
50-0 100-0 


This differs considerably from Kirwan who, appears to be the 
only chemist who has examined this variety : he states the com- 
position of it as, 


Py. Lise eee Hi ee Bee . ol°07 
Ge Se ee ee roe es 36°21 
Water. oJ Fs Rg LALA a ROL, oy 32°72 


The difference in the quantity of water may be in a great 
measure accounted for by his not selecting perfectly formed 
crystals for his experiments ; but how the variation in the pro- 
portions of the acid and base could arise is much more difficult 
to account for. The crystals employed by me were selected by 
Mr. Brooke for the purpose. 

Lalso obtained from Mr. Brooke some well-formed crystals of 
the octahedral variety, and having weighed 14°84 grains, I sub- 
jected them as before to heat for a considerable time; the loss 
amounted to -07 : they were afterwards heated to a much higher 
temperature, but not sufficient to decompose the salt, when a 

ew Series, VOL. Vil. U 


290 Dr. Fleming on a [Aprii, 


further loss of 02 occurred; but this loss was recovered after 
the salt had stood a few minutes exposed to the air. The crys- 
tals did not in the least lose their transparency ; they were then 
dissolved, and solution of carbonate of potash, equivalent to 
9:55 of dry carbonate, was added; the fluid portion was then 
examined for alkali and earth, but showed no traces of either ; 
the carbonate of strontian, when dry, weighed 10°3, and the 
nitrate of potash 14°23: its composition, therefore, is: 


Acid........2....2-. 7°55 or in 100 50:92 
ERAEE siete avetous’ vinlivnié erika ATOS 49-08 


14-77 100-00 


The small loss of water, amounting only to 07, cannot be con- 
sidered otherwise than interposed water, and not in any way 
attached to the formation of the crystal: the composition of 
these salts may be considered as similar, excepting that the 
octahedral variety contains no water of crystallization, and the 
prismatic variety 27-8 per cent, 


ArTICLE XIV. 


On a Submarine Forest in the Frith of Tay, with Observations on 
the Formation of Submarine Forests in General. By John 
Fleming, DD. FRS. Edin.* 


TuE title which I have given to this paper, is, perhaps, faulty , 
and apt to lead the imagination to expect a description of the 
various forms of those sea-weeds which clothe the channel of the 
deep ;—the arrangement of the species, as depending on the soil 
and depth of water, the food which they yield to the various 
creatures that browse upon them,.and the protection they afford 
to such as take refuge among their leaves and branches. Very, 
different, however, is the scene which { propose to describe, it 
being a bed of peat-moss, covered by the sea at every full tide, 
but indicating, by the appearances which it exhibits, that its 
present low level is different from its original position. In other 
words, it is a geological phenomenon, occurring in the Frith of 
Tay, similar to the one observed on the Lincolnshire coast, 
which, in 1796, was examined by the late Sir Joseph Banks and 
Dr. Joseph Correa de Serra, and described by the latter in the 
Transactions of the Royal Society of London for 1799, p. 145, 
under the title, “On a Submarine Forest, on the East Coast of 
England.” I venture to prefix the same title to this paper, 


* From the Transactions of the Royal Society of Edinburgh, vol. ix. Part II, 


1824.] Submarine Forest in the Frith of Tay. 291 


which I now offer to the consideration of the Royal Society of 
Edinburgh, aware of its impropriety, but urged by the wish to 
connect similar phenomena by the common terms employed in 
their description. 

The bed of peat to be described, and now dignified by the 
title of a Submarine Forest, occurs on the south bank of the 
Frith of Tay, and has been observed in detached portions on the 
west side of Flisk Beach, to the extent of nearly three miles, and 
on the east side, upwards of seven miles. At this particular 
place, to which the following observations chiefly apply, it rests 
upon a bed of clay of unknown depth. This clay is of a grey 
colour, much mixed with mica, and in some places with grains 
of quartz, and resembles the carse ground on the opposite side 
of the Frith, or the contents of the sand-banks which obstruct 
its channel. The upper portion of this clay has been penetrated 
by numerous roots, which are now changed into peat, and some 
of them even into iron pyrites. The surface of this bed is hori- 
zontal, and situate nearly on a level with low water-mark. In 
this respect, however, it varies a little in different places. The 
peat-bed occurs immediately above this clay. It consists-of the 
remains of the leaves, stems, and roots, of various common 
plants, of the natural orders Equisetaceew, Graminew, and Cype- 
racer, mixed with roots, leaves, and branches of birch, hazel, 
and probably also alder. Hazel nuts, destitute of kernel, are of 
frequent occurrence. All these vegetable remains are much 
depressed or flattened, where they occur in a horizontal position, 
but, where vertical, they retaim their original rounded’ form. 
The peat can be easily separated into thin layers, the surface of 
each covered with leaves. The lowest portion of this peat is of 
a browner colour than the superior layers; the texture likewise 
is more compact, and the vegetable remains more obliterated. 
The peat contains a good deal of earthy matter. 

The surface of this bed of peat is nowhere (that I ‘have 
detected) covered by any alluvial stratum, nor does it occur at & 
higher level than four or five feet below high water-mark, 
Towards the shore it seems to be cut off by the old red alluvial 
clays on which the newer grey, or carse clay also rests. 

The only circumstance of much interest, in reference to this 
peat-bed, remains to be stated. Upon its surface may be 
perceived the stumps of trees, with the roots attached, and 
evidently occupying the position in which they formerly grew ; 
as the roots are observed to spread, subdivide, and penetrate the 
bed in their usual natural manner. f have counted at one time, 
after a favourable tide had cleared away all silt and gravel from 
the surface, upwards of a score of these roots, situate at unequal 
distances from one another, but all, by the position and arrange- 
ment of their roots, demonstrating that such had been, while 
growing, their original situation. ‘To prevent any suspicion from 
arising, that I may have been — on this subject, [ may 

uU 


292 ; Dr. Fleming on a [APRiL, 


state, that the scene, situate but a few hundred yards from my 
dwelling, has been examined repeatedly, and under different 
circumstances, and several friends who have visited the spot, 
have appeared satisfied of the accuracy of my conclusions. If 
may mention the names of two of these, Mr. Neill and Mr. Bald, 
both members of this Society, and well qualified, by habits of 
observation, to form a correct opinion on the subject. Many 
of these trunks and roots occur from eight to ten feet below high 
water-mark. 

If we assume, therefore, that the roots of these trees are in 
their natural position, with respect to the bed which now sup- 
ports them, are we warranted to conclude that they grew ona 
surface ten feet lower than the high water-mark, but before that 
surface was exposed to the periodical inundations of the tide? 
Every cavity, in this climate, situate at a lower level than that of 
the sea, is invariably filled with water, and in a condition hostile 
to the growth of trees, until its surface has been elevated, by the 
washing in of mud, or the growth of peat, to a position at least 
equal to the ordinary rise of the tide. Since these trees could 
not, therefore, have grown in an inland valley so far below the 
rise of the tide, even where the sea was excluded, we must draw 
the conclusion that. the surface on which these trees grew, was, 
at the period of their growth, at least ten feet higher, in relation 
to the sea, than at present; and to account for this remarkable 
change, we must adopt one of the following suppositions :— 
Either that the sea has risen ten feet, and overflowed that sur- 
face which was formerly beyond its reach; or, that the ground 
supporting these trees has sunk to the same extent. 

The first of these suppositions, viz. a permanent rising of the 
sea, has not been resorted to by amy of those writers whom we 
have had an opportunity of consulting. Indeed it is contrary to 
those known laws which regulate the movements of the ocean, 
and receives no support from any circumstances which have 
been observed on the maritime shores of this country. if 

If, then, we abandon the idea that the sea has gained an 
elevation of its level, and adopt the other supposition, viz. that 
the peat-bed has sunk, so as now to be ten feet lower than when 
the trees grew upon its surface, we advance a step nearer the 
object at which we aim. It still remains, however, to be deter- 
mined, what those causes were, which operated in depressing 
the surface of this bed, and enabling the waves to pass over that 
soil which was formerly so much beyond their influence, as to 
be fit for the support of the hazel and the birch tree. 

The first method of explaining the phenomenon likely to pre- 
sent itself, especially where the bed is limited in extent, is by 
supposing that the substratum, having lost its adhesion to the 
bed on which it rested, by the percolation of water, and the 
exposure of the side next the sea, moved down an inclined 
plane into deep water, carrying along with it the upper layer 


1824.) Submarine Forest in the Frith of Tay. 293 
of vegetable matter, and the trees growing upon its surface. 
Such occurrences have taken place in several inland bogs, both 
in Scotland and Ireland, which have moved out of their posi- 
tions to a lower level. The extent, however, of this bed, and 
the horizontality of its layers, prevent us from considering its 
present depressed position as having been produced by any 
sliding of this kind. Neither hath it arisen from the washing 
away of the soft matter on which the bed supporting the trees 
rested, for the clay still remains, and at the line of junction is 
much incorporated with the peat. 

This washing away of the subsoil, however, has been resorted 
to by Mr. Watt of Skail, to explain the conditions of a sub- 
marine forest on the west coast of Orkney. It occurred to him 
“ that this bed of moss and trees has arrived at its present level 
(so as to be covered, during the flood-tide, to the depth of at 
least fifteen feet of water), in consequence of the removal of a 
bank of earth, at least eighteen feet deep, which has been 
washed gradually away, by the water of the Loch of Skaill 
oozing along the rocks upon which it rested, and upon which 
the mass of leaves now rests, held together by the fibres of the 
roots of the trees.” See Edinb. Phil. Jour., vol. iii. p. 101. 
This explanation, however, is liable to very strong objections. 
It is not probable, that, on the stormy coast of the west side 
of Orkney, where the rocks themselves yield to the fury of the 
waves, and where the top of every cliff is a heap of ruins, a 
mass of earth, eighteen feet in thickness, would be permitted 
to remain, until washed away by the slow force of percolating 
fresh water, or that a continuous bed of peat, of nearly an acre 
in extent, would be spared from destruction, and suffered to 
settle peacefully, in the Bay of Skaill, so as to be covered at 
flood-tide with fifteen feet of water. 

If we have no reason to believe that this Tay-bed was trans- 

orted to its present situation, in what manner has it reached 
its present level? Two solutions of this curious question have 
been offered, as connected with similar occurrences, by eminent 
individuals, Dr. Borlase, Dr. J. Correa de Serra, and Professor 
Playfair. 

r. Borlase, who, in 1757, observed a submarine forest at 
Mount’s Bay, Cornwall, covered at full tide with twelve feet 
of water, considered the depression of the bed, which supported 
the trees, and still contained their roots in sttu, as having 
arisen from subsidence of the ground, produced by earth- 
quakes, or, to state it in his own words, “ that there has been 
a subsidence of the sea-shore hereabouts, is hinted in my 
letter to you, p. 92; and the different levels and tendencies 
which we observed in the positions of the trees we found, 
afford us some material inferences as to the degree and ine- 
qualities of such subsidences in general; as the age in which 


204 al Dr. Fleming on a fAprit, 


this subsidence happened (near 1000 years since at least), may | 


convince us, that when earthquakes happen, it is well for the 
country that they are attended with subsidences,; for then the 
ground settles, and the inflammable matter, which occasioned 
the earthquake, has no longer room to spread, unite and recruit 
its forces, so as to create frequent and subsequent earthquakes ; 
whereas, where there are earthquakes without proportional 
subsidences, there the caverns and ducts under ground remain- 
ing open and unchoaked, the same cause which occasioned 
the first has room to revive, and renew its struggles, and to 
repeat its desolations and terrors; which is most probably the 
case of Lisbon.” Phil. Trans. 1757, p. 52. 

The views of Dr. Borlase, in reference to this depression of 
the ground, in consequence of earthquakes, was evidently in- 
fluenced by the curious observations which he had former! 
made on the subsidence of some places at the Scilly Islands, 
as stated, Phil. Trans. vol. xlvii. p. 62; and other observers 
may be led to form the same opinion, especially if the singular 
sinking of the cliff at Folkstone, about forty feet, even in the 
absence of an earthquake, be taken in consideration, See 
Phil. Trans. 1786, p. 220. 

Dr. Correa de Serra also ascribes the depressed position of 
the submarine forest of Lincolnshire to the force of subsidence, 
aided by the sudden action of earthquakes. ‘ There is a force 
of subsidence (he says) (particularly in soft ground), which, 
being a natural consequence of grayity, slowly, though per- 
petually operating, has its action sometimes quickened and 
rendered sudden by extraneous causes, for instance, by earth- 
quakes.” ‘ This force of subsidence, suddenly acting by means 
of some earthquake, seems to me the most probable cause to 
which the actual submarine situation of the forest we are speak- 
ing of may be ascribed. It affords a simple easy explanation 
of the matter; its probability is supported by numberless in- 
stances of similar events.” Phil. Trans. 1799. 

Professor Playfair, when contemplating the phenomena of 
the Lincolnshire submarine forest, rejected the explanation 
offered by Dr. Correa de Serra, and availed himself of some of 
the peculiar assumptions of the Huttonian Theory of the Earth. 
“The subsidence (he says) however, is not here understood 
to arise from the mere yielding of some of the strata imme- 
diately underneath, but 1s conceived to be a part of that geolo- 
gical system of alternate depression and eleyation of the surface, 
which probably extends to the whole mineral kingdom, To 
reconcile all the different facts, I should be tempted to think, 
that the forest. which once covered Lincolnshire, was immersed 
under the sea by the subsidence of the land to a great depth, 
and at a period ,considerably remote ; that when so immersed, 
it was covered over with the bed of clay which now lies upon 


pliant inane nme Leal 


1824.]\. Submarine Forest in the Frith of Tay. 295 


it, by deposition from the sea, and the washing down of earth 
from the land ; that it has emerged from this great depth till a 
part of it has become dry land; but that it is now sinking 
again, if the tradition of the country deserves any credit; that 
the part of it in the sea is deeper under water at present than 
it was a few years ago.” Illustrations of the Huttonian Theory, 

. 453. : 

4 A careful examination of these conjectures, which had been 
offered to account for the phenomena of submarine forests, soon 
convinced me that the subject was still imperfectly understood. 
Under this impression, I endeavdétred to become possessed of 
all the conditions of the problem}#and now venture to offer a 
solution. The opinion which I havé been led to form has been 
entertained for some years, and stated to several friends, with- 
out an objection having presented itself. 

If we suppose a lake situate near the sea-shore, and haying 
its outlet elevated a few feet above the rise of the tide, we 
have the first condition requisite for the production of a sub- 
marine forest. 

If we now suppose, that, by means of mud carried in by 
rivulets, and the growth of aquatic plants, this lake has become 
a marsh, and a stratum of vegetable matter formed on the 
surface, of sufficient density to support trees, we arrive at the 
second condition which is requisite. This state of a marsh, 
formerly a lake, is of common occurrence, more especially 
where the surrounding crounds are high, and covered with soil, 
for in this case the rain washes down earthy particles, and, by 
spreading them on the grassy surface, renders it a more suitable 
soil for the growth of trees. 

Tn this second condition, all the strata below the outlet of 
the marsh are kept constantly wet, or in a semifluid state. The 
force of ordinary subsidence, aided by occasional earthquakes, 
may render the whole tolerably compact; yet the quantity of 
water necessarily present, will prevent any thing like the degree 
ys condensation of ordinary alluvial land or soil from taking 

ace. 

A Suppose a marsh in this condition to have the level of its 
outlet lowered, or rather, to have its seaward barrier removed 
(an occurrence which many circumstances induce us to believe 
to have happened frequently both on the east and west coasts 
of this country, where submarine forests are not of rare occur- 
rence), what consequences would follow? The extremities of 
the strata now exposed to the sea, would at every ebb-tide be 
left dry, to a depth equal to the fall of the tide. Much water, 
formerly prevented from escaping by the altitude of the outlet, 
would now ooze out from the moist beds, and the subsiding 
force would act more powerfully in the absence of the water 
which filled every pore. All the strata above low water-mark 


296 Dr. Fleming ona > [Aprit, 


would thus collapse, and the surface of the marsh, instead of 
remaining at its original height, would sink below the level of 
the sea. But the escape of the water from the strata would 
not, in such circumstances, be confined to the beds situate 
above the low water-line. Even those occupying a position 
considerably lower, would be influenced by the change ; for 
the water even in such would be squeezed out, in consequence 
of the pressure of all the matter of the strata above the low 
water-mark, exerted during every ebb, in the expulsion of the 
water at the lowest level, thus permitting the subsidence of the 
strata to take place even to the lowest beds of the morass. 

In consequence of this drainage, produced by the ebbing of 
the tide on those marshes, the original barriers of which have 
been destroyed, there is no difficulty in accounting for the de- 
pression of the surface of a marsh many feet lower than its 
original level, nor in explaining the fact that Neptune now tri- 
umphs where Sylvanus reigned, and that the sprightly Nereids 
now occupy the dwellings of their sister Naids. 

The same explanation, now offered to account for the sub- 
marine forest of the Tay, seems equally applicable to those of 
Mount’s Bay, Laneciaehace and Orkney. It is warranted by 
the effects which we have observed to have taken place in dif- 
ferent districts of Scotland, from the artificial drainage of 
marshes which had formerly been lakes, and which were in a 
condition of surface fit for the growth both of willows and 
alders. In some cases, where the outlet of the marsh has been 
lowered perhaps ten feet, and a ditch at this new level opened 
through the middle of the ground, an expectation has been 
formed. that the original surface would be drained of all its 
moisture, and brought into an arable condition. A season, 
however, has scarcely elapsed, before this deep ditch has be- 
come shallow, not by the silting up of the bottom, but by the 
subsidence of the neighbouring matter, in consequence of the 
abstraction of the water; and the ground which was expected 
to become fit for yielding crops of grain, has returned to a 
condition better suited to the growth of rushes. No provision 
in these cases had been made for the effect of subsidence. 

Before concluding this paper, I may take notice of a few 
facts which seem to have some interest in a geological point 
of view. 

1. One effect of the subsidence to which I have here alluded, 
is the complanation of all the vegetable remains which occur 
in a horizontal position, or parallel with the surface of the bed 
of peat; while those situate vertically retain their cylindrical 
shape. The vegetable remains, so common in the strata accom- 
panying coal in this country, exhibit the same appearances in 
similar circumstances, and lead to the conclusion, that the 
matter of the strata, at the period of deposition, was in such a 


1824.) Submarine Forest in the Frith of Tay. 297 


condition as to admit of the mechanical effects of subsidence 
taking place. 

2. In the examination of the vegetable remains in this bed 
of peat, and of others which have been investigated, I have 
been led to conclude (contrary to the commonly received opi- 
nion *), that many of the supposed stems of reeds which occur 
in a petrified state, are in fact roots. These roots, or rather 
subterranean stems, such as the Arundo colorata and phrag- 
mites, Menyanthes trifoltata, and many other marsh plants 
exhibit, frequently occur in beds of peat, in a dead state, and 
exhibit their peculiar characters, when but few traces of the 
stems to which they belonged can be detected. 

3. Several changes of a chemical kind have already taken 
place in this stratum of peat. The fibrous structure of much of 
the vegetable matter is obliterated, small portions of the reeds, 
and even of the wood, are so changed as to resemble wood- 
coal ;—changes these, which plainly intimate, that a process is 
going on, by which, in time, that which is now peat may be- 
come coal. In the crevices of some portions of the wood I 
have detected thin crusts of the blue phosphate of iron, It is 
rather singular to have found some of the roots in the soft clay 
changed into iron-pyrites. This change has chiefly taken place 
in the bark, and in such cases the wood and pith are wanting. 
In one example, however, the pith remained, and had likewise 
been converted into pyrites. In many cases the clay is full of 
tubular cavities, the remains of the spaces which the roots or 
stems of plants once occupied. The walls of these cavities are 
usually off a darker colour, and firmer texture, than the sur- 
rounding matter, and have evidently undergone some change, 
in consequence of the decomposition of the vegetable matter. 
In some cases, the epidermis of the plant remains, in contact 
with the surrounding clay, while the matter of the interior has 
disappeared. Into these cavities the clayey matter enters 
slowly, and fills the mould which the decomposition of the 
plant has prepared. This may be regarded as a process similar 
to the one which has taken place in those vegetable petrifac- 
tions so common in the argillaceous and arenaceous beds 
of the coal-formation, in which slate-clay, clay-ironstone and 
sandstone, are exhibited under the external forms of plants. 


* See Parkinson's Organic Remains, vol. i. p. 455. 


298 Analyses of Books. [ApriL, 


ARTICLE XV. 


ANALYSES OF Books. 


Philosophical Transactions of the Royal Society of London, for 
f 1823. Part LL. a oo 


(Concluded from p. 229.) 


XXVI. On the Apparent Magnetism of Metallic Titanium. 
By William Hyde Wollaston, MD. VPRS. 

This brief but interesting communication is as follows :— 

“ In an account that I lately gave of the properties of metallic 
titanium, which is printed in the first part of the volume of the 
Philosophical Transactions forthe present year,* there is an over- 
sight, which I am desirous of rectifying as soon as may be. I 
have there stated that the cubic crystals of titanium, when first 
detached from the iron-slag where they are found, were all 
attracted by a magnet, but that when they had been freed from 
all particles of iron adherent to them, they appeared to be no 
longer acted upon by it. 

“‘ Having since that time been led by the observations of M. 
Peschier, of Geneva, to examine this question more accurately, 
I find that, although the crystals are not sufficiently attractile to 
be wholly supported by the magnet, yet when a crystal is sup- 
ported by a fine thread, the force of attraction is sufficient to 
draw it about 20° from the perpendicular, and consequently that 
the force of attraction is equal to about one-third the weight of 
the metal. 

“ When a piece of soft iron of about the same size was made 
of a cubic form (weighing half a grain), the attractive force of 
the iron to the same magnet-was found, in successive trials, to 
lift from eighty to ninety times its weight of a silver chain 
adapted to this inquiry. 

“ Bya similar mode of trial, I found that cobalt carried from 
fifty to sixty times its weight, and that a similar quantity of 
nickel supported from twenty to thirty times its own weight by 
the same magnet. 

“ From the above comparison of the magnetic forces, it is 
evident that the presence of about 1-250th part of iron as an 
alloy in the metallic titanium, would be sufficient to account for 
this power, without regarding titanium itself as a magnetic 
metal; and its origin in the midst of iron, gives every reason to 
suspect that it would be contaminated by some proportion of 
that metal. 

“Tt is, however, extremely difficult really to detect the pre- 
sence of so small a proportion of iron, on account of the high 
colour of the precipitates of titanium. For though it may be. 


* Annals, N.S. y. 67, vi, 222. 


1824.] Philosophical Tranactions for 1823, Part Il. 299 


easy to produce an appearance of blue by using a prussiate, 
which already contains iron, and is consequently better adapted 
to prove the absence of iron where no blueness appears, than to 
ascertain its presence, it is by no means easy to obtain the more 
indisputable evidence of iron by infusion of galls. It is only by 
repeated evaporation of the muriatic solution, and continued 
exposure of the residuum to the temperature of boiling water, 
that I have succeeded in separating enough of the titanium to 
allow the blackness of gallate of iron to appear, when the efflo- 
rescent edges of the dried salt are touched with infusion of galls. 

“ Although the quantity thus rendered sensible does not 
appear in proportion sufficient to account for the magneti¢ force 
observed, there seems more reason to ascribe it to this impurity, 
than to suppose titanium possessed of that peculiar property in 
a degree so far inferior to the other known magnetic metals.” 

XXVII. An Account of the Iffect of Mercurial Vapours on 
the Crew of his Majesty’s Ship Triumph, in the Year 1810. By 
William Burnett, MD. one of the Medical Commissioners of the 
Navy, formerly Physician and Inspector of Hospitals to the 
Mediterranean Fleet. Communicated by Matthew Baillie, MD. 
FRS. 

The curious facts to which this paper relates, having already 
been detailed by Dr. Paris and Mr. Fonblanque, intheir “ Me- 
dical Jurisprudence,” vol. ii. p. 460, and the paper itself having 
been reprinted in a contemporary journal, their repetition here 
is unnecessary. 

XXVIII. On the Astronomical Refractions, By J. Ivory, 
AM, FRS. 

We have endeavoured, in the following paragraphs, to convey 
a general idea of the nature and contents of this voluminous and 
elaborate communication, necessarily omitting the author’s 
mathematical details, but adopting, for the most part, his own 
words, 

It was known to the ancient astronomers that there is a dif- 
ference between the real and apparent places of the stars, arising 
from the refraction of light in its passage through the atmo- 
sphere. Tycho Brahé was the first who attempted to free his 
obseryations from the effect of this irregularity, Since his 
time the astronomical refraction has become more and more an 
object of attention, as it is found to have the greatest influence 
on the delicate exactness of modern observations. In the course 
of the last twenty years many researches on this subject have 
been published by philosophers of the first note, who have 
applied all the resources both of theory and practice to over- 
come the difficulties which it presents. By these means our 
knowledge has been greatly extended; but the problem of the 
refractions must still be considered as the most imperfect part 
of modern astronomy. 

The first investigation that presents itself in the problem of 


300 Analyses of Books. -[APRIL, 


the refractions is to find the velocity of the light at any given’ 
height in the atmosphere. The only physical principle wanted 
for this purpose is the refractive power of air according to its 
density. Hauksbee first determined by experiment, that air 
refracts light in proportion to its density ; and this result has 
been confirmed by succeeding philosopheis. There is even good 
reason to think that the conclusion of Hauksbee is not mate- 
rially affected by the variable quantities of aqueous vapour con- 
tained in the atmosphere at different times. Admitting then the 
principle we have mentioned, we must conceive that the light 
coming from the sun or from a star, moves in vacuo with a 
uniform velocity until it reaches the atmosphere. It is there 
deflected from its course by the spherical and concentric shells 
of air it meets with, each of which acts upon it with a force per- 
pendicular to its surface, and directed to the centre of the earth. 
Now, asallthe light enters the atmosphere with the same velocity, 
and as the deflecting forces are cf the same intensity at the same 
distance from the common centre to which they tend; it follows, 
that the new velocities acquired by the action of the forces will 
be independent of the direction of the light’s motion, and will 
be the same at the same distance above the earth’s surface. 

The ultimate deviation of the light of a star from its primitive 
direction depends upon the augmentation of the velocity which 
the light acquires in its passage through the atmosphere, and 
likewise upon the different obliquities with which it crosses the 
several strata of air. Now the first of these two things is the 
same for all stars and for all constitutions of the atmosphere, for 
it is the same when the density of the lowest stratum of air con- 
tinuesthe same. But the second is different for stars, that are 
differently placed with regard to the zenith, and it varies also 
with the densities of the strata that compose the atmosphere. 
Itis, therefore, certain, that the formula of Laplace is rigorously 
exact in no case whatever. But when a star is near the zenith, 
the variations in the obliquity of the light in passing through the 
several strata of air, are inconsiderable ; and the formula will be 
nearly true. However, there is always some error, which accu- 
mulates as the zenith distance increases, and will at length 
become sensible. Delambre tells us, that in comparing the 
observations of different days, he found errors arising from 
refraction that amounted to 6” or 7” at 75° from the zenith; and 
the observations of a very accurate astronomer show that similar 
inequalities are perceptible much nearer the zenith ( Dr. Brinkley’s 
paper Phil. Trans. 1821, p. 342). Now these inequalities do not 
arise from any thing imperfect in the manner of observing: they 
are undoubtedly produced by alterations in the remote parts of 
the atmosphere which do not affect the barometer or thermome- 
ter placed at the observatory. It appears, therefore, that the 

eculiar constitution of the atmosphere has a perceptible 
influence on the refraction at 75° from the zenith ; and when 


1824.] Philosophical Transactions for 1823, Part Il. 301 


Laplace’s formula is made to extend to 74°, itis carried to its 
utmost limit. However mutable we may suppose the condition 
of the atmosphere to be, there must be a mean state equally 
removed from the opposite extremes. Now, a table of refrac- 
tions that should have this mean state of the atmosphere for its 
basis would be the most advantageous of any. For although, 
with respect to single observations, the errors of such a table 
might be as great as in some other hypotheses, yet in a nume- 
rous set of observations made at different times so as to embrace 
all the usual changes, the inequalities of an opposite kind would 
counterbalance one another. But toa certain distance from the 
zenith, Laplace’s formula is sufficiently exact for practical pur- 
poses ; and it has the advantage of taking away the necessity of 
having recourse to precarious suppositions respecting the consti- 
tion of the atmosphere. 

There is no ground in experience for attributing to the grada- 
tion of heat in the atmosphere any other law than that of an 
equable decrease as the altitude increases. This law prevails to 
the greatest heights to which we have been able to ascend. The 
mean elevation for one degree of depression of the centigrade 
thermometer is very nearly 90 English fathoms ; and in the 
height ascended by Gay-Lussac, rather more than 4} miles, the 
same quantity comes out equal to 95 fathoms. To this great 
extent the law of a uniform decrease of temperature holds good 
without much deviation from the truth. It therefore seems to 
be the assumption most likely to guide us aright in approximat- 
ing to the true constitution of the atmosphere. The very exact 
coincidence in the properties of all the atmospheres compre- 
hended in the formula assumed by Mr. Ivory, with the pheno- 
mena actually observed at the surface of the earth, accounts in a 
satisfactory manner for the near approach of the refractions in 
every case to the quantities determined by astronomers. It 
appears that although the refractions near the zenith are affected 
in a degree hardly perceptible by the peculiar constitution of the 
atmosphere, yet near the horizon they depend upon the same 
arrangement of the strata of air indicated by terrestrial experi- 
ments. The causes in the irregularities observable in these last, 
likewise disturb the celestial pheenomenon in a more remarkable 
manner. In measuring the height of a column of air, the acci- 
dental disturbances to which the atmosphere is continually sub- 
ject, are in some measure corrected by means of the tempera- 
tures observed at both extremities of the column; but in 
computing the refractions, the astronomer has no guide but the 
thermometer placed in his observatory. In the remote parts of 
the atmosphere, there may occur innumerable changes deflecting 
the light of a star from its proper course, of which he has no 
intimation, and for which he can make no allowance. In com- 
parison of this great source of error, we may reckon as of small 


302 Analyses of Books. i [Aprit, 


account the inacciitacies that are owing to the neglect of 
moisture diffused in the atmosphere, or to our want of an exact 
knowledge of the law of density in regard to temperature. There 
can hardly be any other remedy than that of which astronomers 
so often avail themselves, whenever an ignorance of the real 
causes obliges them to assimilate the phenomena to the effect of 
chance; namely, to multiply observations in different circum- 
stances, with the view of making the inequalities of an opposite 
description compensate one another. . 

From the foregoing discussion we may draw this conclusion : 
that an atmosphere constituted like that of the earth must have 
an altitude of at least 25 miles in order that the refractions from 
the zenith to the horizon be such as they are actually observed 
tobe But an atmosphere agreeing with nature in the quantity of 
the refractions may be found, that shall have any proposed alti- 
tude greater than the minimum quantity ; and we may infer from 
the duration of twilight, that the atmosphere of the earth must 
have an altitude equal to 50 miles, or even more. 

XXIX. Observations on Air found in the Pleura, in a Case of 
Pneumato-thorax ; with Experiments on the Abscrption of different 
Kinds of Air introduced into the Pleura. By John Davy, MD. 
FRS. 

A brief abstract of this paper will be found in our report of the 
proceedings of the Royal Society, in the Annals for July, 1828. 
Dr. Davy has added, in an Appendix, an account of a case of 
pneumato-thorax, in which the operation of tapping the chest 
was performed ; with some additional observations on air found 
within the body ; and on the power of mucous membranes to 
absorb air. The air collected in this case, by tapping the chest, 
consisted of 93 azotic gas, and 7 carbonic acid gas; thus, in 
composition, proving almost exactly the same as the air found 
in the fatal case described in the Paper itself. Various facts are 
adduced, tending to support the idea, that mucous membranes. 
are capable of absorbing air. 

XXX. On Bitumen in Stones. By the Right Hon. George 
Knox, FRS. 

The results of the experiments detailed by Mr. Knox in this 
paper, possess considerable interest, particularly as indicating 
the propriety of instituting further researches on the subject; 
and of examining stony substances for bitumen when they are 
submitted to analysis: we therefore subjoin them, in a tabular 
form. . 


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1824.] Proceedings of Philosophical Societies, 305 


* XXXI. On certain Changes which appear to have taken place 
in the Position of some of the principal Fixed Stars. By John 
~ Pond, Esq. Astronomer Royal, FRS. : 

This communication chiefly consists of a series of tables of 
observations on the stars; confirming, in Mr. Pond’s’judgment, 
his doctrine of their southern motion.—B. 


ArtIcLE XVI. 
Proceedings of Philosophical Societies. 
ROYAL SOCIETY. 


Feb. 19.—A Series of Meteorological and Astronomical 
Observations made in New South Wales, and on the Voyage to 
that Country, were presented from Major-Gen. Sir T. Brisbane, 
KCB. FRS. 

A paper was read, “ On the Semi-decussation of the Optic 
Nerves ; by W. H. Wollaston, MD. VPRS.” 

It has been generally concluded by anatomists, and they sup- 
port the conclusion from the observation of the arrangement of 
the optic nerves as distinctly seen in certain kinds of fishes, that 
in the human eye, the optic nerves, after passing from the 
thalami nervorum opticorum, meet, and then proceed appa- 
rently in union, though in reality still separate; so that the 
right eye is believed to be entirely supplied with these nerves 
from the left thalamus, and the left eye from the right thalamus : 
and this arrangement is called the decussation of the optic nerves. 
The consideration of a particular species of blindness, however, 
has led Dr. Wollaston to a somewhat different distribution of the 
optic nerves. After fatigue, arising from four or five hours’ 
violent exercise, Dr. Wollaston was affected by a partial blind- 
ness, of which he first became sensible by seeing only half the 
face of a person near him, and next by seeing only the termina- 
tion “son” of the name “ Johnson; ” this blindness was to the 
left of the point of vision in each eye; it was not perfect dark- 
ness, but merely a dark shade ; and in about fifteen minutes, it 

adually passed off, in an oblique direction upwards towards the 
eft. As it was referable to an affection of the nerves, Dr. W. 
did not apprehend or experience any return of it, other nervous 
affections being produced by fatigue. Some years afterwards 
he again experienced this singular kind of blindness, without 
any obvious cause, and first became sensible of it likewise by 
seeing only the half of a person’s face ; but in this case the right 
side of both eyes was affected, and complete vision was suddenly 
restored by the joy produced on receiving information of the safe 
arrival of a friend from a hazardous enterprise. Dr. Wollaston 
has a friend who has experienced the same affection for seven- 

New Series, vow. vit. x 


306 Proceedings of Philosophical Societies. [APRIL, 


teen years past, whenever his stomach is considerably deranged : 
another friend was attacked by pain at the left temple, and at 
the back of the left eye, which was succeeded by this sort of 
blindness on the right side of each eye; he can see to write,— 
see the paper le is writing upon, and the pen he writes with,— 
but not the hand that guides the pen. The affection in this 
case, Dr. W. fears, is a permanent one; the pain first expe- 
rienced seems to have arisen from some effusion causing a 
degree of pressure on the brain, and the blindness from the 
continuance of this pressure on the left thalamus nervorum 
opticorum. 

Now all these cases seem referable to the partial insensibility 
of each retina, and they indicate that the left side of the retina 
in each eye is supplied with nerves from the same thalamus, and 
the right from the opposite thalamus; so that the nerves supplying 
the former alone decussate, and not those of the right side; an 
arrangement which Dr. Wollaston calls the semi-decussation of 
the oplic nerves. 

Dr. Wollaston proceeded to illustrate this statement of the 
distribution of the optic nerves, from that observed in those of 
fishes ; in the sturgeon the eyes are diametrically opposite each 
other, each on one side of the head, the left eye being entirely 
supplied with nerves from the left thalamus of the brain, and the 
right eye entirely from the right thalamus. The blindness above 
described, Dr. W. remarked, does not appear to be rare, but is 
seldom particularly noticed, like many other things, because it 
is not understood. 

This very interesting paper concluded with a short section in 
which Dr. Wollaston applies the sympathy of structure in the 
eyes, indicated by the effects just noticed, to the explanation of 
the long agitated question respecting the cause of single vision 
with two eyes. Every point in each eye is supplied with a pair 
of filaments from the same nerve, and the two eyes thus sympa- 
thize with each other in every point: hence arises single vision ; 
and hence also the reason why infants direct both eyes in a 
corresponding direction, instead of squinting. 

Feb. 26.—A Catalogue was presented from the Rev. Fearon 
Fallows, FRS. Astronomer at the Cape of Good Hope, of nearly 
all the principal Fixed Stars between the zenith of Cape Town, 
Cape of Good Hope, and the South Pole. 

A paper was read, “ On the various Degrees of Intensity of 
the local Magnetic Attraction in different Parts of Ships; by 
George Harvey, MAS. Communicated by John Barrow, Esq. 
FRS. Secretary to the Admiralty.” . 

March 4,—William Wavell, MD. and Capt. Philip Parker 
King, RN. were admitted Fellows of the Society; the Lord 
Bishop of Limerick, and the Rev. Dr. E. Maltby, Prébendaty of 
Lincoln, being unable to attend for admission, requested to have 
their names inserted in the printed lists of the Society, which 
was granted accordingly. wie 


1824,] Royal Society. 307 


A letter to the President was read, from Sir E. Home, Bart. 
VPRS. entitled “Some curious Facts respecting the Walrus 
and Seal, discovered in the Examination of Specimens brought 
Home by the late Expeditions, from the Polar Circle.” 

As the late various expeditions to the northern regions had 
been planned, primarily, by the President and Council of the 
Royal Society, Sir Everard Home wished to lay before the 
Society some curious facts which he had ascertained in the 
examination of some specimens brought home by them. This 
he was desirous of doing before the officers who are to proceed 
on the new expeditions should have left our coasts, in order that 
they might know that their exertions were important to science 
in various respects, besides the grand objects of their 
researches ; and that they might likewise know that the pickle or 
brine in which provisions are preserved at sea is well adapted 
to the preservation of the internal parts of animals, preserving 
them in a better state for examination, dissection, and injection, 
than when they have been long steeped in spirits. 

The first discovery Sir Everard had to state was, that the 
hind flipper or foot of the walrus is provided with means for 
enabling the animal to walk in opposition to gravity precisely 
analogous to those possessed by the fly, and the use of which 
could not have been suspected, had not the previous discovery 
been made respecting the latter animal, as described in the 
Phil. Trans. for 1816. Sir Everard at once recognized this 
structure on seeing a mutilated foot of the walrus, and, in con- 
sequence, had requested his friend Capt. Sabine to procure him 
a specimen of the animal, which Capt. 8. had accordingly 
done, with the aid of the assistant-surgeon of the vessel in 
which he sailed.. The examination of this specimen showed, 
that in the hind foot of the walrus there is a cup for enabling 
the animal to produce a vacuum, and thus to walk in opposition 
to gravity exactly likethe two cups with which the fly’s foot is pro- 
vided. The apparatus in the latter required magnifying 100 times 
to make the cups distinctly visible, but in the walrus it was dimi- 
nished fourtimes to bring it within the compass of a quarto plate. 
The author, when writing his former papers on the fly’s means 
of progression, had not been able to determine the use of the 
two points in the foot of that animal; Mr. Adams had called 
them pickers, and had supposed that they were inserted in the 
cavities of the surface over which the animal was walking, and 
thus retained it in opposition to gravity,—an opinion which 
Sir Everard Home deemed undeserving of consideration ; 
though he could not assign any use to the points in question. 
In the foot of the walrus, however, it is evident that the two 
toes which answer to the points in that of the fly are used for the 
purpose of bringing the web closely down upon the surface 
traversed, so as to enable the animal to form a more perfect 
vacuum, and that the air is re-admitted on their being lifted up. 

x 2 


308 = Proceedings of Philosophical Societies. [ApRiL, 


This part of the paper was illustrated by a drawing by Mr. 
Bauer; and it was singular, Sir Everard observed, that that 
gentleman should have had to delineate the same organ in two 
such different animals, . 

The second fact described in this paper also relates to the 
walrus. The bile in this animal is received from the liver by a late- 
ral communication into a cylindrical reservoir, with much mucus 
in its coats, and is thence impelled with considerable force into 
the duodenum. The cesophagus is wide, admitting oflarge masses 
of food being swallowed, and of regurgitation: the opening 
of the pylorus is small and valvular, preventing the passage of 
its contents back again into the duodenum: the structure of the 
duodenum, pylorus, and adjacent organs, is very similar to that 
of those of the seal. It had been observed by Mr. Fisher, the 
astronomer to the late expedition under Capt. Parry, that the 
food of the walrus is the fucus digitatus, which is found in 
great abundance in the Arctic seas, thrown up on the shores 
by the waves, and also beneath the ice. 

The third fact to which Sir Everard Home adverted in this 
communication relates to the structure ofthe funis and placenta 
of the seal, as observed in a specimen of those parts brought 
home by Lieut. Griffiths, one of the officers in the late expedition 
under Capt. Parry. The vessels composing the former are not 
twisted, and are about nine inches long; at the distance of three 
inches from the placenta, they anastomoze into blood-vessels, 
which are connected with the placenta by three membranous 
coats; the whole conformation giving great freedom to the 
embryonic circulation. Drawings of this subject and that last 
noticed, made by Mr. Rose, a pupil under the author at St. 
George’s Hospital, were annexed to the paper. 

A communication was likewise read, entitled “‘ Some further 
Particulars. of a Case of Pneumato-thorax; by J. Davy, MD. 
FRS.” Of this we shall give an account in our next. 


ASTRONOMICAL SOCIETY. 


Feb.13.—This day being the fourth anniversary of the Society, 
a numerous meeting of the members took place at the apart- 
ments in Lincoln’s Inn Fields; when a very satisfactory report 
upon the state of the Society’s affairs and proceedings during 
the last year was read, and ordered to be printed. This report 
paid a due tribute of respect to several members whom the 
Society has lost by death in the last year, and particularly to 
Col. W. Lambton, of Madras, and Dr. Walbeck of the Observa- 
tory at Abo. It gives a succinct account of the measurement 
of the largest continuous arc of a meridian yet effected, which 
en the former gentleman upwards of twenty years in 
ndia. 

The Chairman (Mr. Colebrooke) then proceeded to distribute 
the honorary rewards of the Society, viz, the Society’s gold 
medal to Charles Babbage, Esq. FRS. as a token of the high 


1824.] Geological Society. 309 


estimation in which it holds his valuable invention of an engine 
for calculating mathematical and astronomical tables, being the 
first medal awarded by the Society. A similar gold medal to 
Prof. J. F. Encke, Director of the Observatory at Seeberg, in 
Gotha, for his investigations relative to the comet which bears 
his name, and which led to the rediscovery of it in 1822. The 
silver medal of the Society to Prof. Charles Rumker for the 
rediscovery of Encke’s comet, and a similar medal to M. Jean 
Louis Pons, of La Marlia, in Italy, for the discovery of two 
comets on the 3lst of May and loth July, 1822, and for his 
indefatigable assiduity in that department of astronomy. The 
chairman prefaced the presentation of each medal by a most 
eloquent, learned, and interesting address of considerable length, 
all of which were delivered in the most impressive manner. They 
were replete with information on the successive improvements 
in machinery for assisting calculation, as well as on cometary 
astronomy, and we were happy to find, that in consequence of a 
motion made by Davies Gilbert, Esq. MP. and seconded by 
John Fuller, Esq. they will be printed for circulation among the 
members. 

The election for the Officers and Council of the Society for 
the ensuing year thea took place, when the following appeared 
to be the unanimous choice of the meeting, viz. :-— 

President.—H. T. Colebrooke, Esq. FRSL. and E. and FLS. 

Vice- Presidents —C. Babbage, Esq. MA. FRSL. and E.; 
FP. Baily, Esq. FRS. and LS.; Sir B. Hobhouse, Bart. FRS.; 
and The Right Hon. George Karl of Macclestield, FRS. 

Treasurer.—Rey. W, Pearson, LLD. FRS. 

Secretaries —O. G. Gregory, LLD. Prof. Math. Roy. Mil 
Acad. Woolwich; J. Millington, Esq. FLS. Prof. Mech. Philos. 
Royal Institution. 

Foreign Secretary.—J. F. W. Herschel, Esq. MA. FRSL. 
and E. 

Council.—Major T. Colby, Roy. Eng. LLD. FRSL. and E. ; 
G. Dollond, Esq. FRS.; Bryan Donkin, Esq.; Capt. J. Frank- 
lin, RN. FRS.; D. Gilbert, Esq. MP. VPRS. FLS.; B. Gom- 
pertz, Esq. FRS.; S. Groombridge, Esq. FRS.; and D. Moore, 
Esq. FRS. SA. and LS. 

Several new members and associates were nominated, and the 
greater part of the Society adjourned to Freemasons’ Tavern, 
where a dinner was provided. 


GEOLOGICAL SOCIETY. 

Dec. 19, 1823.—A paper was read, containing Geological 
Observations collected on a Journey through Persia from Bush- 
eae the Persian Gulph to Teheran ; by James B. Fraser, Esq. 
MGS. 

The author is of opinion that both the east and west sides of 
the Persian Gulph to a great extent, consist of a calcareous 


310 Proceedings of Philosophical Societies. [APpRiL, 


formation, which, it is ascertained, in many parts continues far 
inland. In a part of this formation, his route from Bushire com- 
menced; between which place and Shiraz, the hills are composed 
of sulphates and carbonates of lime, and the strata often much 
disturbed. Through a large tract of this country, carbonate of 
lime is intermixed with the gypsum, but in parts, rocks of pure 

ypsum occur, and very frequently accompanied by salt. 
Streams and lakes of salt abound, and there is a considerable 
one of the latter at Shiraz. Proceeding northward, the route 
from Shiraz to Ispahan, a distance of about 250 miles, lies over 
an elevated country, the nature of which is similar to that before 
described, but the carbonate of lime predominates. Between 
the village of Gendoo and the town of Yes-dikhaust, Mr. Fraser 
found clay slate, and a conglomerate rock inclosing pebbles of 
quartz, greenstone, and limestone, cemented by carbonate of 
lime; strata of this aggregate rock alternate with a finer sand- 
stone. The mountains between Ispahan and Teheran are of a 
character very different from the preceding ; among them clay 
slate was observed, andthe highest region, which reaches a great 
elevation, consists of granitic rocks. 

Jan. 2, 1824.—A paper was read “On the Geological Struc- 
ture of St. Jago, one of the Cape de Verd Islands; by Major 
Colebrooke.” 

From the observations of the author, and the accompanying 
specimens, it appears that at the landing place near the town of 
Porto Prago, in St. Jago, the rock of the cliff is composed of 
fragments of trap imbedded in a hard pure white carbonate of 
lime. The fragments of this breccia are generally small, and 
none of them rounded by attrition. The cliff on which stand the 
batteries and town of Prago, is regularly stratified, and at the 
bottom are beds of a calcareous sandstone alternating with 
others which contain specimens of a large oyster; in both of 
these beds occur pebbles of trap. The stratum which crowns 
the cliff is from eight to twelve feet in thickness, and consists of 
trap. 

Jan. 16.—A paper entitled “‘ Outline of the Geology of the 
South of Russia; by the Hon. William T. H. Fox Strangways, 
MGS.” was read in part. 

eb. 6.—On this day, being the anniversary of the Society, the 
following gentlemen were chosen as Officers and Council for the 
year :— 

President —Rev. W. Buckland, FRS. Prof. Geol. and Min. 
Oxford. 

Vice-Presidents—A. Aikin, Esq. FLS.; J. Bostock, MD. 
FR. and LS.; G. B. Greenough, Esq. FR. and LS.; and H. 
Warburton, Esq. FRS. 

Secretaries.—C. Lyell, Esq. FLS.; P. B. Webb, Esq. FLS.; 
and T. Webster, Esq. 

Foreign Secretary. —-H. Heuland, Esq, 


1824,] Meteorological Society. 311 


Treasurer.—J. Taylor, Esq. 

Council.—Sir T. D. Acland, Bart. MP.; J. Duke of Bedford, 
FL. and HS.; W. Clift, Esq. FRS.; H. T. Colebrooke, Esq. 
FR. and LS.; Major T. Colby, LLD. FRS. L. and E.; T. Hors- 
field, MD. FLS.; Sir A. Crichton, MD. FR. and LS.; C. 
Stokes, Esq. FRA. and LS.; T. Smith, Esq. FR. and LS.; 
W.H. Pepys, Esq. FR. L.and HS.; Rev. Adam Sedgewick, MA. 
FRS. Wocsaapten Prof. Cambridge; W. H. Fitton, MD. 
FRS. 

Keeper of the Museum and Draughtsman.—T. Webster, Esq. 

feb. 20.—A notice was read, of the Discovery of a perfect 
Skeleton of the Fossil Genus hitherto called Plesiosaurus; by 
the Rev. W. D. Conybeare, FRS. MGS. 

The Plesiosaurus, which is the subject of this notice, was 
found in the blue lias of Lyme Regis, in Dorsetshire. In the 
whole exterior portion of its vertebral column the skeleton is 
entire, and of the remaining parts of the animal few are wanting. 
In the Transactions of the Geological Society, vol. 5, and vol. 1 
second series, the author had attempted to assign to the various 
dispersed and disjointed remains of this animal which were then 
known, their relative places in the skeleton, and his opinions, he 
observes, have now, in all essential points, received full confirm- 
ation. After pointing out the errors into which he had fallen, 
Mr. Conybeare describes the osteology of this remarkable fossil 
animal; the most characteristic and distinguishing features of 
which are, the extraordinary length of the neck, which fully 
equals that of the body and tail united, and the number of its 
vertebre, which very far exceeds that of any animal previously 
known. 

METEOROLOGICAL SOCIETY. 

Jan. 14.—The Committee appointed by the Council of this 
Society to consider and report upon the best means of establish- 
ing correct and complete series of meteorological observations 
having presented their Preliminary Report, it was communicated 
by the Council to the Society, at this meeting. 

The Committee represent in this Report, that the first and 
principal object of the Society is to obtain accurate and compa- 
rable observations of atmospheric phenomena from all parts of 
the world; and after adverting to the advantages which would 
result from the general adoption by meteorologists of instru- 
ments graduated upon the same scales, to be examined by all at 
the same hours, and the results noted upon the same plan, they 
proceed as follows: 

“The Committee are, however, aware, that there are many and 
weighty difficulties in the way of such an arrangement, and that 
much time would necessarily be required for their consideration 
and discussion; they therefore recommend that immediate 
measures be taken to procure correct registers of comparable 
observations from different parts of Great Britain and its colo- 


312 Proceedings of Philosophical Societies. [ApRiL, 


nies, as well as from other parts of the world, with instruments 
graduated to the common scales. To effectuate this purpose 
with advantage, they consider it absolutely necessary that. the 
Meteorological Society of London should set the example of the 
requisite precision by establishing a Meteorological Observatory 
in the metropolis, or its vicinity, and instituting operations to be 
conducted with undeniable accuracy, and with instruments of 
standard excellence.” 

A paper was read “ On the Natural History and probable 
Causes of the Vernal Winds of the North of England, as they 
prevail in Westmoreland; by John Gough, Esq. of Kendal. 
Communicated by Dr. Birkbeck, President of this Society.” 

In this paper, Mr. Gough minutely describes the phenomena 
which accompany and characterise the periodical easterly winds 
of spring, especially as they prevail in Westmoreland, and 
states the following opinion respecting their cause, with 
various illustrations of it. The cause of these winds may 
be referred to the progressive advances of the spring from the 
south to the north. This season commences in Italy about the 
20th of February; it is equally advanced in Westmoreland 
about the middle of April, at which time the countries situated 
on the confines of the Arctic Circle remain buried in snow. 
This covering will unavoidably arrest the progress of spring in 
its advances towards the Arctic Circle, and prolong a milder 
kind of winter in the northern regions. The delay here pointed 
out is certain and annual, because the solar heat, instead of 
warming the surface of the country thus buried in snow, is 
absorbed by the icy covering, and employed in converting it into 
water of the temperature of melting ice. While the sun is 
employed in removing this impediment to vegetation in the 
north, his beams are warming the plains and valleys of England, 
in consequence of which the thermometer in the shade frequently 
stands between 60° and 70° at noon, during the latter part of 
April, and falls occasionally to the freezing point in the night. 

These facts show that the inhabitants of Britain enjoy an 
advanced state of temperature, while the people of Sweden and 
Norway are exposed to a degree of cold equal to the rigours of 
our winter. The preceding difference in the temperature of the 
atmosphere of Britain and the more northern regions gives a 
greater specific gravity to the air of Sweden and Norway than 
to that of England, as well as all the intervening countries that 
are free from snow ; and this excess of density is, in Mr. Gough’s 
opinion, the cause of the vernal winds. 

Several other communications were likewise read. 


MEDICO-BOTANICAL SOCIETY. . 
Jan. 15.—The Medico-Botanical Society of London held their 
anniversary meeting, when the following Council was elected 
for the ensuing year, viz. :— 


1824.] Scientific Intelligence. 313 


- Dr. Bree, FRS. President; Dr. Paris, FRS.; Dr. E. T. 
Monro; J. Brookes, Esq. FRS.; W. T. Brande, Esq. FRS. ; 
Sir J. Mac Gregor, MD. FRS.; Sir A. Crichton, MD. FRS. 
Vice-Presidents; W. Newman, Esq. Treasurer; Mr. C. Hold- 
stock, Secretary; J. Frost, Esq. Prof. of Botany; T. Jones, 
Esq.; W. Yarrell, Esq.; T. Andrews, Esq.; A. White, Esq. ; 
Dr. J. Elliotson. 


Articte XVII. 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS 
CONNECTED WITH SCIENCE, 


I, Improvement in the Mountain Barometer. 


Mr. Newman has proposed to remedy the inconveniences of the 
common instrument: what these are, and the mode of removing them, 
we shall give in his own words :— 

«« The object has been to correct those defects and errors which arise 
from the use of a wooden cistern and leather bag, in the common 
barometer. It has been found that when the cistern is made of a wood 
sufficiently sound and close-grained to permit of the pressure required 
from the screw to make the instrument portable, that it is so imper- 
vious to air, as not to allow it to pass with sufficient freedom, and con- 
sequently, that when the instrument is used at any great altitude, the 
mercury cannot fall into the cistern except with considerable difficulty, 
and a long time is required before an accurate observation of the air’s 
pressure can be made; most generally, however, the cistern is suffi- 
ciently pervious to air, but it is then found that on screwing up the 
mercury to the top of the tube, a portion of the metal generally makes 
its way through the wood, thus soon rendering the instrument quite 
useless ; for it is very evident that a barometer that loses a portion of 
mercury from the cistern by making it portable or otherwise after it 
is adjusted, can no longer be correct, or give the height of the column. 

‘** To obviate these inconveniences, I have substituted a cistern of 
iron in place of the wooden one; it is fastened to the tube by a thick 
collar of wood, which is glued on in the usual manner ; a screw passes 
through the centre of the bottom, so as to move in a line with the ba- 
rometer tube ; it is terminated inside the cistern by a piece of cork tied 
over with leather, so that the instrument being inclined that the tube 
may be filled with mercury, this cork may be screwed up against the 
end of the tube, and effectually preserve the metal within from oscilla- 
tion, without subjecting the cistern itself to ary pressure. 

‘«* As there is no pressure on the mercury in the cistern, the wooden 
cap may be left so porous in one part, as to allow of the ready access 
of air, so that the column shall fall freely to its proper level, without 
any danger of losing mercury. 

“ Another great object in a mountain barometer, is to obtain the 
temperature of the mercury, which is done by fixing a thermometer 


514 Scientific Intelligence. fArrit, 


with the bulb in the cistern ; I have found that by carrying a barome- 
ter in my hand and near the body, the temperature is increased consi- 
derably, and will frequently rise as high as 5° Fahr. 

<< In the barometer of common construction, the height of the column 
of mercury is marked offfrom another instrument, presumed as a stand- 
ard, and in that case, the actual height is rarely or ever given, for 
every change that takes place in the weight of the ary alters 
barometers more or less according to the proportion which the diame- 
ters of the tubes bear to those of the cisterns, and for that reason, upon 
examining twenty barometers no two will agree, unless they were 
marked off together, and happen to stand at that exact height. 

“To remedy this source of error each instrument may be reckoned 
a standard, the height of the column is marked off from the surface of 
the mercury, and the point given at which it was marked off; when 
with the correction for the capacities of the tube and cistern, and also 
the temperature, the actual height of the barometer is ascertained. 
Upon examining the first four which I made independent of each other 
on this principle, one for Mr. Daniell, one for the Royal Society, and 
two for Capt. Sabine, they agreed within ‘004 of an inch with each 
other.” —(Institution Journal, xvi. 277.) 


II. Vegetable Alkalies. 


Mr. Brande has lately given analyses of several of these bodies, some 
of which differ much from those of MM. Dumas and Pelletier, men- 
tioned in the Annals for January. The most remarkable discrepance 
is in the analysis of cinchonia. The mean of Mr. Brande’s analyses 
gives as its constituents 


Gatbon: ii daaaies cd war OTs TYISO 


ABOE!s ab ess ieee eee ese by 13978 
Hydrogen ........65 Ci Wes eo TEE 
100°19 


This substance, according to MM. Dumas and Pelletier, contains 
oxygen, and consists of 


ASHE OU a ons acFRia reid mo nici aiire s ae bs A, 
a TR ald inlet aapemeal 902 
LS (ist elite Br lens sar - 622 
20) ele regi ed tira 9 Se gh (atk 

100-00 


The following, Mr. Brande states as an approximation only to the 
correct proportions of the elements of quina: 


Carbon, .. ceawsssss ‘ vsovws 13°80 
MOE. sb. va ho pee onthe 616 Saisie 13-00 
EXy drogen ss viv sik ale b aie otis os 765 
RORY CI ais 0 0:5 9 ye bs» id ees 5:55 


1824.] Scientific Intelligence. f 315 
MM. Dumas and Pelletier find its constituents to be: 


Ce oo Rasy: Bs ao cians a asian h soe 
FAL)! A ERIE ade. 8°45 
BRVOFOQEM, s.c5.4 c+ ¢ i) paletas suse, COG 
VRE ais 6.4 5.48.55 Bethy .» 10°43 

100°56 


The differences in the proportions of azote and oxygen are very 
considerable. 

In the analysis of morphia, the agreement is much greater than 
could have been expected from the great differences noticed in cin- 
chonia and quina. Mr. Brande gives as the elements, 


Carbonwiis vis weit seal ee awa ae 72° 
yA) ae 55 
Hydrogen 3 oii 8's a8 ea aires oo 5S 
Oxygenev. ves cewe. veviow sani 270 
100°0 
while MM. Dumas and Pelletier state its composition to be: 
RO ee ie maha hale 4, Raa Site o aay Loe 
BO es Cha bosa ga V es dient bas 5°53 
MI CERT 5.5m) ogni ns sieitlayst tenant pista XO 
Oxygen.,...... bs Wei@S od ene pice doe 
99-40 
According to Mr. Bussey (Annals, N.S. vi-229) ,morphiais composed of 
Carbon. . i)ssiwe saa’. Seve ess of 690 
AZO 6 6c bs SS UNE sia #63 
Hydrogen ....bsisae vii bv seed (1. OG 
Oxygen... ..se.ecssereeesesess 200 
100:0 


In this analysis there is a difference of more than five per cent. in 
the quantity of oxygen compared with that in the last quoted; but 
while MM. Dumas and Pelletier differ from Mr. Brande in assigning 
nearly eight per cent. of oxygen to cinchonia, they and M. Bussey 
differ from Dr. Thomson in stating azote to be one of the constituents 
of morphia, and, according to him, it is composed of 


Carbon. ........; ig tae sees 44°72 
Pbydpope: 228 8 VS Pee Fences obey 
OR Ren CPE Re Es cess 40°69 

100°00 


From the different statements which have been thus made with 
respect to the composition of these vegetable alkalies, it appears pro- 
ble, either that different substances have been employed under the 
same name, or that impurity must have been in some cases mixed with 
them ; if the difference existed as to the quantity of any other element 
instead of the presence of azote, it might, perhaps, be referred to moist- 
ure, or water of crystallization; but as the case stands, further experi- 
ments are necessary. 


316 Scientific Intelligence. [ApriL, 


Ill. Deebereiner’s Eudiometer. 


Prof. Debereiner having suggested the use of finely divided platina 
for the purpose of detecting minute portions of oxygen in a gaseous 
mixture, in which hydrogen also is present, Messrs, Daniell and Chil- 
dren mixed 20 measures of atmospheric air, with 37 measures of hydro- 
gen gas, and passed up to the mixture a small portion of the platina 
powder, procured by heating the ammonia muriate to redness, and 
made into a ball with precipitated alumina. The pellet was heated red 
by the blowpipe, immediately before it was used ; its size about that of 
a small pea. The absorption amounted to 15 measures = 4-3 oxygen, 
being 0'1 of a measure more than the quantity of oxygen in 20 mea- 
sures ofatmospheric air, which may probably have arisen from aslight 
impurity in the hydrogen, or from some minute unperceived bubbles 
of air, entangled in the mercury. 

Another mixture of common air and hydrogen, in which the latter 
was in considerable excess, was deprived of its oxygen by the pellets, 
and when the absorption was complete, 38 measures of the residual gas 
were taken, and a fresh pellet, heated to redness, immediately before 
it was used, passed up. After standing about a quarter of an hour, no 
absorption had taken place. The tube and the mercury were then 
placed before the fire, till the whole apparatus was too hot to be 
touched with the naked hand. Jt was then removed from the fire, and 
when cooled to its original temperature, the mixture occupied, as 
before, exactly 38 measures. The powder of platina with hydrogen 
seems, therefore, to be admirably calculated for eudiometrical purposes. 
Its application is extremely simple and easy, it is speedy in its effect, 
and no error need be apprehended from the formation of ammonia, 
even at considerably elevated temperatures. It appears also to be 
well calculated for ascertaining the purity of simple gases, at least as 
far as regards admixture of atmospheric air. The oxygen of a very 
minute portion of common air, mixed with carbonic acid gas, and a 
little hydrogen, was immediately absorbed, on passing up one of the 
little pellets to the mixture.—(Institution Journal, xvi. 374.) 


IV. New Minerals. 


Mr. Brooke has lately described two new mineral bodies; to the 
first he has given the name of Childrenite, on account of the attention, 
among other inducements, which Mr. Children has shown to mireral- 
ogical chemistry. This mineral was met with in Devonshire, and was 
said to have been taken from some part of the ground whieh had been 
perforated for the Tavistock canal; it was supposed at first to be car- 
bonate of iron; but Dr. Wollaston determined that it was a phosphate 
of alumina and iron. 

The primary form of the crystal is assumed by Mr. Brooke to be a 
right rhombic prism; but he has not succeeded in cleaving it. The 
crystals scratch glass; their colour is wine-yellow, they occur on the 
surface of crystallized quartz, and might be mistaken by a casual 
observer for sulphate of barytes. 

The next mineral was sent, among other Vesuvian substances, to 
Mr, Brooke by Dr. Somerville, from which circumstance he has named 
it Somervillite ; the primary form of the crystal is a right square prism, 
but the crystals are modified by numerous secondary planes; they may 


1824.] New Scientific Books. 317 


be cleaved parallel to the terminal planes, but imperfectly, if at all, 
parallel to the lateral planes, or to the diagonals of the prism; their 
colour is a very pale dull-yellow ; they occur in cavities, with crystal- 
lized black mica, and with another substance not yet examined; the 
mass to which they adhere appears to be nearly all Somervillite, inter- 
mingled with black mica. 

This substance might at first view be mistaken for idocrase ; but it is 
much softer; the cleavage parallel to the terminal planes much more 
distinct, and the cross fracture more glossy. Mr. Children has also 
compared the characters of this mineral under the blowpipe with those 
of idocrase. When exposed alone in the forceps, it slightly decrepi- 
tates, which idocrase does not, and fuses, with greater difficulty than 
idocrase, into a greyish glass, the globule from idocrase being greenish. 
With borax, in the reducing flame, idocrase produces a light-green, 
and this a colourless glass. ’ 

Mr. Brooke has likewise examined the mineral called kupferschaum 
by the Germans, of which he had not met with any analysis. This 

- mineral, which is the same as the fibrous or flaky bright-green substance 
found at Matlock, appears to be a carbonate of copper and xinc.— 
(Institution Journal, xvi. 274.) 


V. Death of Mr. Bowdich, in Africa. 


It is with unfeigned regret that we announce the death of this enter- 
prising and accomplished traveller: he has fallen a victim to his over 
exertions in surveying St. Mary’s River, in Gambia: he expired, 
after lingering a fortnight, on the 10th of January, leaving a widow 
and three children totally unprovided for. Weare happy to learn that 
proposals will shortly be issued for publishing, for their benefit, Mr. 
Bowdich’s ‘‘ Excursions in Madeira and Porto Santo,” a work which 
he had completed prior to his decease. 


ArticLe XVIII. 
NEW SCIENTIFIC BOOKS. 


PREPARING FOR PUBLICATION, 


Elements of Physiology, by J. Bostock, MD. is nearly ready. 

Capt. Sir Henry Heathcote, RN. has in the press, a Treatise on 
Staysails for the Purpose of intercepting Wind between the Square 
Sails of Ships and other Square-rigged Vessels; illustrated by suitable 
Diagrams, and Plates. 

A Treatise on the Nature, Symptoms, and Cure of Cataract; by 
John Stevenson, FRCS. 8vo. 

A Treatise on Mineralogy, by Frederick Mohs; translated from the 
German by W. Haidinger. 2 vols. post Svo. 

Extracts from a Journal written on the Coasts of Chili, Peru, and 
Mexico, in the Years 1820, 1821, and 1822 ; by Capt. Basil Hall, RN. 
Author of a Voyage to Loo Choo. 2 vols. post 8vo. 


318 New Patents. [ApPRIL, 


JUST PUBLISHED. 
A Second Letter to Sir John Cox Hippesley, on the Mischiefs inci- 
dental to the Tread-Wheel, as an Instrument of Prison Discipline, 
containing an Examination of the Official Reports upon this Subject, 
returned to the Secretary of State’s Office, during each Session of 
Parliament. By John Mason Good, MD. FRS. &c. Price 2s. 6d. 

The West India Colonies: the Calumnies and Misrepresentations 
circulated against them by the Edinburgh Review, Mr. Clarkson, Mr, 
Cropper, &c. examined and refuted. By James Mac Queen. §8vo. 
12s. 

The Pupil's Pharmacopeeia ; being a literal Translation of the New 
Edition of the London Pharmacopeia, &c. By W. Maugham, 
surgeon. 6s, 

Sketches of the Philosophy of Apparitions ; or an Attempt to trace 
such Illusions to their Physical Causes. By S. Hibbert, MD. FRSE. 
&e. 10s. 6d. 

The English Flora. By Sir James E. Smith, President of the Lin- 
neean Society, &c. Vols, 1 and 2. 11. 4s. 

The New Pharmacopeia of the Royal College of Physicians of 
London, 1824; translated by Sir George L. Tuthill, Kt. MD. FRS; 
8vo. 7s. 18mo. 4s. 

Gardner on Iodine. 8yvo. 4s, 


ARTICLE XIX. 


NEW PATENTS. 


G. Pollard, Rupert-street, St. James, Middlesex, brass-founder, for 
certain improvements on machines for levigating or grinding colours 
used in the various branches of painting, which machinery may be 
worked by any suitable power, and is applicable to other useful pur- 
poses.—Jan. 19. 

J. Russel, Wednesbury, Staffordshire, gas-tube manufacturer, for his 
improvement in the manufacture of tubes for gas and other purposes.— 
Jan. 19. 

S. Broadmeadow, Abergavenny, Monmouthshire, civil engineer, for 
his improved method of manufacturing and purifying inflammable gases 
by the admission and admixture of atmospheric air.—Jan. 19. 

H. Fletcher, Walsall, Staffordshire, saddler’s ironmonger, for certain 
improvements in tanning hides and other skins.—Jan. 19. 

T. Bewley, Mount Rath, in Queen’s County, Ireland, cotton manu- 
facturer, for certain improvements in wheeled carriages.—Jan. 24. 

J. Heathcoat, Tiverton, Devonshire, lace manufacturer, for certain 
improvements in the method of figuring or ornamenting various kinds 
of goods manufactured from silk, cotton, or flax.—Jan, 24, 

J. Jones, Leeds, Yorkshire, brush manufacturer, for certain improve- 
ments in machinery and instruments for dressing and cleansing woollen, 
cotton, linen, silk, and other cloths or fabrics. —Jan. 27. 

Sir W. Congreve, Bart. Cecil-street, Strand, for his improved method 
of stamping.—Feb. 7. 


1824.) | Mr. Howard's Meteorological Journal. 319 


ARTICLE XX. 


METEOROLOGICAL TABLE. 


ee 
BARroMETER, THERMOMETER, 
1824, Wind. Max. Min. Max. Min. Evap. | Rain. 


Feb. 1S E] 30:20 30°11 45 25 


2, £E 30°27 30:20 43 24 ‘ais 
3S E] 30:20 20°89 45 32 — 07 
4, W 29:97 29°89 49 35 a2 16 
5| W 30°20 29:07 43 32 eee 
6N WI] 30°29 30°20 45 32 — pee 
7S W| 30°37 30°29 49 A5 = a 
8| W 30°50 50°37 54 48 aS st 
9 Var. | 30°50 30°48 52 35 — a 
OS WI 30:48 30°44 51 31 — ae 
11N W| 30°44 30°16 46 32 i. ce 
125 WI 30.16 29°42 45 35 *A5 12 
13} W 29°42 29°05 48 37 _ 1°04 
14, W 29:60 29°05 45 32 — 02 
15IN- E} 29°75 29°60 42 26 aes 
16} N 29°75 20°61 43 28 pe 
17IN-_—-E! «29°61 29°50 42 29 — 
RGD 29°57 29°50 45 34 — 06 
19, E 20:66 29°57 45 37 — 10 
20, E 29:91 29°66 47 36 — 33 
215 W| 30°04 29°91 42 30 — 
9| E 30°12 30°04 47 39 — 08 
23, E 30°12 30°12 42 38 a 
24) E 30°12 29°98 43 Q7 — 
25| E 29°98 29°96 38 30 
26, N 29°96 29°90 43 30 — 
2 N 29:97 29°90 39 33 — 23 
235 W| 30:05 | 2997 | 42 | 34 | — 10 
N 29°97 29°94 45 34 +40 


— 


— 


30°50 29°05 54 24 0°85 | 2°31 


The observations in each line of the table apply to a period of twenty-four hours, 
beginning at 9 A, M. on the day indicated in the first column. A dash denotes that 
the result is included in the next following observation. 


320 Mr. Howard’s Meteorological Journal. [Avri., 1824. 


REMARKS. 


Second Month.—1. Clear morning with white frost: fine day. 2. Very fine day. 
3. Hoar frost: foggy. 4. Cloudy. 5. Fine: lunar halo at night. 6. Ditto. 
7. Drizaling. 8. Overcast. 9, 10, Drizzly. !1. Very fine morning. 12. Drizzly. 
13. Morning fine: afternoon rainy: night stormy. 14, Cloudy. 15—I!7. Fine. 
18. Cloudy and fine: a little snow in the morning between five and six, which melted 
immediately. 19. Fine. 20. Drizzly morning: rainy evening. 21. Drizzly: very 
foggy night. 22. Foggy morning: fine afternoon. 23. Bleak. 24, 25. Fine. 
26. Bleak: some hail and snow at three, p.m. 27. Rainy: some hail at half-past 
eight, a.m. 28, Cloudy: rainy evening. 29. Cloudy. 


‘ 


RESULTS. 


Winds: N, 4; E,8; SW, 5; SE,2; W,5; NW,2; NE, 2; Var. I. 
Barometer: Mean height 


“Mor the amontli..<nconsaivccel tk ecasluclalasnctetcws «+2. 29°963 inches. 


_ For the lunar period, ending the 2Uth........0++-00 -/ 29:929 
For 14 days, ending the 2d (moon south) ........ «. 29°938 
For 13 days, ending the 15th (moon north) .........+ 30-026 


Thermometer: Mean height 


For the miontlaetiic\s.c/c cera minzs.dyeninaiole'© wisiaresimeievtslalaei oan 


For the lunar period. ..........- ececerscccccecccess 40017 

“For days, the sun in Aquarius......... seiteseéos A0'ZI6 
EVaporationes cic csccececsviccieccviaraccccee a evececens Wiebe co. ceice e tUl ovate 
FRAN sc ccciecice Sie'e gis einetelgieisinia)suthie'wisiacias Auitieini:ac sic aie cqeipaiteisinciaelem bores 


Laboratory, Stratford, Third Month, 24, 1824. R. HOWARD. 


ANNALS: 


OF 


PHILOSOPHY. 


MAY, 1824, 


ARTICLE I. 


Remarks on Solar Light and Heat. By Baden Powell, MA. of 
Oriel College, Oxford. 


(To the Editor of the Annals of Philosophy.) ° ~ - 


SIR, April 2, 1824. 

In explanation of the design of the present communication, I 
conceive it necessary to observe in the first instance, that having 
been engaged in experiments on solar light and heat, I have laid 
accounts of some of them before the Royal Society (see reports 
of Royal Society, Annals, Feb. 1824) : ce accounts, however, 
being confined to the mere detail of the experiments, I wish 
through the medium of your journal to offer some remarks on 
the subject, of a more general nature, and which may be consi- 
dered as forming a sort of introduction to such experimental 
researches. , 

If then in taking a brief review of the present state of our 
knowledge upon this subject, my remarks and statements should 
not be of a nature wholly new, my design as thus explained will 
be a sufficient excuse ; and the more so as I could not proceed | 
to the few experiments here given without such preliminary 
considerations. { am, Sir, your obedient servant, 


B. Powe... 
ge 


T. (1.) Speaking according to our ordinary sensations, we are 
accustomed to say that the sun communicates both light and 
New Series, vou, vu. Y 


322 Mr. Powell on Solar Light and Heat. [May, 


heat. Light is transmitted in a way which we term radiation. 
The heat from non-luminous hot bodies is transmitted to a dist- 
ance in a way closely analogous; and to which the same name 
has been applied. In the first instance we might suppose that 
the sun sends out two separate emanations, one of light, and 
another distinct from it, and similar to that of radiant heat from 
a mass of hot water; and this, perhaps, was the first view taken 
of the subject, though a confused idea of some very close and 
intimate connexion subsisting between the solar light and heat 
appears to have prevailed. 

(2.) This subject, as might naturally be expected, attracted 
the early notice of experimenters. A very slight examination 
sufficed to show that the rays of solar heat (whatever their 
nature might be) differed essentially in many properties from 
those of terrestrial heat, whether radiated from luminous or non- 
luminous bodies. Whether there existed a separate set of 
heating rays distinct from those of light, and at the same time 
differing in many respects from rays of terrestrial heat; or 
whether these differences depended on some unknown property 
of the rays of light, was a question which for a long time 
remained without any direct investigation, and on which even 
now, we have, perhaps, no very precise ideas. 

Among the earliest experiments on the subject, if not actually 
the first, were those of Mr. Boyle, on the different degrees of 
heat communicated by the sun to black, white, and red-coloured 
surfaces. These were extended and confirmed in the well- 
known investigations of Dr. Franklin, Xe. 

“Mr. Boyle caused a large block of black marble to be 
ground into the form of aspherical concave speculum, and found 
that the sun’s rays reflected from it were far from being too 
powerful for his eyes, as would have been the case had it been 
of any other colour; and although its size was considerable, yet 
he could not set a piece of wood on fire with it; whereas a far 
less speculum of the same form, made out of a more reflecting 
substance, would presently have made it flame.”—(Boyle on 
Colours, &c.) 

Scheele conceived that the sun’s rays of light produced heat, 
not when in motion, but only when stopped by the interposition of 
solid bodies.—(Treatise on Air and Fire, &c.) 

Mr. Melville seems to have viewed the matter nearly in the 
same light, and to have conceived reflexion at an opaque surface, 
the cause of excitation of heat from the sun’s rays.—(See Phil. 
. Mag. June, 1815, a paper by Dr. Evans.) 

(3.) In later times the experiments of Prof. Leslie, Sir H. 
Davy, &c. have sufliciently established the property possessed 
by that emanation (whatever its nature may be, whether simple 
or compound) which is derived from the sun, of producing 
greater heat in bodies in proportion as their surfaces owing to 
darkness of colour, have the capacity of absorbing rays of light. 


1824.} Mr. Powell on Solar Light and Heat. 323 


It has been equally well established by Prof. Leslie, Count 
Rumford, &c. that the heat emanating from a mass of non- 
luminous hot matter, has no such relation to the colour, though 
a very close one to the nature and texture of the surface. 

(4.) The experiments of Sir E. Home (Phil. Trans. 1821, 
Part I.) are particularly deserving of attention, as exhibiting 
what might at first sight be considered an exception to the 
above remarks; a greater effect being produced in some instances 
on a white than on a black surface. A more attentive examina- 
tion, however, will show us that these experiments prove thus 
much. The heat occasioned by the rays of the sun when 
received directly, or when in some degree intercepted as by thin 
white cloth, on the skin, is greater than that communicated by 
conduction to the same skin, through a black cloth in contact 
with it, which is itself, in the first instance, heated by absorbing 
the rays. 

A white skin is scorched, and a negro’s skin is not, in ten 
minutes by the direct rays of the sun; that is, as before, the 
outer coat of the white skin allows some of the direct rays to 
pass through and affect the sentient substance beneath ; 
whereas in the case of the black skin, the rays are absorbed by 
the black surface, and so affect the sentient parts only as heat 
of temperature. 

II, (6.) As to the nature of this heating effect, the greatest 
difference of opinion has long prevailed among the most distin- 
guished philosophers; one party maintaining the totally distinct 
existence of light and radiant heat in the compound solar beam; 
the other contending for the absolute identity of the two: the 
same principle being merely displayed under two different modi- 
fications. (See Sir W. Herschel, Phil. Trans. 1800, Part II. ; 
Leslie on Heat, p. 162, Biot, Traité de Physique, vol. iv. p. 
690, &c.) 

Without entering upon an examination of the merits of either 
theory, we may proceed to remark that the first object in the 
inductive examination of this subject is to ascertain distinctly 
what peculiar properties of this heating emanation we can fix 
upon by which its nature may be defined, and by the help of 
which we may be enabled to compare it with other heating 
emanations. 

(6.) Among the most obvious properties of the solar rays, we 
tei that before adverted to, viz. that they produce heat on 

odies in proportion to the darkness of their colour, and not in 
regard to the absorptive qualities of the texture of their surfaces 
for the heat from non-luminous bodies. This relation is univer- 
sal, and without any exceptions; it is consequently one which 
we can satisfactorily adopt as the foundation of a distinctive 
description. 

(7.) We may from this advance to another test, which will 
afford an additional characteristic. It has been distinctly shown 


c 


» 


324 Mr. Powell on Solar Light and Heat. [May, 


that all heating emanations from terrestrial bodies whether lumi- 
nous or not, are more or less stopped, or even in some cases 
totally intercepted, by the interposition ofa glass screen. Similar 
experiments may easily be tried on the solar rays. 

That little or no diminution of effect is produced on a black- 
ened thermometer exposed to the sun, by the interposition of 
glass, has been shown ys several experiments. As it is 
remarked by De la Roche (Biot, Traité de Phys. vol. iv. p. 611), 
I have also frequently observed the same thing, taking notice of 
the temperature of the glass, as will be subsequently seen. But 
there is another part of the question which still appears to me to 
want further examination. The sun’s rays produce some heating 
effect on surfaces of a light colour. I have, therefore, tried 
whether also in this case, and when the texture of the surface 
was very absorptive for simple radiant heat, a glass screen has 
any power to diminish the effect. Two thermometers. were 
exposed together to the direct and screened rays, one having its 
bulb coated with indian ink; the other with a thin paste of chalk 
and water; the bulbs were free from contact. If there existed 
in the solar beam any rays of such a nature that they were 
affected by the ¢extwre rather than the colour of surfaces, and 
were not capable of passing through glass, they would be affected 
by a surface of chalk more than one of indian ink. If they 
formed only a small proportion of the whole, the diminution, 
when glass was interposed before the inked thermometer, might 
be so small as to be imperceptible; but with the whitened sur- 
face, it would be much more conspicuous. 

(8.) The following are the results of two sets of experiments 
conducted on this principle: 


THERMOMETERS. 
Ga ee aN 
Exposed. Screened. Temp. of glass. | Thickness 
A. B. A. B. Before | After | of glags, 
Rise in two White. | Black. | White. | Black. | exper. | exper. | Inch. 
minutes cen- } 
tigrade. 4-0° 65° 5:0° §-0° 18-0° 190° 0*44 
A: 55 40 7:0 205 | 20:5) | — 
4°5 7:0 3°5 6°5 21:0 21:0 — 
5:5 8-0 45 75 17°0 WS | oo 
5:0 9:0 2°5 3°9 —_ _ — 
5 7-0 6:0 85 — —_ _ 
ry et) 3:0 3°5 T:0 18:5 19-0 0:06 
Mean 4-0 6°57 A-14 7:0 


1824.] Mr. Powell on Solar Light and Heat. 325 


THERMOMETERS, 
Tos in — 
Exposed. Screened, Temp. of glass. | Thickness 


B. A. B. A. | Before | After | ° slass- 
Rise in two White. | Black. | White. | Black. | exper. | exper. Inch. 
minutes cen- | —————— | ————  —$ | — | — |} ————__| 


tigrade. +50 7 50 1 18 20:0 | 0-06 
3:25 6 40 6 20 20°5 the 
5-0 10 5-0 10 19 19-0 | 0-44 
4-0 1 3-25 1 19 19-0 1 
Mean 4:18 | 75 | 4:32 |. 07-5 


(9.) These results exhibit a very close agreement in the ratio 
of the risings of the two thermometers, when exposed, and when 
screened, and this with glasses of different thickness, at different 
times, and with different absolute intensities of the sun’s rays ; 
as also when the colours of the bulbs were mutually changed. 
The mass of the bulb A was somewhat greater than B; the glass 
acquired no heat sufficient to interfere with the results ; and the 
thermometer was always placed so that the bulbs were not near 
any object which might radiate heat. The temperature of the 
air affecting both surfaces equally would tend to diminish the 
ratio. To its variation, I conceive, the trifling difference in the 
ratios may fairly be ascribed. 

(10.) Hence, I think, we are entitled to conclude, that there 
do not exist in the solar beam in its natural state any rays of the 
description just alluded to; but that the whole emanation 
consists of one sort of rays distinguished by the two characteris- 
tics of affecting substances with heat in proportion to the dark- 
ness of their colour, and being wholly transmissible through glass 
without heating it ; and that these same rays when they infringe 
on the eye are capable of producing the sensation of vision ; 
and by the absorption of some, and the reflexion of others, of 
their constituent parts, at the surfaces of bodies, produce the 
phenomena of colours. 

(11.) The heating effect maintains an intimate relation to 
light both in respect to the substances which it traverses without 
interception, and to those by which it is absorbed, and to the 
degree of absorption. It is found to accompany the rays of 
light in the most constant and inseparable manner: through 
whatever substance, and in whatever direction it takes its course, 
this is strikingly exemplified in one of Sir W. Herschel’s experi- 
ments (Phil. Trans. 1800, No. 13, Exper. 11), in which the heat- 
ing effect is shown to accompany the rays of light in all the 
alterations of its course through a Newtonian telescope with 
four lenses. 

_ Speaking in general terms, within ordinary limits, and for 
light of the same colour, we may say, that the heating effect 
increases or decreases in proportion to the intensity of illuminat- 


326 Mr, Powell on Solar Light and Heat. [May, 


ing effect. Prof, Leslie considers the proportion to be precise 
and undeviating. 

(12.) Whatever we suppose to be the state in which the heat 
exists when it thus inseparably accompanies the luminous rays, 
it is evident that there must be some peculiar circumstance in 
the mode of its union which makes its effects sensible only under 
some particular circumstances ; and under others endows it with 
properties which heat in its simple radiant state does not possess. 
It evidently exists in a state essentially different from that of 
simple radiant heat ; and we may in general say, that it is never 
developed or rendered sensible except under such circumstances 
as produce at the same time some modification or change in the 
light itself. 

Upon considering all these well established facts, I think, 
instead of using such terms as “ calorific rays,” and “luminous 
rays,” it is much more conformable to facts, and involves no 
hypothetical ideas, to describe the phenomena by the terms 
“rays of light,” and the “ heating power or property” of those 
rays. 

Iff. (15.) Thus far my remarks have been confined to the 
nature of the heating power of the sun when its rays are in that 
state in which they naturally are, as coming directly from that 
luminary. In the next place we have to inquire whether by any 
modification which these rays may be made to undergo by artifi- 
cial means, we can attain to any further elucidation of the nature 
of this heating power. 

(14.) It has been shown by the experiments of M. Berard 
(Biot, Traité de Phys. vol. iv. p. 603, &c.), that when light under- 
goes polarization, the heating power participates in that effect. 

It has also been shown by the same distinguished philosopher 
(see Biot as above), that simple radiant heat when unaccompa- 
nied by light is susceptible of being polarized also. In consi- 
dering these results, we must be careful not to confound them 
together; because simple rays of heat are capable of displaying 
the effects of polarization, and the heating effect in the solar 
beam also obeys the same impulse, we must not hastily conclude 
that the same agent existing in the same form is, therefore, the 
common heating principle in both cases. 

(15.) The heating power of the sun is well known to be 
capable of being collected in a focus along with the luminous 
rays, both by reflexion and refraction. By the former means 
simple radiant heat may also be concentrated : this circumstance 
again shows a szmi/arity, but does not prove an identity in the 
agents or powers. A; 

In one of Sir W. Herschel’s experiments (Phil. Trans. 1800, 
No. 15, Exper. 23), a focus of heat different from that of light 
seems to be proved. This opinion it is not my design at pre- 
sent either to maintain or controvert. I have only to observe, 
that granting its truth, it must not be applied as an argument to 


1824.] Mr. Powell on Solar Light and Heat. 327 


show that simple radiant heat exists distinctly in the solar beam; 
or in other words, that the sun’s heat is produced by an assent 
identical with that which emanates from non-lnminous hot bo- 
dies ; it merely shows that the refractive and dispersive power 
which the lens exercises on /ight is capable of eliciting from it a 
certain agent or set of rays which produces the sensation of heat, 
but not that of illumination ; and by no means shows that that 
agent exists in a separate form when the rays of light are in 
their direct natural condition. 

If the focus of heat be the same as that of light, and the expe- 
riment of Sir W. Herschel (Phil. Trans. 1800, No. 15, Exper, 
19, 20) be admitted, where the concentration of simple radiant 
heat by a lens appears to be proved, the same remark applies as 
that just made with respect to concentration by a mirror. 

(16.) The principal modification which the sun’s rays are 
made to undergo, and from which conclusions relative to the 
nature of their ean power have been drawn, is the analysis 
to which they may be subjected by the prism. Into any discus- 
sion upon the controverted points respecting these experiments, 
I shall abstain from entering. We will suppose it granted that 
a set of invisible heating rays are separated beyond the visible 
red rays. The existence of such rays in a distinct state in the 
spectrum cannot be considered as any proof that they have that 
distinct existence in the natural state of the rays. It by no 
means proves that any such simple heating rays must have come 
directly from the sun, and have been transmitted through the 
prism, with merely a change in their direction. 

From the experiments above given, we may, in reference to 
this point learn thus much: the direct rays are not accompanied 
by any separate heating rays which are either stopped by glass, 
or bear a relation to texture more than colour. It therefore 
becomes an important object to try whether in the prismatic 
beam these heating rays possess those characteristics or not. 
With respect to one of the characteristics, viz, transmissibility 
through glass, we have no ground to assume that the heating 
prismatic rays possess it from the circumstance of their passing 
through the prism, because, when the light impinges upon the 
prism, we know that it has not any such separate rays accompa- 
nying it; and of the nature or properties of the rays during their 
passage through the prism, we are altogether ignorant. 

(17.) My object in making these remarks is merely to attain 
if possible some clear ideas on the subject in question ; and to 
point out those parts of it which appear to me to. want further 
elucidation ; moe to several of which I have attempted to direct 
experimental research. The subject must always remain 
perplexed and obscure so long as we dispute about such terms 
as ‘‘ calorific rays,” “ luminous,” or “ non-luminous heat,” &c. 
The only way of arriving at clearness of ideas, and thence being 
able to pursue the inquiry in a satisfactory manner, is to fix upon 


328 Col. Beaufoy’s Astronomical Observations. [May, 


some definite criteria by which the nature of heating agents may 
be distinguished and compared ; and instead of framing theories 
to explain the union of heat and light in the sun’s beams, to 
describe the nature of the phenomena in conformity to the 
criteria above pointed out, as afforded by certain experimental 
facts. 

It becomes necessary to subject to an examination by those 
criteria the supposed exterior heating effect of the prismatic 
spectrum ; as well as the analogous exterior heat of the cone of 
light formed by a lens, and probably several other phenomena, 
before we can obtain from them any further information respect- 
ing the nature of the heating power which is so inseparably 
associated with the sun’s light. 

The remarks hitherto made apply to the subject of solar light 
and heat; but they might be extended also to the investigation 
of the relations of light and heat from terrestrial sources. The 
want of some fixed criteria of definition must upon consideration 
be felt equally in following up this part of the subject. as in the 
former ; and to endeavour to supply that want should be the 
first. business of the experimenter. 

Some further observations will probably form the subject of a 
future communication. 


ArTICLE II, 


Astronomical Observations, 1824. 
By Col. Beaufoy, FRS. 


Bushey Heath, near Stanmore. 
Latitude 51° 37’ 44°3” North. Longitude West in time 1’ 20°93”. 


March 28. Emersion of Jupiter’s second § 8h 17’ 24” Mean Time at Bushey. 
BAPEIMLE ole! cece ec ss om tate 8 18 45 Mean Time at Greenwich. 

March 31. Emersion of Jupiter’s first § 8 13 49 Mean Time at Bushey. 
satellite. ..... arictiioan 8 15 10 Mean Time at Greenwich. 
12 15 44 Immersion of a small star. 
12 19 Ol Im. Jupiter's 4th satellite. 
12 21 19 Immersion of a small star. 

13 21 51 Em. Jupiter's Ist limb. 

13 22 O1 Em. Jupiter's 2d limb. 
Clouds prevented the Immersion of Jupiter being seen: at the Emersion, the limbs of 

Jupiter, and the Moon, were tremulous. 

April 7. Emersion of Jupiter’s first {10 09 15 Mean Time at Bushey. 

BAteHted 26). Heb elie aie lalla sto 10 36 Mean Time at Greenwich. 


April 5. Occultations by the moon, Si- 
Gertal "IMCs aids asin d 5.68. <6c 


1824.] On the Decomposition of the Metallic Sulphates. 329 


ArTICLE III. 


On the Decomposition of the Metallic Sulphates by Hydrogen 
Gas. By J. A. Arfwedson. 


Srnce it has become known that the fixed alkaline sulphates 
may, by means of hydrogen gas, be reduced to metallic sulphu- 
rets, it was natural to infer that the same method would be 
equally successful with the different metallic sulphates. This 
consideration induced me to undertake a set of experiments by 
the above-mentioned method, in order to determine more accu- 
rately the nature of the combination of sulphur and manganese; 
concerning which chemists have been long of opinion that the 
manganese in it is in the state of an oxide; although several 
circumstances, the most important of which is its property to 
dissolve in acids with the evolution of sulphuretted hydrogen 
gas, have led also to the opposite sentiment. The experiments 
which I am going to relate had at first no other object than to 
determine the nature of this compound of sulphur and manga- 
nese; but the unexpected results obtained led afterwards to the 
experiments which will be related. 

To avoid unnecessary prolixity in the description of the follow- 
ing experiments, I should state in the first place, that all the 
reductions of which I shall have occasion to speak, were per- 
formed in precisely the same kind of apparatus, consisting 
merely of a piece of barometer tube, of rather difficultly fusible 
glass, about the middle of which was blown a small globular 
cavity, into which the substance destined for reduction was put. 
The hydrogen gas was prepared from zinc and dilute sulphuric 
acid. It was dried by passing it through fused muriate of lime, 
before it entered the tube. In those cases where sulphuretted 
hydrogen gas was employed, it was freed from the accompany- 
ing moisture in exactly the same way. 


Reduction of Protosulphate of Manganese by Hydrogen Gas. 


Tn the little apparatus just described a portion of pure sulphate 
of manganese was put, which, though previously deprived of its 
water, was again heated in the apparatus till I was certain that 
it retained no moisture: then the evolution of hydrogen gas was 
set a-going, and when the whole atmospherical air had been 
driven out of the apparatus, the salt was heated over an Argand 
spirit-lamp. Till the matter became red-hot, it underwent no 
alteration ; but at that temperature the salt began to become 
dark, and at the same time sulphurous acid and water came 
over together. When this extrication was at an end, and when 
the hydrogen gas passed through unaltered, the reduction was 


330 M. Arfwedson on the- Decomposition of [May, 


considered as completed, and the apparatus was allowed to cool, 
still filled with hydrogen gas. The product of this experiment 
was a light-green powder, which dissolved in muriatic acid, with 
the evolution of sulphuretted hydrogen gas; and the solution 
was rendered only slightly turbid by the solution of barytes. 
Thus it appears that the salt was completely decomposed : 
1-484 gramme of sulphate of manganese thus treated lost 0-697 
gr. in weight, or 46:97 percent. In another experiment 0°553 

r. lost 0°263, or 47°56 per cent. A third experiment gave a 
loss of 1:034 gr. from 27195 grs. of salt, which amounts to 47°10 
per cent. The mean of these three experiments gives 47-22 for 
the loss of weight sustained by 100 parts of anhydrous sulphate 
of manganese when thus treated. 

It becomes now a question of some difficulty to determine 
the composition of the substance thus obtained. It is impossible 
that it could contain the same quantity of sulphur as the salt 
employed (Mn S?), because a quantity of sulphurous acid had 
made its escape: nor could it be manganese combined with an 
atom of sulphur (Mn 8); for on such a supposition the weight 
lost by 100 parts of the salt should have been 52°32, which was 
considerably greater than that found by experiment. I thought 
it, therefore, likely that I had obtained a body analogous to the 
crocus antimonii ; or that it consisted of a combination of sul- 
phuret of manganese and protoxide of manganese. The simplest 
proportion in which such a combination can take place, is one 
atom of sulphuret with an atom of protoxide; and in order to 
obtain such a result from protosulphate of manganese it is 
obvious that 100 parts of the salt must lose 47:09 ; or almost the 


loss sustained in the preceding experiments; for 2 Mn & : 


2 Mn S? — (Mn + Mn 8’) :: 100 : 47:09. The reason of this 
combination may be thus explained, that the sulphate of manga- 
nese is decomposed by hydrogen gas in such a way that half of 
the salt is changed into Mn S*, while the other half loses its 
acid and remains in the state of protoxide. In order to prove 
the truth of this opinion, it was merely necessary to determine 
the quantity of sulphur in the reduced body, the quantity of 
manganese being already known from our knowledge of the 
composition of the salt ; and the remainder wanting to make out 
the complete weight must obviously be oxygen. I attempted 
first to determine the sulphur by dissolving the body in aqua 
regia in order to oxidize the sulphur, that it might be afterwards 
thrown down by barytes; but the evolution of sulphuretted 
hydrogen gas which took place on the addition of the acid 
rendered this method abortive. I next dissolved the matter in 
muriatic acid, and made the sulphuretted hydrogen gas pass 
through a solution of acetate of lead; but even when this pro- 
cess was followed, I obtained an uncertain and varying product : 


1824.] — the Metallic Sulphates by Hydrogen Gas. 331 


the cause of which was that the sulphuret of lead formed is partly 
converted into sulphate during the drying. 

Still, however, the method remained of determining the quan- 
tity of sulphur by roasting the compound. A portion of the 
substance in question prepared just before, which I shall here- 
after call oxtsu/phuret of manganese, was heated to redness in a 
platinum vessel. The matter took fire before it became red-hot 
and burnt, leaving behind brown oxide of manganese, or oxidum 
manganoso-manganicum. But in order to drive off the whole of 
the sulphur, a long continued roasting was necessary. 

0°36 gr. of oxisulphuret gave by this treatment 0:347 gr. of 
brown oxide of manganese ; equivalent to 96:39 per cent. The 
oxide of manganese thus obtained dissolved in muriatic acid 
without any residue, and the solution was not rendered turbid 
by muriate of barytes. Now if the oxisulphuret of manganese 


were a compound of Mn + Mn 8°, then 100 parts of it would 


correspond with 96°58 parts of Mn + Mn’, or brown oxide of 
manganese ; and the result, as is obvious, corresponds very well 
with this calculation. 

Meanwhile, in order to be certain of the accuracy of these 
conclusions, I thought it necessary to make direct experiments, 
in order to show the existence of protoxide of manganese in 


ak 
or this purpose a portion of protosulphate of manganese 
was reduced by hydrogen gas, in the way above described. 
After this the apparatus was weighed in order to determine the 
amount of the oxisulphuret remaining.* A stream of dry 
sulphuretted hydrogen gas was then passed through the same 
apparatus. It was clear that the protoxide of manganese, in 
case it was present, would by this process be converted into 
Mn S*; consequently a certain portion of water would be 
formed. This accordingly took place, and with so much rapi- 
ity, that almost as soon as the gas entered the apparatus, and 
before any heat had been applied, the whole interior of the small 
glass globe in which the matter lay, was covered with small drops 
of water. Itis possible that the reduction in this case might be 
accomplished without the application of any heat; but to make 
sure of the reduction, it is expedient to a hy the heat of aspirit- 
lamp till the matter becomes ofa low red heat ; and the process 
must be continued as long as any moisture makes its appear- 
ance. The apparatus is then to be allowed to cool. It is to be 
weighed after the gas with which it is filled has been driven off, 
and replaced by common air. 0933 gr. oxisulphuret treated in 
this way left 1-022 gr. of sulphuret. This corresponds to 100 
parts of. the former, and 109-54 of the latter. This is just the 


* The diminution of weight was quite the same as in the former experiment. 
8 q 


"B22 _ M. Arfwedson on the Decomposition of [May, 
quantity of Mn S$? which, according to calculation, should be 


obtained from 100 parts of Mn + Mn S*; for Mn + Mn &: 
2 Mn S?:: 100: 109-98. 

The colour of oxisulphuret of manganese is somewhat a lighter 
green than that of the protoxide. It remains unaltered though 
exposed to the air; and thus is easily distinguished from the 
protoxide, which, as is known, speedily absorbs oxygen, and 
becomes brown. It is easily distinguishable likewise from the 
sulphuret of manganese, which has a much darker green colour, 
and which moreover, when long exposed to the air, gradually 
becomes oxidized, and assumes a brown colour. 

The constituents of 100 parts of oxisulphuret of manganese 
calculated from the data given above, are as follows: 


IEBRBANCSE oy.5 were ie a Keone ate be 70°26 
Sulphur. .......... 05 Cds dR tah 19°86 

ORYVACD oa ores) else y etue oiatarvineiaie vie sae 9°88 

100-00 

Or, 

Sulphuret of manganese ......+-+.+0+- 55 
Protoxide of manganese .... .+.+.e0-s 45 

100 

Reduction of Protoxide of Manganese by Sulphuretted Hydrogen 
Gas. 


It was of importance after the preceding experiments to deter- 
mine whether any other sulphuret besides Mn $* could be formed 
when protoxide of manganese is treated with sulphuretted 
hydrogen gas. I prepared, therefore, a portion of protoxide of 
manganese by reducing the oxide by means of hydrogen gas, 
and after the weight of the protoxide had been determined with 
the requisite precision, it was treated with sulphuretted hydrogen 
gas so long as any water was formed. From 0317 gr. protoxide 
of manganese treated in this way, I obtained 0°392 gr. sulphuret 
of manganese, or from 100 parts of the former 123°66 of the 


latter; but Mn: Mn S? :: 100: 122-19. The small excess in 
the experimental result proceeded doubtless from this cause, 
that the protoxide could not be weighed with sufficient rapidity 
to prevent it from absorbing a little oxygen from the air. 

I attempted afterwards to reduce protosulphate of manganese 
by means of sulphuretted hydrogen gas. 0°899 of anhydrous 


salt gave 0°526 of sulphuret of manganese. Now Mn 8° : 
Mn &° :: 0°899 : 0523. From this it seems to appear that 
manganese in the dry way cannot combine with more than two 
atoms of sulphur. 


a 


ae a ge ee 


1824.] the Metallic Sulphates by Hydrogen Gas. 333 


Examination of the Substance formed when Protocarbonate of 
Manganese is fused in a close Vessel with Sulphur. 


1. Protocarbonate of manganese was intimately mixed with 
nearly twice its weight of washed flowers of sulphur. The mix- 
ture was put into a small retort blown at the enameller’s lamp, 
which was afterwards slowly raised to a red heat.. When no 
more sulphurous acid was exhaled, and when the superfluous 
sulphur had been volatilized and collected in the beak of the 
retort, the mouth of the retort was stopped with a cork, and the 
fire withdrawn. On cooling, the matter contained in the belly 
of the vessel was taken out. It had the light-green colour of 
oxisulphuret of manganese. It dissolved in muriatic acid with 
the evolution of sulphuretted hydrogen gas; but the solution 
was considerably affected by munate of barytes. 0-418 gr. of it 
left after burning 0°392 gr. of brown oxide of manganese. 
Another portion, weighing 0°710 gr. was dissolved in muriatic 
acid, and precipitated by muriate of barytes. There were 
obtained 0:039 gr. of sulphate of barytes, equivalent to 0:026 
protosulphate of manganese ; consequently the abovementioned 
0418 gr. of sulphuretted manganese contained 0-015 protosul- 
phate of manganese, and the remaining 0-403 had given 0-377 
of brown oxide.* 0:403 Mn + Mn S* would have given 0-388 
brown oxide, and the same quantity of Mn S*is proportional to 
0-354 brown oxide; consequently the body under examination 


seems to be a mixture of Mn S° with a smaller quantity of Mn 


than in the compound Mn + Mn 8°. 

2. It was probable that the imperfect conversion of the proto- 
carbonate of manganese into Mn S? in this experiment, was 
owing to the process having been conducted too rapidly; ‘so 
that the sulphur was distilled away before it had time to decom- 


pose all the Mn. A new portion of protocarbonate of manga- 
nese and sulphur was, therefore, mixed together, and exposed to 
a heat just sufficient to keep the sulphur in the state of fusion. 
When in consequence of continuing this heat for several hours 
it was supposed that the decomposition might be completed, the 
heat was augmented so as to drive off the excess of sulphur, and 
the retort was corked and allowed to cool. In the same manner 
as in the former experiment, it was found that 0-922 gr. of the 
sulphuret of manganese now formed contained 0:036 of proto- 
sulphate of manganese. The remaining 0-886 left when burnt 
0°787 of brown oxide of manganese. 0-886 Mn S* are propor- 
tional to 0°778 brown oxide of manganese. Hence it appears 


* This is agreeable to an observation already made, that no protosulphate of manga- 
nese is formed when sulphuretted manganese is burnt. 


334 M. Arfwedson on the Decomposition of {May, 


that in the latter experiment the sulphuret contained a smaller 
admixture of oxide than in the former. 

3. A portion of the sulphuret of manganese prepared in the 
second experiment was accurately mixed and fused with its 
own weight of sulphur, 0°732 gr. of this product contained 
0-031 of protosulphate of manganese, and 0°701 gr. of the 
remaining quantity gave when burnt 0°619 gr. of brown oxide of 
manganese. This quantity differs only by 0-004 gr. from the 
calculated quantity of oxide which should have been obtained 
from 0°701 Mn S?; so that the sulphuret of manganese of this 
experiment appears to have been free from protoxide. 

rom these experiments it appears that when protocarbonate 
of manganese is fused with sulphur ina close vessel, there is 
always formed (together with a little protosulphate of manga- 
nese) a Sulphuret of manganese containing more or less oxide. 
This is the substance which has been erroneously denominated 
sulphuretted oxide of manganese ; and the best way to obtain a 
sulphuret free from oxide is to fuse this substance a second time 
with its own weight of sulphur. 


Native Sulphuret of Manganese, or MANGANGLANSE, from 
Nagyag, in Transylvania. 

In connexion with the preceding experiments, it seems of 
importance to determine the corstitution of sulphuretted man- 
ganese prepared by nature, This mineral, according to the 
analysis of Klaproth, is composed of 


Protoxide of manganese ...+.-esees-00 82 
PULL wig iso 8)¥,e pom jo vis Rinminle ef «plates GEM 
Carbonic acid. sega be«d-+siae oaesGignocen 


‘98% 


Klaproth concluded that the manganese was in the state of 
protoxide, because he found that when protoxide of manganese 
and sulphur were melted together, he obtained acompound similar 
to the natural one as far as external characters were concerned. 
But the insufficiency of such a reason, connected with the cir- 
cumstance that the mineral, like the artificial sulphuret of manga- 
nese, dissolves in acids with the evolution of sulphuretted 
hydrogen gas, seems to furnish sufficient ground for suspecting 
the accuracy of Klaproth’s opinion. 

0-494 or. of pulverized manganglanse were heated to redness 
on a thin platinum plate, till they ceased to lose any more 
weight. Native sulphuret of manganese parts more difficultly 
with its sulphur than what is artificially prepared, On that 
account the roasting must be several times repeated, because 
the weight is diminished each time the process is repeated. The 


* Beitrage, iii, 42, 


1824.) the Metallic Sulphates by Hydrogen Gas. 335 


residual oxidum manganoso-manganicum weighed 0°425 gr. It 
dissolved completely in muriatic acid, and the solution was not 
rendered turbid by muriate of barytes, and was found to contain 
no foreign body, except a trace of iron. 0:494 Mn S? are pro- 


portional with 0:434 Mn + 2 Mn; which does not much exceed 
the experimental result. We may conclude from this experi- 
ment that manganglanse is a compound of one atom manganese 
with two atoms sulphur. That the loss of weight was a little 
greater than it ought to have been was a necessary consequence 
of the protocarbonate of manganese mixed with the ore, which 
could not be completely separated, notwithstanding every possi- 
ble care. Even when we find pieces which appear quite pure, 
if we heat them in a little glass capsule, they always become 
spotted with small brown flocks of decomposed carbonate. 

hese may always be easily perceived if we examine the matter 
through a glass. 


Reduction of Sulphate of Zinc by Hydrogen Gas, 


The zinc vitriol employed in these experiments was prepared 
by dissolving pure oxide of zinc in distilled sulphuric acid. The 
salt was moderately heated to render it anhydrous without 
driving off any of the acid. It was then treated with hydrogen 
gas exactly in the same way as the protosulphate of manganese. 
At the same temperature in which that salt was reduced, the 
sulphate of zinc began likewise to be decomposed; sulphurous 
acid and water were given out; and in a short time the reduc- 
tion was completed. A little before that period, the matter 
swelled up and acquired a motion ; at the same time its temper- 
ature augmented, in consequence of which a small portion of 
metallic zinc was sublimed, and attached itself to the upper part 
of the apparatus. . 

The reduced substance was pulverulent and straw-yellow. 
When treated with sulphuretted hydrogen gas a considerable 
portion of water was formed. It dissolved in muriatic acid with 
the evolution of sulphuretted hydrogen gas, and the solution was 
not rendered turbid by muriate of barytes. Hence it~ was 
evidently a mixture of sulphuret and oxide of zinc. 

_ The loss of weight during the reduction of the salt was in three 
careful experiments as follows: In one experiment 0:544 er. of 
zine vitriol left 0°305 gr. or 56:07 per cent. In the next 2:933 
gr. of the salt left 1:708, or 58-23 per cent ; and in the third 
1-166 gr. of salt left 0-664, or 56°95 per cent. 

_ The quantity of oxisulphuret here obtained is greater than it 
ought to be if the compound were analogous to the oxisulphuret 


of manganese ; that is to say, Zn + Zn S$; for 100 parts of 


sulphate of zine correspond by calculation with 52°52 Zn + Zn 
$*, a quantity which deviates considerably from that actually 


336 M. Arfwedson on the Decomposition of [May, 
obtained ; and an equally great, if not a greater deviation would 
result if we suppose that the oxide and sulphuret are combined 
in other atomic proportions. It was observed that a portion of 
the zinc was reduced to the metallic state; but the quantity 
was so small that the amount of the change which. it would 
produce cannot come into calculation. Indeed if it were to 
produce any change upon the result, the obvious consequence 
would be to render the loss of weight a little too high; whereas 
in all the experiments that loss was too small. From the expe- 
riment it is obvious, that the loss of weight is various in different 
experiments, and that it becomes less when the quantity of salt 
operated on is greater. 

' These circumstances taken together might naturally lead to 
the opinion that the sulphate of zinc was more or less completely 
decomposed in the different processes. But as has been already 
stated, a portion of the reduced mass was always dissolved in 
muriatic acid, and tested with muriate of barytes, by which the 
liquid was sometimes rendered slightly opalescent, but not the 
least precipitate ever fell. There might, however, have been 
some circumstance which occasioned the result to come out in- 
accurate, but in what it consisted I cannot say. 

Meanwhile we may conclude from the preceding experiments, 
that when sulphate of zinc is treated with hydrogen gas, the salt 
is decomposed in such a way that somewhat more than the half 
of it becomes sulphuret, and the remainder oxide of zinc; 
though at the same time the proportions of each of these bodies 
do not correspond with any atomic numbers; and experiments 
which do not give corresponding results, are not worth the pains 
of determining the relative proportions of the constituents 
obtained. 


Examination of Native Sulphuret of Zinc, or Zinc-Blende, 


I employed for this analysis « portion of a large piece of erys- 
tallized yellow transparent blende, as the purest variety of that 
mineral met with in nature. 

a. 1758 gr. of pulverized blende were digested with an aqua 
regia, which had been previously gently warmed, so that it began 
to give out chlorine gas.* When the residual mass, coagulated 
into a lump, seemed to be no longer acted on by the acid, it was 
separated and washed. Dried on the stove in a platinum dish, 
it weighed 0°595 gr. Being heated. to redness in a crucible 
much sulphur was driven off, but a portion remained which was 
sulphuret of zinc. It was dissolved in aqua regia, without any 
residue, and the diluted boiling-hot solution was precipitated by 


* T have found that this is the best solvent which can be employed ; for when we 
dissolve blende in nitric acid or in an aqua regia in which no chlorine exists, as when a 
dilute nitric acid is employed, there is always disengaged at first a little sulphuretted: 
hydrogen gas which may be made evident by holding a paper dipped in solution of lead 
over the mouth of the vessel. Po ae 


1824.) = the Metallic Sulphates by Hydrogen Gas. 337 


earbonate of potash, As soon as in consequence of the conti- 
nued application of heat, all excess of carbonic acid was driven 
off, The precipitate was collected on the filter and washed. 
After being heated to redness, there remained 0°146 gr. oxide 
of zinc equivalent to 0°117 gr. of metallic zinc. The remainder 
of the 0°393 er, or 0276, therefore, was sulphur, 

b. The sulphuric acid formed by the first digestion in aqua 
regia was precipitated by muriate of barytes. There were 
obtained 2-288 ers. of sulphate of barytes, equivalent to 0°786 
sulphuric acid, or 0°316 sulphur, 

c. The residual liquid was mixed boiling-hot with carbonate 
of potash, taking the necessary precautions that none of it was 
lost in consequence of the effervescence. When no more car 
bonic acid was disengaged, the carbonate of zinc was collected 
on the filter and washed. When heated to redness, it left 1-311 
gr. of zinc oxide, and, except a trace of iron, it did not appear 
to contain any other substance in solution: 1°31] oxide is equi- 
valent to 1:05 metallic zine. Thus it appears that 1-758 blende 
contain 

Bie dole e ee Te eg ole seg OP hA 
ES RAE 1:050 


er ee 


1-167 
Sulphur a..cccccsoceccevves 0-276 
BEE HE AIS 1 HL 0-316 


Or in 100 parts : 


RINNE? 7, said asa te vou tvta ‘cb las Sed wan a Wiatelahotelee 66°34 
Sulphur . eeeeeeeeeaoveeeeeeevreee eevee 33°66 


100-00 


This is two atoms of sulphur to one atom of zine for Zn : 28 
:: 66°34 : 33:09. 


Sulphate of Cobalt. 


1, 0-639 gramme of pure crystallized sulphate of cobalt ; but 
reviously freed from water by heat, were treated in the way 
already described, with hydrogen gas. At a high temperature 
the salt was easily and rapidly decomposed ; sulphurous acid and 
water were formed ; and a dark grey cohering mass remained, 
which weighed 0°345 gr. In a subsequent experiment, the 
weight remaining from 0-772 gr. of the salt, was 0:412 gr. The 
substance thus obtained dissolved in a great measure in muriatic 
acid, without the extrication of any gas. When the mass was 
heated, it was attacked a little more by the acid, and a little 
in i hydrogen gas was disengaged. The undissolved 
ew Series, VOL, VII. Z 


308 “M. Arfwedson on the Decomposition of (May, 
residue when heated gave out sulphur, and oxide of cobalt 
remained. : 
2. 0°379 gr. of this reduced substance, treated with sulphu- 
retted hydrogen gas, gave out water, and the weight at the 
conclusion of the process was 0'440 gr. In a subsequent expe- 
riment the weight was increased from 0:224 to 0-261 gr. The 
number 0-440 corresponds with 116-09 to the 100 parts, and 
the number 0:261 with 117-04. The water obtained in this pro- 
cess, together with what was said above of the presence of 
sulphur, shows us that the sulphate of cobalt decomposed by 
hydrogen gas becomes likewise an oxisulphuret. 
The residue per cent. when the salt is reduced, amounts in the 
first experiment to 53:99 ; and in the second to 53-24; or at a 


medium to 53°62: but 2 CoS?:Co + Co S*:: 100 : 53:55. 
From this we may conclude, that sulphate of cobalt is decom- 
posed by hydrogen gas in the same way as protosulphate of 
manganese ; or that one-half of the salt is converted into oxide, 
and the other half into sulphuret. The experiments with sulphu- 
retted hydrogen gas ought to, haye corresponded with the fore: 


going result; but this is not the case; for the weizht of Co + 
Co 8? : 2 Co S* :: 100 : 109-7 ; consequently from 100 parts of 
the oxisulphuret I should have obtained 109-7 of sulphuret, 
whereas in the experiments I got as much as 117:04; but I have 
good reasons for presuming that this experiment formed a sul- 
phuret containing more sulphur than Co 8*. Since the cobalt 
pyrites from Riddarhyttan, according to Hisinger’s analysis,* 
consists of cobalt united to three atoms of sulphur. The number 
117-04 agrees nearly with Co S* + CoS’. 


Sulphate of Nickel. 

A portion of pure oxalate of nickel (obtained according to 
Laugier’s method, by adding oxalic acid to a solution of nickel 
not free from cobalt in ammonia) was heated in a small retort 
till it was decomposed. The residual metallic nickel was 
dissolved in dilute sulphuric acid, and evaporated till it yielded 
crystals. " 

1-015 gr. of crystallized sulphate of nickel freed from moisture 
by exposure to heat,}+ were treated with hydrogen gas. This 
salt was decomposed as easily and speedily as the preceding 
salts. At first sulphurous acid and water were evolved, but at 
last the gas which came over had the odour of sulphuretted 
hydrogen. After an hour, even this odour ceased, and the 
apparatus was allowed to cool. The residue of this experiment 
weighed 0°49 gr. and was a pale-yellow cohering mass, which 


* Afhandl.i Fysik, Kemi, &c. iii. 316. 
+ This must be done with caution, because the salt begins to be decomposed at a 
cherry-red heat. : : iB 


1824.7 ‘the Metallic Sulphates by Hydrogen Gas. 339 


here and there seemed to have undergone a commencement of 
fusion. It was brittle, and easily reduced to a powder, which, 
when rubbed against a hard body, gave a whitish-yellow metallic 
streak ; and was attracted rather strongly by the magnet. It 
dissolved in nitric acid, leaving a residue of sulphur. By con- 
centrated muriatic acid, it was slowly attacked, with the evolu- 
tion of sulphuretted hydrogen gas ; but indilute muriatic acid it 
did not seem to dissolve even when the action of the acid was 
assisted by heat. 

The product of this experiment could not be an oxisulphuret, 
because it is well known that the oxide of nickel is reduced to 
the metallic state by hydrogen gas. I must have obtained a 
sulphuret which contained less than two atoms of sulphur, as 
the decomposition of the sulphate of nickel was attended with 
the evolution of both sulphirous acid and sulphuretted hydrogen 
gas. It is to be presumed that the salt lost one atom of sulphur, 
so that the sulphuret of nickel obtained was a compound of one 
atom of each of its elements. Let us see how this supposition 
corresponds with the experiment. 1-015 gr. of sulphate of 
nickel left a residue of 0-49 gr. This corresponds with 48-28 


from the hundred parts ; but the weight of Ni 88: Ni S:: 100: 
48-44. From this it is evident that the sulphuret obtained was 


N, 8. I ought to mention likewise that the reduction of the 
sulphate of nickel should not take place in too high a tempera- 
ture ; for in that case, the sulphuret of nickel melts into lumps, 
in consequence of which an additional portion of sulphur is dissi- 
pated, and the loss of weight turns out too high. | obtained in 
an experiment made in this way from 1-095 sulphate of nickel a 
residue of 0-513 ; yet according to the preceding calculation, it 
ought to weigh 0,53. But I cannot with certainty affirm that 
this additional loss of weight is owing merely to the escape of 
sulphur; for at the time when the matter melts, if the gas which 
escapes be set on fire, it burns with a distinct green flame. 
From this it seems not unlikely that even some of the nickel flies 
off as well as of the sulphur. 

{now wished to Know in what respects this lower combination 


of sulphur with nickel differed from Ni S*. A portion of this: 
second compound, therefore, was prepared by passing sulphuret- 
ted hydrogen over red-hot oxide of nickel. 1-186 gr. of nickel 
oxide gave 1-438 gr. of sulphuret of nickel, which deviates very 


little from the quantity N.S’, which ought by calculation to, 


have been obtained ; for the weight of Ni: N, S® :: 1-186 : 

1-441, This combination of nickel and sulphur was pulverulent, 

Its colour was a somewhat darker-grey than that of the oxide. 

It was not in the least attracted by the magnet. It could not be 
72 


4 


340 M, Arfwedson on the Decomposition of:  [May, 


fused even when) exposed to a higher temperature than was 
necessary to fuse N: 8. Thus the two sulphurets differ in several 
respects from each other. bsddisn stl vs 


Analysis of native Sulphuret of Nickel, or the Mineral called 
Hair Pyrites. ; 

Klaproth, who analyzed this mineral, found it to consist of 
metallic nickel mixed with a little cobalt and arsenic; and this 
conclusion was considered as correct till Prof. Berzelius, a few 
years ago, in consequence of a set of experiments on it by the 
blowpipe, concluded that hair pyrites was not metallic nickel, 
but sulphuret of nickel ; but.as no analysis of it, so far as I know, 
has yet been made, I conceived that the undertaking should not 
be neglected, especially as Prof. Berzelius had the goodness to 
present me for the purpose with a very beautiful piece of that 
rare mineral. ; 

a. 0°222 gr. of needles of hair pyrites freed as much as possi- 
ble from the small fragments of quartz with which they were 
mixed, were digested in aqua regia, as long as any thing was 
dissolved. The solution, together with a small portion of sul- 
phur swimming upon the surface, was decanted off, the quartz 
grains lying at the bottom of the flask. These grains, when 
washed and heated to redness, weighed 0:006 gr. The undis- 
solved sulphur was likewise separated. It weighed, after being 
washed and dried, 0:002 gr. 

b. The solution in aqua regia was precipitated by muriate of 
barytes, and the sulphate of barytes obtained being collected on 
the filter and edulcorated, weighed, after being heated to red- 
ness, 0'524 gr. containing 0°18 sulphuric acid, or 0:072 sulphur. 

c. The residual liquid was freed from barytes by sulphuric 
acid, and then precipitated by caustic potash. The hydrate of 
nickel containing potash was collected on a filter, and washed 
with hot water, till the liquid which passed through ceased to 
leave any residue when evaporaiatl to dryness, It took several 
days to accomplish this. Being then dried and heated to red- 
ness, it was oxide of nickel, and weighed 0°176 gr. equivalent to 
0:139 gr. of metallic nickel. 

A portion of this oxide of nickel was dissolved in muriatic 
acid, and the solution was supersaturated with caustic ammonia. 
By this means the precipitate which appeared at first was dis- 
solved, with the exception of a few inconsiderable flocks, which 
being examined before the blowpipe were found to be alumina 
mixed with oxide of iron. These flocks without doubt owe their 
origin to the stony matter accompanying the hair pyrites. From 
the ammoniacal solution the oxide of nickel was precipitated 
by caustic potash. The residual liquid was colourless, but when 
it was evaporated to dryness, and again redissolved in water, 
there remained a brown powder, which gave a blue glass with 
borax, and consequently was oxide of cobalt ; but the quantity 


a Tn 


1822] — the Metallic Sulphates by Hydrogen Gas. 541 
was so small that it cannot be estimated. Whether this cobalt 

riginated from the matrix, or whether it was really a constitu- 
ént of hair pyrites, cannot be determined. The second conjec- 
ture is not improbable, as all other nickel-minerals contain 
cobalt, 

Another solution of the oxide of nickel in muriatic acid was 
mixed with the liquid remaining after the able Set with 
caustic potash inc. Then a current of sulphuretted hydrogen 
gas was passed through this liquid after it had been mixed with 
a slight excess of muriatic acid. No precipitate fell, but the 
liquid assumed a tint of yellow indicating the presence of a trace 
of arsenic. If we subtract the 0°006 gr. of quartz from the 
0222 gr. of hair pyrites, subjected to analysis, there will remain 
0:216 gr. which is composed of 


Sulphur a....sceceseees 0002 
1 Lee ee 0:072 


er 


0-074 or 34:26 
THIMMRBUIBE Wed ov dic 'e'taetbe sb vie wile 0-139 64:35 


—_—————- 


0213 9861 


An atom of nickel weighs 739°51, and two atoms of sulphur 
402:32 ; but 759-51 : 402°32 :: 64:35 : 35°02. Thus it appears 
that hair pyrites is a compound of one atom of nickel and two 
atoms ofsulphur. It is not in the least affected by the magnet. 


Protosulphate of Iron. 


A determinate portion of pure protosulphate of iron, which 
nad previously, by the cautious application of heat, been 
deprived of its water, was treated with hydrogen gas. The salt 
dxbubited the very same appearances as sulphate of nickel under 
the same circumstances. Sulphurous acid and water first came 
over, and at last sulphuretted hydrogen gas. When the process 
was concluded there remained a dark-grey agglutinated pulve- 
rulent matter, which was strongly attracted by the magnet, and 
dissolved in muriatic acid with the evolution of sulphuretted 
hydrogen gas. The solution was not altered by muriate of 
barytes. 0°858 gr. of anhydrous sulphate of iron, gave 0-396 gr. 
of the new substance : 0:367 er. of this new product were treated 
_ with sulphuretted hydrogen gas. The weight was increased to 
0474 gr.; but not the smallest portion of water was formed, 

showing that sulphate of iron is changed by hydrogen gas into 
a substance which contains no oxygen. 

The experiment with the hydrogen gas was repeated on 
1-012 gr. of sulphate of iron, and the residual matter amounted 
to 0°479 gr. The residue in the first experiment was 46-15 per 
cent. and in the second 47°33 ; the mean of which is 46°74. The 


| 
| 
) 


342 M. Arfwedson on the Decomposition of | [May, 


weight of Fe S?: Fe 8 :: 100 : 46:82. I had thus obtained a 
compound of an equai number of atoms of iron and sulphur; 
and consequently the body contained only half as much sulphur 
as the compound, which we have hitherto called sulphuret of iron 
at minimo. The increase of weight in the experiment with 
sulphuretted hydrogen gas was too great to induce us to admit 
that the product was Fe S°; for the weight of Fe S: Fe S*:: 
0°367 : 0-450; whereas the experiment gave 0°474,. But it is 
known from Prof. Stromeyer’s experiments,* that what we com- 
monly call sulphuret of iron in minimo—a substance which may 
be prepared artificially, and exists also as a natural production 
known under the name of magnetic pyrites, is not Fe S*; but a 
compound which may be represented by the formula Fe S* + 
6 Fe S*, so that it contains more sulphur than Fe S*. The con- 
stituents per cent. of magnetic pyrites are : 


Tron So eee MSU ec evedaev ad OO OD 
UDRP "ont oot t whs seis ¥eielb ele b's bles Oe ae 


- 100-00 


In my experiment, 0°367 Fe S were operated upon, which 
contain 0:283 iron; the sulphuretted hydrogen gas augmented 
the weight to 0:474. This new compound of course contains 
0-283 iron and 0°191 sulphur, or in 100 parts, 59°7 iron and 40-3: 
sulphur. Thus the sulphuretted hydrogen had furnished the 
quantity of sulphur requisite to convert Fe S into magnetic 
pyrites. 


Subsulphate of Iron. 


This salt is obtained, as is known, when a smaller quantity of 
caustic potash is added to a solution of persulphate of iron than 
is requisite to separate the whole of the iron. As it contains 
only one atom acid united to two atoms of the basis, 1 expected 
that the hydrogen gas would have converted it into Fe? 8S. But 
contrary to expectation, sulphurous acid and sulphuretted hydro- 
gen were disengaged during its reduction 0°709 gr. prepared in 
the above described way, and free from water, left for residue 
0-422 er. But a long time elapsed before the sulphuretted 
hydrogen gas ceased to come over, although the mass was kept 
in a full red heat. The matter was in appearance similar to 
metallic iron, such as it is formed when the oxide is reduced by, 
hydrogen gas. It was acted on almost as strongly by the mag- 
net as that, and was semimalleable, but it dissolved in muriatic 
acid with the evolution of sulphuretted hydrogen. The quantity 
of the reduced body, compared with that of the salt employed,. 
shows that the product was a compound of four atoms iron with 
an atom of sulphur, or that the salt lost half ofits sulphur, toge= 


* Gilbert’s Ann, xviii. 186, ) 


1824] the Metallic Sulphates by Hydrogen Gas. 343 


ther with all its oxygen; for the weight of 2 Fe °S : Fe *S:: 
0:709 : 0:420. The residue in the experiment was only a very 
little higher, or 0-422. 

~ Thus to the sulphurets of iron already known, viz. Fe S* and 
Fe S%, we can now add Fe S and Fe* 8; and probably that 
series will be still further increased with Fe *S; so that it will 
be possible to exhibit a sulphate of iron, so constituted that the 
number of atoms of the acid shall be equal to those of the base. 


Sulphate of Lead. 


The salt was decomposed by hydrogen gas with facility, and 
sulphurous acid was disengaged, followed at last by sulphuretted 
hydrogen. The product obtained was a mixture of sulphuret 
and metallic lead, which, towards the end of the process, had 
melted together in small balls, which were quite malleable. On 
the solution of the mass in nitric acid, a considerable portion of 
sulphur was disengaged. 1:294 gr. of sulphate of lead pre- 
viously exposed to a red heat, left fora residue 0:940 gr. Hence 
it appears that a little more than half of the salt is converted 
into metal, and the remainder into sulphuret of lead; for the 


weight of 2 Pb S*: Pb + Pb S*:: 1:294 : 0-952. 

Whether in a higher temperature hydrogen gas cannot change 
the whole sulphate of lead into metal, was not tried; but it is 
less probable, as we see by Berthier’s experiments,* that if 
sulphate of lead be mixed with charcoal powder, and heated in 
a hessian crucible even to whiteness, there always remains a 
mixture of metallic and sulphuretted lead. : 
.. The preceding experiments were tried also with sulphates of 
copper,’ bismuth, tin,,and antimony; but none of these trials 
gave any very remarkable results. The copper and bismuth 
salts were reduced to pure metals. The tin salt gave metallic 
tin still mixed with some sulphuret, and from the antimonial salt 
was obtained a residue of oxidized metallic and sulphuretted 
antimony. 


Articie IV. 


An Analysis of some Minerals. By Aug. Arfwedson.+ 
’ . Cinnamon Stone from Malsjo. 

» Durine a mineralogical journey in Vermland during the 
summer of 1820, Prof. Berzelius met with a. garnet mineral in 
the lime quarry of Masjo, in the neighbourhood of Philspstad, 
* Ann. de Chim. July, 1822, p. 276. ; 

+ Translated from the Kongl. Vetenskaps Academiens Handlingar, for 1822, p. 87, 


344 M. Arfwedson’s Analysis of some Minerals. [Mav, 
which in its external characters bore a strong resemblance to 
the cinnamon stone of Ceylon; and he afterwards, by a compa- 
rative set of experiments before the blowpipe, satisfied himself 
that the two minerals possessed very similar characters. I hope 
by the following analytical experiments to be able to show that 
this mineral comes very near cinnamon stone even in its chemi- 
cal composition. 

By concentrated mutiatic acid, the stone is not in the least 
acted upon, at least not while cold, excepting that the few 
attached fragments of calcareous matter are gradually dissolved. 

1:526 gramme of the mineral purified in this way, and after- 
wards reduced to a fine powder, were heated with three times its 
weight of carbonate of potash. The fused greyish mass was 
dissolved in muriatic acid. There remained a quantity of silica, 
which, after being heated to redness, weighed 0°625 gr. (a). 

The muriatic solution was precipitated with caustic ammonia 
with the usual precautions to prevent the alumina from being 
again dissolved ; and the precipitate which evidently containe 
iron was collected on a filter, and washed with hot water. It 
was again dissolved in muriatic acid, and supersaturated with 
caustic potash ; by which the precipitate which fell at first was 
again redissolved, with the exception of a little oxide of iron, 
which, after exposure to a red heat, weighed 0:067 gr. Bein 
again dissolved in muriatic acid, it was found to contain 0-00 
gr. of silica (6); consequently the weight of the oxide of iron was 
0:06 er. (c). 

From the alkaline solution, the alumina was separated by 
muriatic acid and carbonate of ammonia. Its weight, after 
exposure to a red heat, was 0°321; but when dissolved in 
sulphuric acid, it left 0-007 gr. of silica (d); so that the true 
weight of the alumina is 0°514 (e). 

From the liquid which had been treated with caustic ammonia, 
and which had been again rendered neutral by a few drops of 
muriatic acid, the lime was precipitated by oxalate of ammonia. 
The oxalate of lime obtained was well washed with warm water, 
dried, heated to redness mixed with a little liquid carbonate of 
ammonia, and heated gently till all the ammonia was disengaged. 
The carbonate of lime obtained in this way amounted to 0°920 
gr. equivalent to 0°518 gr. of pure lime (f). 

The liquid thus freed from lime was mixed with a sufficient 
quantity of carbonate of potash, and evaporated to dryness. The 
dry residue when dissolved in water left a substance, which, 
after being exposed to a red heat, weighed 0-006 gr. and which 
possessed the characters of oxide of manganese mixed with a 
little magnesia (g). 

A determinate quantity of the mineral in coarse powder was 
exposed to a red heat in a platinum crucible; but lost no 
weight. 


1824.) M. Arfwedson’s Analysis of some Minerals, 345 


Thus the constituents of the mineral have been found to be : 
Silica (a).. 0°625 
« (6)... 0-007 

(d) ve 0:007 


Per cent. 
0°639 or 41°87 containing oxygen = 21-06 
Alumina eaoerbeeee 0°314 90°57 — 9-60 
esi aa (OS) oad = 9°53 
Oxide of iron .... 0°060 3°93 = 1:20 


Manganese with 
“magnesia....... 0006 0°39 


1537 100°70 
We perceive from this table that the oxygen of the silica is 
equal to that in the bases. Further, that the alumina and lime 
have the same quantity of oxygen, and each eight times as much 
as the oxide of iron. Thus the formula exhibiting the constitu- 
tion of the mineral is FS + 8AS + 8CS. 

Klaproth’s analysis of cinnamon stone from Ceylon gave* 
Bilicaw:. (2idk dative cs vows awed van 2980 
(Alininde vid. bade ena dots cawtagees eae 2120 
Tame b's os oa eidie Dales vert Fad US dea 31:25 
Oxide of iron. ; iss eestissedessteas 650 
i dees vidos views dvs otnRee, TLRS 


100-00 

That result does not deviate far from mine; but as far as 
regards the smallest ingredient, oxide of iron, the considerable 
excess of it occasions quite a different formula. It hecomes FS 
+4084 5AS8.  Itis possible that Klaproth underrates both 
the lime and the alumina, because he separated the former by 
carbonate of soda, and the latter from its solution in potash by 
means of sal ammoniac. His formula, therefore, may bea good 
deal faulty. The formula which I found is considerably simpler, 
and, therefore, more likely to be correct. 

I conceive that we have thus found reason to consider the 
mineral from Malsjo just analyzed as a real cinnamon stone, at 
least as long as Klaproth’s analysis continues unrepeated and 
unconfirmed. 


Brasilian Chrysoberyl. 


Our knowledge of the constituents of this mineral is derived 
from Klaproth’s analysis,+ according to which it is composed of 


MUROMAL) os n5.n ted a URES ERK TAL Od EA 
DADC s wa Kdesk o.clks, RFbs A alhe ae® POE 6:00 
Rade GT Weis «00.6 0.64. Ca enh b.e 008 Stee 
Silica. eee eer e eee eeeeeresesseeree 18-00 


—— 


97°00 
* Beitrage, v. 142, + Ibid. i, 102, 


346 M. Arfwedson’s Analysis of some Minerals. [May, 


- In a set of experiments which Prof. Berzelius made upon 
almost all minerals by means of the blowpipe, he expressed his 
opinion respecting this mineral that it did not contain lime as 
an essential constituent, but that in all probability chrysobery] is 
a pure subsilicate of alumina. 

I have found this opinion confirmed by the following analytical 
experiments. On that account they may deserve to be stated in 
this place. 
Analysis. 

0:614 gramme of the mineral were reduced to a fine powder 
in the agate mortar, and afterwards separated from all the 
coarser particles by washing. This powder was mixed with a’ 
sufficient quantity of caustic potash, and raised to a red heat in 
a silver crucible. After the heat had been kept up a full hour, 
the mass was found in a state of semifusion. It was washed out 
of the vessel with water, and treated in the usual way with 
muriatic acid, which left undissolved 0:238 gr. This residue 
was heated again with potash, and dissolved in muriatic acid. 
The undissolved portion now weighed 0:137 gr. The heating 
with potash was. repeated still another time, and there now 
remained undissolved by. tiie muriatic acid. 0:108 gr. which, on 
examination, proved to.be pure silica.* (a) 

The solutions. in muriatic acid were mixed. with the water 
employed to edulcorate the silica, and the liquid was precipitated 
by caustic ammonia added in as small excess as possible. The 
precipitate, after being well washed, and heated to redness, 
weighed 0:507 gr. When dissolved in sulphuric acid, it left 
0-007 gr. (b) of silica, and the solution gave with caustic potash 
a precipitate, which was again redissolved by an additional dose 
of the potash, with the exception of some flocks of peroxide of 
iron which could not be weighed. The matter dissolved: by the 
sulphuric acid was of course alumina, and its quantity (subtract- 
ing the silica) was 0°500 (c). 

For the greater security, the alkaline solution was saturated 
with muriatic acid, till the precipitate was redissolved, after 
which carbonate of ammonia was added im great excess. Had 
any glucina or yttria existed in the matter, it would have been 
dissolved by this excess of carbonate of ammonia, and would 
have fallen when the filtered liquid was boiled till the excess of 
ammonia was driven off; but the liquid stood this test without 
‘any precipitate appearing. 

The liquid which had been precipitated by caustic ammonia 
was neutralized by muriatic acid, and mixed with some drops of 
oxalate of ammonia; but even after the interval of 12 hours, the 
liquid had not the least appearance of turbidness ; nor could any 


* To satisfy myself whether the silica be pure, I am in the habit of fusing it with a 
good quantity of carbonate of potash. If the fused mass dissolve in water without resi- 
due, I consider. the silica as free from any admixture of foreign earth, _ « 


1824.) M. Arfwedson’s Analysis of some Miierals. 347 


precipitate be produced by boiling it after adding a little carbo- 
nate of potash. 
0-614 gr. of this mineral, therefore, contain 


Aa Cleats hss vas as sre! OILS 
Ce tah Rd 5. os afaon 0-007 
0-115 or 18:73 
Wiiman (eyo Pot 8, AO i ace 0-500 81:43 
0-615 100-16 


_ _ 18°73 silica contain 9:42 oxygen, and 81-43 alumina contain 
38°03 oxygen; but 9:42 x 4 = 37°68. According to these 
proportions, the formula for chrysoberyl is At S. 


Boracite from Liineburg. 

Prof. Stromeyer states in a letter, of which an extract is 
inserted in Gilbert’s Annalen, xviii. 215, that he analyzed this 
mineral, and found it a compound of 67 boracic acid and 33 
magnesia. As Stromeyer’s analyses have in general very justly 
acquired the confidence of the public, we ought not to call their 
accuracy in question upon slight grounds; but as we are still 
ignorant of the method of analysis which he employed, it is the 
more difficult to give implicit confidence to his statement, that. 
all the methods hitherto known for separating boracic acid 
from its combination, only accomplish their object in a very 
imperfect manner. 

n some of my experiments to extract boracic acid from its 
compounds, I found that if a borate (for example, borax) be mixed 
with three or four times its weight of finely pulverized and pure 
fluor spar, together with a sufficient portion of concentrated 
sulphuric acid, and the matter be afterwards heated to dryness, 
and then exposed to a red heat, we can in that way separate the 
whole of the boracic acid in the form of fluoboric acid gas. The 
quantity of the basis being then determined, which it may be 
with precision, we obtain the true composition of the salt sub- 
jected to analysis.* This analytical method may be applied to 
all borates with incombustible bases, as far as they are decom- 
posable by sulphuric acid; and boracite being in this predica- 
ment, I was in hopes that I had it in my power to repeat Stro- 
meyer’s analysis with the prospect of obtaining a correct 
result. 


* In two experiments made in this way, I have found anhydrous borax composed of 


First Exp. Sec. Exp. 
Boracic acid......-. ORGAN o/s 69'2 
Sodhis 2 aes <\geitwie BUA ik enwees 30°8 


100-00 10000 


348 M. Arfwedson’s Analysis of some Minerals. (May, 


In order to free the boracite as completely as possible from 
all admixture of the matrix, consisting of gypsum, a portion of it 
reduced to a fine powder was boiled repeatedly with water. It 
was afterwards collected on the filter, washed, and dried, 

0'849 gramme of it were mixed in a platinum crucible with 
3 grammes of Derbyshire fluor spar in fine powder, made into a 
paste with concentrated sulphuric acid, and then heated till it 
was reduced to dryness, taking the reqquictt precautions to 
avoid the dissipation of any portion from the effervescence, and 
the evolution of the gas which took place. The dry mass was 
then exposed to ared heat. For the greater security, the process 
was repeated, but no fluoboric gas was disengaged; showin 
that the mineral had been completely decomposed by the first 

rocess. 

The sulphate of magnesia was then extracted by water, and 
the undissolved portion was washed so long upon the filter that 
I was sure none of the magnesia remained mixed with the gyp- 
sum. The filtered water was then freed from the gypsum which 
it contained in solution by oxalate of ammonia. It was then 
evaporated to dryness, and exposed to ared heat. The salt thus 
obtained weighed 0°758 gr. and possessed the characters of pure 
sulphate of magnesia. The quantity of magnesia in it amounted 
to 0257, and consequently the remaining 0°592 gr. necessary to 
make up the weight of the boracite must have been boracic 
acid. 

100 parts of boracite then contain 


Boracie: acids be iias sad ess wcidwalees we 69:7 
Magnesias sisseceessssccecsscsscss BOB 


a 


100:0 


Gay-Lussac and Thenard found that boracic acid contains 33 
per cent of oxygen. If this be the case, the oxygen in 69:7 is 
23. 30°3 parts of magnesia contain, on the other hand, 11°73 
parts of oxygen; but 11:75 x 2 = 23-26; so that boracic acid 
contains twice as much oxyyen as magnesia. As long as the 
constitution of boracic acid remains disputed, I will not allege 
this coincidence as a proof of the accuracy of my analysis ; but 
merely as a circumstance from which Gay-Lussac and Thenard’s 
conclusions may receive some support. 


1824.) Mr. Herapath on the Theory of Evaporation. 349 


ARTICLE V. 


Addition to Mr. Herapath’s Theory of Evaporation in the Annals 
for November, 1821, By John Herapath, Esq. 
(To the Editor of the Annals of Philosophy.) 
DEAR SIR, Cranford, April 12, 1824, 

In Prop. 14 of my theory of evaporation, it is said that the 
absolute evaporation is not affected by the pressure of any super- 
incumbent air. This is to be understood of the decomposition 
at the surface of the evaporating body, and not of that escape or 
dispersion of vapour which constitutes apparent evaporation, 
Against the indiscriminate confusion of these things hints are 
given, I believe, in more than one place in my theory ; but my 
_ attention having been recalled to the subject by the kind inqui- 
ries of the Rev. E.W.M. Rice, some views respecting the effects 
of pressure by airs have occurred which I intend here to notice 
iN order to prevent misconception on certain points of my former 
theory. 

If A evaporating surface were placed in an indefinite vacuum, 
it is plain that little, or perhaps none, of the emitted vapour 
would be recondensed on the body, but would expand into 
space. But were any body as an air, for instance, to be con- 
fined over the evaporating body, the particles of this air would 
of course come in contact with many particles of the ascend- 
ing vapour, and striking them in all directions some would 
necessarily be beaten back on the evaporating body. Of these 
a considerable portion would most probably be recondensed, 
But whatever be the number recondensed, they will evidently he 
as the number beaten back to the surface, and they as the num- 
ber struck by the particles of the air. Again the number struck 
in a given time must be as the number of particles of the air 
shiek in the same given time would pass through or strike a 
given space. Now this number multiplied by the momentum of 
a single particle, that is by the temperature of the air, is equal to 
the elastic force of the medium. The number of recondensed 
particles, therefore, or the momentary effect of a superincumbent 
air on the incremental evaporation is as the elasticity of the air 
directly, and its temperature inversely, And as this is demon- 
strated of no particular air, it is true of any air. 

Hence, therefore, if two evaporating bodies of the same kind be 
placed in any two airiform unattracted media, respectively of the 
temperatures of their contained evaporating bodies, the momentary 
effects of the media on the evaporations will be in a ratio com- 
pounded of the elasticities directly, the incremental evaporations 
directly, and the temperatures inversely. 

And if the temperatures are equal, the momentary effects are 


350 Mr. Herapath on the Theory of Evaporation. [May, 
directly as the elasticities and rates of evaporation ; and when the 
elasticities are equal, these effects are inversely as the temperatures, 
and directly as the rates of evaporation. Of course in the same 
fluid at the same temperature, the incremental diminution is as the 
pressure directly. “ 

It would be easy to reduce the above laws to a comprehensive 
integral expression; but as 1 know/not a single experiment with 
which it can be compared, I am not disposed to indulge in useless 
calculations. Besides it appears to me there is another cause 
very ct influencing the quantity of apparent evaporation ; 
and of which [ am likewise destitute of any experiments to afford 
me the least aid towards numerical comparison. It is this. In 
the above views we have regarded the superincumbent air as 
totally devoid of gravitation, and affecting the evaporation by 
its elastic force only. ‘This however seems not to be the whole 
operating cause. Though by our theory, confirmed by expe- 
rience, all airs in contact pretty rapidly intermix, and the rising 
vapour is therefore incessantly intermixing with the surrounding 
air, yet when the temperature is high, the vapour must evidently 
be liberated faster than the dispersion ly intermixture can pro- 
ceed; and consequently the relative specific gravities. of the 
vapour and surrounding air tend much to suppress or elevate the 
vapour. A heavier air would accelerate the ascent of the vapour, 
and by this means contribute to diminish the recondensation ; 
and hence increase the apparent evaporation. But an air as 
light or lighter than the vapour would not favour the vapour’s 
ascent, and would, therefore, diminish the apparent evaporation 
by increasing the recondensation. Consequently if the evapo- 
rating fluid, its temperature, and the pressure of the superincum- 
bent air be the same, the greater the specific gravity of the surround- 
ing air, provided it exceed that of the vapour, the greater the 
apparent evaporation. 

I am not aware that this phenomenon has ever been noticed ; 
but if philosophers who may be engaged on this part of physics 
would have the goodness to attend to these hints, they may pro- 
bably unfold an interesting set of laws, and add something 
perhaps important to our present stock of knowledge. 

Several wavs have occurred to me of evolving the temperature 
in a function of the quantity of water left, sapposing evaporation 
alone to affect the temperature, and that at a given temperature 
there was a given quantity of water; but the utter detect of 
experiments again prevents my proceeding. However: the 
following views of the subject rest on principles so simple and 
susceptible of modification, if experiments should require it, that 
I am induced to give them a place here, if it be only to excite 
philosophers to present us with some experiments on this inte- 
resting part of evaporation. Though in my theory of evaporation 
I have said that the vapour arises from a decomposition at the 
surface, it is evident that no theoretical views only can furmish 


1824.) Mr. Herapath on the Theory of Evaporation. 351 
us with the fact, whether this decomposition takes place at the 
mathematical surface, or at a very small distance beneath ; not 
can we from theory alone decide whether the vapour and its fluid 
have a common temperature, or even nearly so, before the former 
quits the latter. The well-known fact that the vapour freely 
ascending from boiling water is, near the surface of the water, 
not at the very reduced temperature to which the decomposition 
alone would have brought it, but at the temperature of the 
water, tends certainly to favour thisidea. Hence if it be assumed 
that every portion of vapour when it quits the water has the 
Same temperature as the remaining water; and if w be the quan- 
tity of water, ¢ its temperature, and dw the momentary evapora- 


tion, we shall have by Cor. 1, Prop. 20, Annals for Dec. 1821; 
lldw 


6 


for the number of vaporous particles in d w. Therefore, 


tw 6tw 


hai dita woll ahodaietiGa » 
dwt wade CoH 


is the common temperature to which the water and vapour 
would be reduced by the decomposition of dw quantity of water. 
Consequently, 


6tw 5tdw 
dt=t GS Ebbw CNY > aw 
vob dt 5 dw 
aa ead en 


whose integral is ¢ = A w’, 
A being an arbitrary constant equal to 
ty 

Jer, 

Wy G 
where ¢, and w, are known corresponding, or the primitive values 
oft and w. 

If, therefore, the transmission of temperature by water was 
instantaneous, and every portion of vapour had its temperature 
equalized, as soon as formed, with that of the remaining water, 
and then quitted the water entirely, the temperature would be as 
the quantity of water left raised to the sth power; provided 
evaporation only interfered. But we know that water is not 
what is called a perfect conductor of heat, and therefore that the 
above law is not mathematically true. As the evaporation, 
however, is generally but trifling, unless in high temperatures, 
this theorem may probably be found a tolerable approximation. 

Were the number of the particles increased’ in the ratio of 
1 to r by the decomposition, we should have’ 


t=Aw'-'. 


If, therefore, r = 100, ¢ & w%. Hence if « be diminished 
by a hundredth part only, the values of ¢ corresponding to w = 


352 Mr. Herapath on the Theory of Evaporation. [May, 


100 and. w = 99 will have a ratio equal to that of 1 to °36973, 

or 100 to 37 nearly, And therefore if the true temperature 

corresponding to w = 100 be 1172°6 or 212° Fahr. the true 

temperature corresponding to w = 99 will be only 433°5, or 

about — 361° Fahr,; so that here for a loss of weight of only 

ne +isth part, the temperature would be sunk nearly 600° of 
ahr 


We see from the preceding calculation that where the number 
of particles is much increased by the decomposition, a very 
trifling or even an utterly inappreciable loss of weight may 
nevertheless be accompanied by a very considerable diminution 
of temperature. Hence may easily follow the phenomena of 
radiation, and even those of the emission oflight. Indeed lam 
fully convinced from many circumstances that evaporation, 
radiation, and the emission of light, are phenomena similar in 
kind, and governed by similar, but not precisely, the same laws. 
Probably the chief difference lies in the inequality of magnitude 
in the particles when decomposed. Light is most likely the 
particles decomposed into their smallest parts, which, if they 
could be inclosed within a vessel whose pores would not allow 
them a passage, would form a body similar to gas or vapour of 
extreme levity ; and, on the contrary, if vapour was formed in 
vacuo, its particles would fly off in direct lines, like light with a 
great velocity. These views are rendered interesting not merely 
from their simplicity and their reducing to one simple cause 
phenomena apparently so very different as vapour and light, but 
they take from the sun that exorbitant temperature which cer- 
tain philosophers have hitherto supposed it to have, and thus 
render it much more fit for a habitable globe. For since the 
molecules of light are conceived to be many times less than the 
particles of common matter, they would have with only the 
same momentum or temperature a velocity many times greater 
than the latter ; and, therefore, after a particle of common mat- 
ter had been struck by a molecule of light, and was returning to 
the other particles of the body of which it formed a part, it may 
be overtaken and struck again and again before it reached them 
by other molecules, each impulse of which would add to its 
motion, and therefore to the temperature of the body ; andif the 
rays of light be condensed by a mirror or lens on any particular 
body, the probability of this augmented temperature would be 
in proportion to the density of the light. Hence, therefore, the 
sun may in reality have a temperature not higher than that of 
_ any other body of the system, and yet produce all the effects 
attributed to it. This idea comes up nearly to that broached 
by the late Sir W. Herschel, but without the aid of his luminous 
atmosphere. I need, I hope, scarcely observe, that these reite- 
rated impulses by different molecules of light on the same parti- 
cle of matter, do evidently not at all affect the theory of gases 
I have heretofore laid down. 


1824.} M. Rose on Analcime, Copper Pyrites, &c. 353 


It was my intention here to extend the theorems I have 
published in my theory of evaporation, and to add some new 
ones since discovered respecting the “ conducting power” of 

ases, the agreement of which with the experimental laws of 

ulong and Petit, contributes another strong link to the chain 
of evidence adduced in favour of my views; butas I may at some 
period print something in a separate form on the important 
subjects I have discussed in various parts of the Annals, 1 intend 
to reserve these, and other things’ which: I have been able to 
effect in different parts of the physical:sciences, to that oppor- 
tunity. rs 


ArTicLe VI. a taal , 


Chemical. Examination of Analcime, Copper. Pyrites, and ‘Sue 
“A phuret of Bismuth. By M. Rose.* aa sale 


Tae first research into the composition of analcime was made 
. = - . ; DON : > 
by M. Vauquelin. He found this mineral to contain 


Silica sees a ee ee ee ee ee 58°0 
EID at ach oo ss ca can ces bee EOD 
oer. ..... Som ehernceecctc ers es cguiia 
Soda. Step: ay eed eat ha 10-0 
BOM as a ien Sita tc cota oto 2°0 
ea itbabe i tmaprn arabs tg gapepapayg tas ek 
| 96°5 
.The analcime which I analyzed jis found in the valley of Fassa, 
in the Tyrol; the crystals were’ trapezoidal, and Wwére in ‘some 
parts ofa slight'red colour; but’ the analysis inditatéd scarcely 
perceptible traces of oxide of irofi : thé erystals Tvtreltrelishdeen 
and free from other impurities. The analcime reduced to pow- 
der, lost, by being strongly’ heated, 8:27 per cent, of water, 
which was slightly alkaline. By hhéating some fragments to 
redness, th> loss in’ different experiments’ aiiounted to 880, 
8°86, and 8-96" pet cent: The ‘analéime lost its transparency, 
and became a white enamel. By See ee 
The analysis ‘of analcime is’ not complicated, since it is very 
easily decomposed by acids, when it has not been heated, and 
is reduced to powder. On this account it is not requisite to 
employ, nitrate of barytes used ‘by M. Vauquélin, and: which 
always occasions more or less loss. When digested in muviatic 
acid, it formed)a jelly, which was dried, and afterwards treated 
with muriatic acid diluted with water to separate the silica, ‘The 
filtered solution contained neither, lime nor magnesia, and was 


: L : te ie | heron 
* Extracted from the Annales de Chimie et de Physique, tom. xxv, p. 192. 
New Series, vor. vit. 2A 


354 M, Rose on Analcime, [May, 


decomposed by earhonate of ammonia; the precipitate, exeept 
a slight trace of silica and oxide of iron, was dissolyed by 
potash, The solution, after the silica and alumina were sepa- 
rated, was evaporated to dryness, and the residuum was heated 
until all the muriate of ammonia was yolatilized. The residuum 
gave cubic crystals of common salt free from potash, The 
results of the analysis were : 


Silica. PO ere ereeroaeeerereecraces 55:12 
Alumina. ee eeeeeeereverereesvegce 22°99 


Soda. e@evveeeeoen @eeeteerevevreeee eeee 13°53 
Water. Seo se Reser ee 62 2.2 02 8 2 re 2 06 8°27 
99°91 


I found upon trial thatthe white transparent analcime which 
is found in the lava of Catana, in Sicily, was of similar composi- 
tion; but the quantity I possessed was too small to make a com- 
ihe analysis, and the fragments were mixed with carbonate of 

ime. 

I analyzed another analcime from Fassa, different from that 
which I have just mentioned, and I found that its composition 
agreed perfectly with that of the preceding ; the results of the 
analysis were +4 


Silica. Cee eee ee eseeeeseeeeresenees 56°47 
PLOMIMA 5 556 bb sss sos R Edo eeeas » 21:98 
COD Seer er err pee eee fi 
MPGLOV:. 05 WAG Gb as bee Dy kee 8°81 


103-04 


~ This analcime was of a flesh-red colour, on which account the 
name of sarcolite has been given to the analcime of Montecchio 
Maggiore, near Vicenza, and in which M, Vauquelin found __ 


Silica . wee eeaves eee ee ee 50:0 
EMIS Po oe be fares hos We is she “Hades 
ane A pagent i pe pager pe ageing te, 21:0 
Soda and potash. .... e Srey bbe 0ah.b:b. 4a SAL 
wel Mee pnge sate gavel ‘Shine Ae ey Pe 5) 
Tron. bmn neg ab 0.8.9 ahd Ae A C4 alae oS 

} 1000 


I cannot explain the great difference between M. Vauquelin’s 
analysis and mine; I think-I have, however, some reason for 
supposing that the sarcolite which he analyzed was not quite 
pure ; for sometimes the large crystals of analeime which are 
found in the valley of Fassa, are so filled with perfectly well 
defined crystals of apophyllite, that they form almost half the 


1824.) Copper Pyrites, and Sulphuret of Bismuth: 355 


mass. In the crystal of analcime which I analyzed, I found a 
crystal of apophyillite of ‘an inch long. It is sometimes difficult 
to separate the ‘mass’ of tlie analcfme ’ from these crystals of 
apophyllite ;, the latter, however, are discovered by their pearly 
lustre, and especially by their distinct cleavage, which is parallel 
to the plane perpendicular to the axis. It follows nevertheless 
from my analysis, in. which I. could discover ‘neither lime nor 
potash which occur in apophyllite, that the fragments which I 
employed were perfectly free from this substance. 


Copper Pyrites. 


_ There are many analyses of copper pyrites; but they do not 
present any probable formula, and differ from each other. I have 
analyzed three sorts of crystallized copper pytites, and I found in 
all of them the same proportions of constituent parts. 

The analysis of copper pyrites, although very simple, neyer 
gave me results which corresponded with a probable formula, 
when I separated the oxide of iron from the oxide of copper by 
pure ammonia. The oxide of iron precipitated always contained, 
eyen after having been perfectly washed, a considerable quantity 
of oxide of copper, which I could not separate if I did not preci- 
pitate the copper from the muriatic solution of oxide of iron by 
means of sulphuretted hydrogen. i 

I dissolved in each analysis. of copper pyrites, two different 
quantities in agua regia. I precipitated one of the solutions by 
muriate of barytes to determine the quantity: of sulphur by the 
sulphate of barytes obtained, and I poured into the other pure 
ammonia in excess. The oxide of iron precipitated. was heated 
to redness, and dissolved in muriatie acid, which always left a 
small quantity of silica. I then treated, as already mentioned, 
the solution with sulphuretted hydrogen. 

I obtained the fol ering Feanits from two varieties of crystal- 
— copper pyrites from Ramberg, in Sayn, and from Fursten- 

erg : 


bs e244 Ramberg. » Furstenberg, . «> 
Manherey 1s deb’. wlolB4t40 seh oun eork? 
Tron . .(, etaith o- idl). DOME <n rail 30:00 
TS oo eos ol ane BOOS, .s 05000 SiR 
Mameaw NL ya lauds « O:27.....4. 0°39 
101-01 100-03° 


The analysis of the crystallized copper pyrites from Freiberg, 
gave no similar results. 

olin G05» Sulphuret of Bismuth. ‘ 
ma This sulphuret from Riddarhyttan, in Sweden, I found - fo 
possess the same composition as the artificial sulphuret of 


bismuth ; namely, 
a A 2a2 


356 Mr. Walker on some Geometrical Principles [Mavy, 


PHRUPDGL «a's wie « »'5, 5 n8 ateiene o19.04.0 ace EL 
Bismuth. @eeeeoeveeoeoeereeeeeseoeneeen 80:98 


eee 


99°70 
The artificial compound gave 


Sulphur . e@eeovpeteoeeeereeveeeeeoeosenee 18°49 
Bismuth, eeeoeenvavneeovereeeeeeoeven ee 81°51 


100-00 


Note.—In this abridgment of M. Rose’s paper, I have not 
given all his views of the atomic constitution of copper pyrites ; 
for as he adopts the numbers of Berzelius in which the weight of 
the atom of iron is double that generally admitted in this country, 
the statements would be useless. He considers its probable 
composition as one atom of sulphuret of copper with three atoms 
of sulphuret of iron. It will, however, appear, that his analysis 
of copper pyrites from Ramberg comes more nearly than mine to 
what I have supposed to be the atomic constitution of this com 
pound ; namely, a compound of two atoms of protosulphuret of 
iron and one atom of persulphuret of copper, or in 100 parts of 


Copper) ao 00 ojcjsieie bis oiaie's ees o elev B478 
Tron ececesesccee eowres er ee eeeeeoe 30°44 
Sulphur pcisc seni waatabea’ eehy ae OB 


100:00 
(See Annals, N.S. vol. iii. p. 301.)— Edit. 


ArticLeE VII. 


A Memoir on some Geometrical Principles connected with the 
Trisection of an Arc. By John Walker, Esq. formerly Fellow 
of Trinity College, Dublin. (With a Plate.) 


(To the Editor of the Annals of Philosophy.) 


SIR, April 14, 1824. 

THE following propositions I believe are new ; and, if I mis- 
take not, they either extend, or promise to extend, the limits of 
Plane Geometry. 

It has long seemed to me, that the moderns have too much 
abandoned the attempt of trisecting an arc, by the right line and 
circle. We know with what ardour the solution of that problem 
was sought by the ancient mathematicians ; as well as how con- 
siderably the science was advanced by their investigations, 


AUS PLATE XXVH 
' 
| 
} 
} 
| \ 
i 
Ay 
) 
—— 
} 


Fig.l 


“e 


& 


nb 


Fig dO. 


Ni 


1824.) ‘ connected with the Trisection of an Arc. 357 


though they failed of arriving at the ultimate object which they 
ae And I believe that geometrical science would not 
have remained as stationary, as it has been for many years, if the 
problem had continued to share the attention of modern geome- 
ters. 

But nothing so much paralyzes exertion as despondency of 
success; and I amaware that some of the most profound mathe- 
maticians of the present day do not hesitate to pronounce, that 
the problem alluded to is impossible. ‘Their assertion is, I think, 
unwarrantable and rash. If I may hazard an opinion, in which 
many will think me over sanguine, I avow iy expectation that 
some of the principles, which I offer in this Memoir, will yet lead 
to the solution of that problem; though I am now obliged to 
dismiss the subject from my mind, on account of other avoca~- 
tions and declining health, 


Prop.I. Prosiem, (Plate XXVIL.) Fig. 1. 


‘In a given segment of a circle to inscribe a triangle, whose 
sides shall be in arithmetical progression. 

Let the given segment be A ba. From B, the vertex of the 
opposite segment, draw the lines BT, Bt, trisecting A a in T 
and t, and meeting the periphery in E and e. From A inscribe 
the chord A x equal to Ee; and draw ax. Isay that Axa is 
the triangle required. 

Dem.—Let y be the point in which a z intersects Ee. Draw 
T y: and parallel to this draw x x, meeting A a in z, and inter- 
secting Eeins. Lastly, draw EzandsT. I shall now prove 
that a x is equal to a x, and that E x is perpendicular to A a; 
Ee 
ry 
fore an arithmetical mean between A a and Eg, i. e. between 
AaandAx. — 

For the triangles B T ¢, at F are similar [having the angles at 
equal, and also the angles at B and a, as standing upon equal 
ares]. «. Bé: Té:: (at)Tt:¢F. .. rectangle Bé F = 
T#; and2BiF=2T ¢ = rectangle Ata= Bie. «.te 
is bisected in F. .-. the similar triangles at F, ye F are mutually 
equilateral, and ye = at = Tt. .*. et 1s parallel to yT, 
and ..tovz. .#.ax2=azx. But also Ey is bisected in s [for 
the triangles* E y x,a ye, and x ys, F y e, being similar, E y : 
(yuyyss:ay:(yeyk: 2.1) +. Es = 2zT, and Ez is 
parallel tos T, and perpendicular to Ee. ..a% (ora D + Dz) 
pe A , 

Lear = —- + =— oft". ». axis an arithmetical mean 


between AaandAxv. Q.E.D. 
_ Cor... (Fig. 2.)—The lines A 6, a b trisect the line Ee; for 
since the line ¢¢ bisects the angle Aea,Ae:(ae) AE: At: 


whence it will follow that a z, orar = ah + —, and is there- 


* The lines E x, ¢ a, are not drawn in the figure, but may be easily supposed. 


358 Mr. Walker on some Geometrical Principles [May, 
dt::2:1. «A }b, bisecting the angle E A e, cuts E é into 
Segments in the saine ratio. verge 

Cor. 2. (Fig. 3.)—Drawing the diameter E p, andthe line A Ps 
the latter bisects the radius B cin q, and trisects B Ein 7. Let 
N be the point in which E P, perpendicular to E e, intersects 
Ap. The triangles E N p, ey a are similar [for the angles at p 
and a stand on equal arcs, as also the angles N Ep and A az; 
but Agr Saye). «EN: Epi: ge:y ai: 1:12. +) BN 
= radius. ..cq = semiradius. But the triangles EN?r,Bgr 
are similar. .-, Ey :7 Bi: EN:q B::2:1. +. EB is trisected 
inr. It is plain, that if from E we draw E g parallel to A p, it 
must bisect the radius  c in Q. hihi 

Cor. 3. (Fig. 3.)\—Drawing through Q an ordinate (which is 
the base of an inscribed equilateral triangle), the lines Be, 6 ¢ 
intersect this ordinate in the same point 0. For the ates A E, 
Pp g being equal, as also the arcs E b, p B, .. the arcAb = Beg. 
-. 6g is parallel to AB. «+. the triangle BA’) is isosceles. 
But its altitude hc is trisected by Be [as Be trisects a DJ. 
-", the side 6 h is bisected by Be ino, [For universally, if from 
an angle at the base of an isosceles triangle a line be drawh cut- 
ting the altitude and leg, the segments of the leg are to each 
other as the upper segment of the altitude to twice its lower 
Segment.] But the ordinate through Q, the middle point of b ¢, 
must also bisect bh. .. &e. ; 

~ Cor. 4. (Fig 4.)—Let i be the point in which the perpendicu- 

lar from e meets a B. Ei? is parallel to A B. For drawing 2 I 
perallel to A a, and cutting B 53 in #, this parallel is trisected in 
r; and from the similarity of the triangles EIr, Bar, B E 18 
also trisected in r. .*. the triangles Br I, Eri are similar, 
~.1 Band Eiare parallel. an 

Scholium.—tIn the assigned solution of the preceding problem, 
the base of the given segment is always one of the extreme sides 
of the triangle ; and the other extreme is the chord of the are 
intercepted by the trisecting lines. But»if the given segment 
contain an angle of Jess than 60°, its base may be the middle 
sidé-of-an inscribed triangle, having its sides in arithmetical 
progression. - And from what has been established, it is plain 
how we may construct that triangle. Let a w (fig. 3) be given as 
the middle side of such a triangle, in the segment a Ba. Then 
we havé e, the middle point of the arc a x. .*. we have P; the 
opposite extremity of the diameter ec P; and «. we have a P, 
But we havé seen (Cor. 2) that a P bisects the radius Being, 
If, therefore, with the centre.c, and the interval of the semiradius, 
we describe a circle, its occurse with a P determines the point 
q- ~. we have the diameter B 0, and .*.its ordinate a A, one of 
the extreme sides of the triangle ;_ the greatest or the least, 
according to the’ point: of intersection of the destribéd  citclé 
with the line a P, through which we draw the diameter. 


1824.] connected with the Trisection of an Arc. 359 
Prop. Il. Prosiem. (Fig. 3.) 


In a given circle to inscribe a triangle, whose sides shall be in 
arithmetical progression, and their common difference equal to 
a given line. 

he solution of this problem also is obvious, from what we 
have established in solving the former. For there we have seen 
that A x is the common difference of the sides, and (Cor. 2) that 
E N isequalto radius. Therefore, given the radius and common 
difference of the sides, we can construct the right-angled triangle 
AEN, having one of its sides inscribed in the circle, its hy- 
potenuse E N equal to radius, and its altitude A x equal to the 
given common difference. This line A x produced gives the 
greatest side A a; whence we have the other two. 

Scholium.—W henever the given common difference is less than 
half the radius, we may find two different triangles to solve the 
problem; for either of the unequal sides, A Eor AN, may be 
inscribed in the circle. Itis plain that A z is amaximum, when 
equal to haitf EN; that is, that the semiradius is the greatest 
possible common difference of the sides. 

Putting unity for radius, the triangle of whose sides the com- 
mon difference is a maximum, is ) 

VT+h VT VIT=1~ 

ABA Caer A Be + 
the cosine of whose middle angle is ¢. And it may here be 
briefly remarked, that in the two different triangles, whose sides 
have any smaller common difference, half the sum of the cosines 
of the middle anglesis3._ Also, the sum of the two least angles 
is the supplement of the sum of the two greatest; and is the 
third part of the difference between the sum of the greatest and 
the sum of the middle angles : just as in the triangle 


A AE ee ae AP a: Gee | 
Bi 2) Wwe ee 


the léast angle is the complement of the greatest, and is third 
part of the difference between the other two. 

any other and curious properties of these triangles might be 
stated ; but we must hasten at present to other matter. 


Prop. III. (Fig. 5.) 

If on the same base A a there be two isosceles triangles, 
whose vertical angles A Ba, A Ea are as three to two; and 
from the vertex of the smaller angle lines be drawn (E T, E ¢) 
trisecting the common base; these lines will trisect (A 6 a) the 
are iH the circumscribing circle on which the gréater angle 
stands. 

Dem.—Produce the altitude E 0, and let 0g = 0 E. Draw 
e A, and produce it to f. ET trisecting the altitudé of the 
isosceles triangle E Ae must bisect the leg A ein D. Draw Dd 
parallel to e E; also the radius A ¢, cutting ET in m, and D d 


360 Mr. Walker on some Geometrical. Principles [May, 


inn. Lastly, from the centre c, and parallel to A E, draw c Y 
meeting E T in Y; which point we shall prove to be in the peri- 
phery of the circle. . 

From the similarity of the triangles cm Y, Am E, cm: Am 
::¢ Y:A E. But we shall prove that cm: Am:: Ac: AE; 
and .*. that Ac = c Y. For the triangles cm E, mn D, being 


v4 : - Am—cm ec 
similar, ¢m:mnis¢ E: Dn; thatis, ¢ m:—>— 3: ckh:— 


oC ms A’m’::’c' EY Eve. > But'e BH’: E es: Ac’: Ave “on ac- 
count of the bisection of the angle f A c by the line A E}]. .*. cm 
:Am:Ac:(Ae)AE. But we have before seen that cm: 
Am:cY:AE. «.cY = Ac,and the point Y is in the peri- 
phery. But the angle 6c Y being equal to b E A, that is, to the 
ie part of A B a, the line ET Y trisects the arc A bain Y. 
QE. -D. 
Cor. 1. (Fig. 6.)\—If from p, the point where A c meets a E, 
the line p d be drawn to the middle point of AE, and ‘be pro- 
duced on each side to meet the periphery in @ and q; the line 
adpq is the side ofan equilateral triangle inscribed in the circle 
A Bab; and if the lines Ee, Eq be produced to meet the 
circle A Eaein mand x, the triangle E m » is an equilateral 
triangle inscribed in that circle. 
For the triangle A p Eis isosceles [for anglep AE =cAB 
+BAE=BEA+2BAE=2BEA=A Ep]. -.pdis 
perpendicular to A E, and .°. bisects the parallel radius’ c x per- 
pendicularly. .. @q is the side of an equilateral triangle, of 


which Y o is the altitude. Now drawing the line A e, it must 
pass through y [fora Ae =aEKe= “ks Sa ys Ay is 
parallel to pd; and ...E y, the hypotenuse of the right-angled 
triangle E Ay, is bisected by pd. But it is also bisected by 
Yr. .«.Ey and eq bisect each other ino. «.@Eqy isa 
parallelogram. .*. the angles @ Ec and q Ec are each of them 
30° [for@Ec =aEKy—yEb=qyE—rcyE=qyr= 
30°, and in' like manner, gEc=qEy+yEHKb=eyE+ 
vyE = qyx = 30°). .«. mEn is an equilateral triangle 
inscribed in the circle A Ea e. . 
Cor. 2.—The arc B @ is the third part of A @ B, and Bg the 
third part of Aa B. For @ Y q being an equilateral triangle, 
arc ¢ Y.=2e¢2.: BatAY =2Br. -.@¢Y —AY =2a@B. 
‘. &c. Inlikemannerg Y +AY=AYq=2Bq-s &c.. 
Cor. 3.—If from c be drawn a parallel to A a, meeting A Ein 
‘k, and Y Ein J, Y dis the third part of YE. For the triangles 
oz Eandcx k are each of them isosceles. .*.k E = diameter. 
But from the similarity of the triangles k7 E, cl Y, YU: 1 E ::. 
cY¥:kE::1:2...&c. It is plain that ¢z must cut off another 
third part of E Y.. Also, thatck= Y y. 
_ Cor. 4.—Producing A cand A B to meet the circle AE ae in 
rand s,the chord E ris equal to A a; and the semicircular arc 


1824.) -connected with the Trisection of an Arc. « 36] 
t BK wis bisected ins. For angle AEa = E Ar, the-triangle 
A pE being isosceles. «. Ad@= Er. But arcE¢ = = and 


Ae EAe 
arc Es= >. .. aro¢ s = —>— = quadrant. 


Cor. 5. (Fig. 7.)—If B f be drawn parallel to A E, it is equal 
to Ec. For drawing f g parallel to the axis, and meeting A E 
ing, f g = g Z, on account of the equality of the angles ¢ Z f, 
ei 2..-- fig + Be orhay=@Zit.BZ=Bf. - 


Prop. IV. (Fig. 7.) 


The same things being supposed, Er the segment of the tri- 
secting line intercepted between the two circles is the third part 
of EX, the segment of it included in the circle A E ae. 

Dem.—Draw An, making the angle EAn = AEz, and 
cutting E X ins. The triangles HA n, A E x being identical, 
An=Ex=EX. But E X trisecting A a, and being parallel 


to an, trisects An. .*. As being equal to > XO = a. But 
As, and ..s X, =s 7, the angles at the base of the triangle 
Asr being equal. [For angle Ars = *2"=AEe. Butit 


alsoequals AEr + EAr. «. angle EAr =X Ee. .. angle 
rAs,rEAn—EAr, =AEX—xvEe=AEe=Ars}. 
EX 


Cor.—Drawing arv, rv = > For the triangle a7 X is simi- 
lar to A E a [for angle ar X=A Ea, and angle rX a= EAa]. 
en 7 X, and rv = Er. 2. Re 

Scholium.—It is plain that A » bisects Ey ino; since Ao = 
E o, and the angle E A y is a right angle. 

ES 


Prop. V. (Fig. 7.) 


- The same things being supposed, if there be drawn a diameter 
of the circle A Ea e perpendicular to the axis, and meeting the 
circle A Ba bin T, the line E T isa tangent, and equal to Et, 
the line drawn from E to the point where z Z produced meets 
the circle AE ae. ; 

For a Z passes through k, the centre of the circle A Ea e; and 
the triangle Z k c is isosceles, and similar to the triangle E Z c. 
“6B: oL:¢0Z:¢k; thatis,cE +c TacT ck... the 
angle c T Eis a right angle, and ET a tangent. », ET? = 
(CBKLER= (+ Ek) = (Ed. Ey be. BTS 
Et. 

Cor.—Henee it appears, that ifc T E. be a right-angled trian- 
gle, in which from the right. angle the perpendicular T kK is let 


362 Mr. Walker on some Geometrical Principles [MAy, 
fall on the hypotenuse ; and if with c as the centre, and the side 
c Tasradius, a circle be described, and another circle, with k as 
the centre and the remote segment k E as radius, intersecting 
the former in the points A and a; the angles A Ea and A Ba 
are as two to three. That the circles may intersect, the side cT 
must be more than half the hypotenuse ; or the angle c ET must 
be more than 50°. 


Prop. VI. (Fig. 8.) 


The same things being supposed, the line Y x, joining the 
point of trisection in the arc A 6 a with the point in which the 
other trisecting line meets the circle A Eae, is a tangent to 
the circle A Eaé, and is equal to Yy, the chord of are +2 

For the line A Y is a tangentat A, the anglea A Y being equal 
to Bots. “=AEa. .».A/Y, or Y y, is a mean proportional 
between E Y and X Y, that is between Ey and xy. .-. the tti- 
angle y Y x is similar to the triangle YEy. ..Y x= Yy, and 
is a tangent at x, the angle z x E being equal toE X x. 

Cor. }.—Let there be drawn B m, B n parallel to the trisecting 
lines ; and let @ q be the base of an inscribed equilateral triangle 
parallel to A a :—then the arc m @ is the third part ofz a7, and 
therefore m q the third part of Ar. For the trang YEy, 
y Y x being similar isosceles triangles, the angle E Y x (stand- 
ing on thearczar) = EYy—YEy = Ban — mBn. 
s.arczar=naB— 2bn. But arc xa B = semicircular 
zar_ Bb 

3 


arcBb—bn w.arczar=Bb—3Bobdn. -. 


= bq —bn=nq, or me. 

Cor. 2.—B m is equal to yr; and y 7 passes through &, the 
centre of the circle AE ae. Forarce BAm=BAY +Ym 
= Bay+Br=ray...Bm=ry. But we have seen that 
Xy=ay. «.ky bisects aX perpendicularly. .. angle a ky = 
ekX aE X. Andangleake = aE A. s.angleyke = 
AEX. But the same is the value of the angle which r y makes 
with the axis. For the sum of that angle and YE6 = Yry 
=AEb=AEY+ YEO. -.1r y passes through &. 


Prop. VII. (Fig. 9.) 


In the produced diameter of a given circle A Ba Jb, let E be 
any point whose distance from the vertex is less than radius ; 
and from E to the extremities of the normal diameter, let there 
be drawn the lines E D, Ed, cutting the circle in the points 
mandn. Let k be the point in which the lines Dn, dm cut 
the axis; and with the centre / and the interval k E let a circlé 
be described cutting the given circle in the points A, a. Then 
the angle A Ea is two-thirds of the angle A Ba. dl 


1824] connected with the Triséction of ah Are. 363 

Dem.—Draw the radii Ac, Ak. The triangle ck D is similar 
to the triangle c D E, each being similartodn D: .«. Ec; ¢ D, 
c & are in continued proportion, that is, Ec, c A, ck... the 
triangle c k Ais similarto c AE. .«.anglec AkK=AEc= 


mee But angle Acb,orABa,=cAk+ckA=3cAk 


=3AEc. «.ancleA Ba = "4 


2 


Prop. VIII. (Fig. 10.) 


If the angles A Ea, A ea be two-thirds respectively of the 
angles A Ba, A ba, and if there be drawn from E and é the 
lines E T, e ¢, each making an angle of 30° with the axis; these 
lines meet each other in the periphery of the circle A Ba b. 

Dem.—The lines E T, e ¢ trisect the ates A Ba, Aba 
respectively in T and ¢(see Cor. 1, Prop. III). Let the line ET 
meet the circle again in C, and draw the ordinate C ce. The 
angle C Bc = 60° + *2* [for CB = CES +4 BCE = 30° 
a eas &e. |. In like manner, the angle at b subtended by 


the ordinate drawn through the point in which e ¢ again meets 


the circle is equal to 60° + ass. But the two angles 60° + 


Ab AB 
—~ and 60° + ——~ 
3 3 

Aba 
3 


mer angle (60° + =~) being equal to C Bc, the latter (60° + 


set *) must be equalto C bc... the ordinate drawn through the 


point in which e ¢ again meets the circle coincides with C c, and 
e¢ meets E T inC. 

Cor. 1.—The sum of the angles A Ee, Ae E being 60° [as 
they are respectively the thirds of two aa spn angles], it 
follows that the angle EAe = 120° = ECe. Therefore a 
circle described with the centre c and radius c C must cireum- 
scribe the triangle E Ae. And in that circle E e¢ is the side of 
an equilateral triangle. ; 

Cor. 2.—Producing A a to meet the circle A ED ¢ in d, the 
angle AEd = 30° + AEa. Foranglec EA =D Ed, each 
of them being equal to C E A. .. angled Ea = D Ee = 30°. 
But angle AE =dEa+AEHa= 30° +. AEa, 

From the principles which have been established, we should 
be warranted immediately to infer the following proposition. 
But I think it expedient to demonstrate its truth independently 
of the preceding theorems. 


are supplemental to each other, the angles 


and “= being together equal to 60°. Therefore, the for- 


364 On the Crystalline Forms of Artificial Salts. [May, 


Prop. IX. (Fig. 11.) 


- If Ee be the side of an equilateral triangle inscribed in the 
circle whose centre is c, and A 6 any chord intersecting it per- 
pendicularly ino; assuming 0 a equal to A o, and drawing the 
radius c a z, I say that the angle at the periphery A E e is the 
third part of the angle at the centre a c z. ofS 
Draw e r perpendicular to E e, and therefore equal to radius. 
Then a 6 = er [for drawing 7 s perpendicular to A 4, it is plain 
thatab =os = er]. Since therefore the three lines er, ab, 
c D are equal and parallel, the lines ec and r D, ac and 6 D are 
Ace. YT 
2 


parallel, .».angleecz =rDb= AEe= 
AEe =*22, QED. 


‘I here dismiss the subject for the present, probably for ever ; 
yet not without a hope that some other qualified person may be 
induced to pursue the train of investigation, which I have 
pointed out. I have hazarded the expression of my opinion, 
that it will yet lead to the trisection of an arc by plane geome- 
try. I even suspect that I see how the trisection of the arc 
A ed (fig. 10) may be derived from the trisection of the are A ba. 
‘But I must resign it into other hands. . 


Pte Ce. Or 


Articte VIII. 


On the Crystalline Forms of Artificial Salts. 
By H.J. Brooke, Esq. FRS. 
(Continued from p. 288.) 

Perchloride of Carbon, 


I am indebted for these crystals to Mr. Faraday. Their 
planes, although very brilliant while inclosed in the bottle on 
whose sides they have been deposited, soon become dull on 
exposure to the air. I have not found them 
cleavable im any direction, but a right rhom- 
bic prism may - regarded as their primary 


form. 
P ani Mor: Myce a a nd ODE i iO! 
P om dd cis olaric - 119 40 
Pot Bea As th a cdere. 90. O 
e;0n Rh Ab ux. bdbsfencs 150 20 
M onAl his ii I QE. am 122. 4.0 
M onbiyulak! ste. seed 219140 


. Muriate of Cobalt. 
These crystals, which I have receiyed from Mr. Cooper, may 


1824.) Apparatus for producing Instantaneous Light. 365 


be cleaved with ease parallel to the terminal plane P, and less. 
distinctly parallel to M and M’ of the annexed figure. Hence 
an oblique rhombic prism appears to be its Oh op 
primary form. . € a 
P on M, or M’. .,.... 109° 31’ “wR 
Pion h.,. so. lick. wavtad 122,120 ft] 
Poon’ é.ecweces.se- 106 20 
Fe ON Caio hivtoeiciev epee LBL .20 
M on Aaj paiels be ee ehiee 128), A0 
OF PMO 68 oasis opisiash 217% 120 


Acetate of Barytes. 
From the crystals of this salt with which Mr. Cooper has sup- 
plied me, it appears that the primary form is @ right oblique- 
angled prism. There is a bright cleavage 


parallel to T, one less bright parallel to M, a! 
and an indistinct one perpendicular to 
these. 


7 
Meee Ly eis cnnnh aay 146° 18” f 
BOTT) ons omar a ds 113 12 
_ oe aghereiigtale .. 116 56 
SE CE a MN | 


ArTICLE IX. 


Apparatus for producing Instantaneous Light. By the Rev. 
‘i’ Cumming, MA. FRS. Professor of Chemistry in the Uni- 
versity of Cambridge. ) io 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, Cambridge, April 15, 1824, 


In the early part of last December, I exhibited to our Society 
Doebereiner’s experiment, of the inflammation of hydrogen in 
atmospheric air by precipitated platina ; and from that time to 
the present have occasionally employed the same apparatus for 
producing an instantaneous light. The method I have used is 
so simple, that I should not have thought it worth communicat- 
ing, if [ had not been told that the instruments made in London 
for this purpose lose their effect after a few experiments. 

Having removed the electrical apparatus from a Volta’s lamp, 
I pi a fragment of precipitated platina between two pieces 
of watch spring, which are inserted into a cork fitting mto a 


small test tube as a cap. The distance of the platina from the 


366 - Mr, Brooke on Nuttallite. \ [hays 


jet is about: three-quarters of an inch, and a small wax taper is 
fixed about half an inch beyond the platina. . 
The only precautions I have found necessary are, to replace 
the cap immediately after each experiment, and to employ a 
pressure upon the hydrogen of not less than five or six inches of 
water, With a pressure of nine inches I have never failed in 
producing the same effect from platina foil of ,4,> inch in 
thickness, by using the precaution of keeping it in a closed 
tube; but when the thickness of the platina. foil was >>, it 
required to be previously raised to nearly a red heat. 

’ The experiment of the aphlogistic. lamp. may be exhibited to 
great advantage by employing either precipitated plata or 
platina foil suspended over the wick, instead of wire, as origi- 
nally proposed. . Lam, dear Sir, truly yours, . 

' J, CuMMING, 


P. 8, By the kindness of our late Woodwardian Professor, 
Mr, Hailstone, I have been favoured with some fragments of 
titanium formed in iron slag, for the purpose of ascertaining its 
place in the thermoelectric series ; which I find to be between 
platina and silver, but have not as yet been able to determine 
its precise situation with respect to the intermediate metals, 


ARTICLE X., 


On the Nuttallite, anew Mineral from Bolton, in Massachussetts. 
| By H. J. Brooke, Esq. FRS. &c. 


(To the Editor of the Annals of Philosophy.) 


DEAR SIR, April 20, 1824. 

I HAVE received from my friend Mr, Heuland a small specimen 
of a mineral from Bolton, in Massachussetts, brought by Mr. 
Nuttall to this country. 

It had been named elaeolite, I suppose from its exhibiting a 
play of light resembling that which is frequently seen in the 
fettstein from Norway, and from its colour generally approaching 
to that of the same mineral; some fragments are, however, 
neatly transparent and colourless. On examining the crystals, 
which are imbedded in carbonate of lime, I find that they differ 
both in cleavage and lustre from elaeolite, and that they are 
much softer. They present the form of a right square prism 
which may be regarded as the primary, with cleavages paralle 
to its lateral planes. The lateral edges of this prism are replaced 
by single planes, but the terminal planes are imperfect. : 

It is softer and much more glassy in its fracture than scapolite, 


1824,} Dr, Berger’s reply to Mr. Henslow, 367 


for which, on agcount of its form, it might be mistaken, and 
does not resemble any other mineral with which I am acquainted, 
I have, therefore, named it Nuttallite, out of respect to the 
gentleman who brought it to this country. 

I hope at some future time to be enabled to describe it 
more fully than I do from the minute crystals my specimen 
contains. 


ArtTIcLE XI, 


Reply to Mr. Henslow’s Observations on Dr. Berger’s Account 
_ of the Isle of Man. By J. F. Berger, MD. 


(To the Editor of the Annals of Philosophy.) 


SIR, Geneva, March 9, 1824. 

BeiNe engaged a short time since in some researches at the 
public library of our city, I there met with the second part of the 
fifth volume of the Transactions of the Geological Society of 
London, the 27th article of which is entitled Supplementary 
Observations to Dr. Berger’s Account of the Isle of Man, by 
J. 8. Henslow, Esq. MGS, Unless I deceive myself it is the 
business of him whom a criticism especially concerns, either to 
profit by a reasonable and impartial criticism, or to animadvert 
upon that which is not true, or dictated by the malignity of 


envy. 

The charge of having published a memoir from ‘‘ loose memo-~ 
randa,* is of so grave a nature, that Mr. Henslow ought to have 
satisfied himself that it was well founded, or to have named the 
persons from whom he received the information.}+ If Mr. H. had 
taken the trouble to write to me upon this subject, I should have 
replied, without in any way discouraging a criticism upon a pub- 
lished memoir, that 1 had remained in the Isle of Man only from 
the 1st of June until the 8th of July, 1811, and that it was on m 
return from Ireland to London, in the beginning of 1813, that i 
drew up the memoir published in the second volume of the Trans- 
actions of the Geological Society, from notes actually made on the 
spot ; and with the exception of Mr. Thomas Webster, Draughts- 
man to the Society, I cols no recollection that any member of 
the Society ever saw these notes, for no-opportunity of showing 


__® After haying finished, as much as depended upon myself, the geological examination 
of this Isle, fearing that my notes originally written in pencil, might be obliterated, it 
occurred to me to fix the plumbago upon the paper by a process well known to artis 
by moistening with a sponge dipped in milk, the leaves of my book, which I ie 
and which from that time were loose sheets. 

t Ne quid falsi audcat, ne quid veri non audeat dicere. 


368 Dr. Berger's reply to Mr. Henslow. (May, 


them presented itself. Mr. Webster obligingly lent me his 
assistance in preparing the map and sections which accompany 
my memoir,* but it is true that I did not-consult him on subjects 
which were not in his department. ~ pita 

It will be readily conceived that I had not the means of ascer- 
taining whether the southern part of the chain of mountains is 
placed in my map of the Isle of Man two or three miles too far 
to the east, according to the opinion of Mr. Henslow (p. 483). 
This fault may exist, and probably is not the only one. I 
regarded this document merely as a geological map, without 
absurdly pretending to dedicate it to. geographical engineers.+ 
I will only add, that, in my opinion, it is better as a topographi- 
cal map of the mountainous part than those of my predecessors, 
and that in publishing his own, Mr. H. has not rendered mine 
useless, or superfluous. 

I must confess 1 was surprised on reading (p. 482), that I had 
omitted to mention several formations of rocks, being persuaded 
that I had inspected them all, with greater or less brevity, except 
those which are volcanic. I was fearful that some unquestion- 
able trace of volcanos, either extinct, orin activity, had escaped 
me, but I was not long in recovering from this apprehension, 
by observing that my critic, and | do not attach the same idea, 
to what‘is called a formation of rocks, and that Mr. H. applies 
this term to objects which are of very secondary importance.{ | 

Mr. Henslow has found granite im situ in other places than 
those which I have mentioned, and he has also traced its course 
further in another direction than I have done. But did this 
require for its narration more than three quarto pages? The rock 
called greywacke,§ by those who adopt the principles of Werner, 
is remarkable in this respect, that bemg composed of the remains 
of ancient rocks, it expresses a formation of modern date, which 

is supposed to have occurred by deposition, rather than by che- 
ot rodet 

. \® Ihave publicly acknowledged my obligation to him. : hyrinend 
4+ I had then only a simple pocket compass to make use of in going successively 
from one mountain to another. ; “, art 

+ Iam of opinion that in Geognosy the term Formation ‘may ‘be defined to'be ‘an 
assemblage of certain rocks or mineral matters, which appear, according to their 
geognostic relations of position, to be contemporaneous or nearly so. I am at present 
acquainted only with the following : ee thnte 


tant : 
; 3 


1. Formation of Primitive Rocks. - 

2 —- Transition Rocks. 

a +—v- Secondary Rocks (Floetz): ie 
wide -— Alluvial; Rocks, \or matter.) ))).90@ og. 

5. -—— Volcanos. 


' LT leave it to those who are more capable than I am, to determine whether what is 
‘called the fresh-water limestone should be added to the'niost recent members of 'the 
third formation, or whether it is actually a distinct formation between the third ‘and 
fourth. 

§ Professor Jameson, by translating the first part of the German name ‘into Eng- 
lish, has rendered the pronunciation less harsh, - ©. ig A 4 


1824.] Dr. Berger’s Reply to Mr. Henslow. 369. 


mical action. Although it is not always easy to distinguish the 
schistose variety of this rock from argillaceous schistus, it may, 
however, be effected either by a glass which magnifies consider- 
ably, or by the blowpipe, which converts the greywacke into 
a frit only, while the argillaceous schistus. fuses; this is 
undoubtedly the effect of the fluxes naturally mixed with it. I 
believe also that the mean specific gravity of this rock is rather 
greater than that of schistose greywacke. The natural decompo- 
sition of the latter produces a sterile sandy soil, but little suited to 
vegetation, on account of the readiness with which water passes 
through it ; while, on the contrary, it is retained by the plastic 
property of the decomposed argillaceous schistus. Lastly, the 
relative positions materially assist the travelling geologist. I 
had carefully weighed all these distinctive characters at the time 
of arranging my memoir on the Isle of Man. I have allotted a 
considerable space to this transition rock, and I find no reason 
inthe supplementary observations of Mr. Henslow, which induces 
me to alter my opinion in this respect. 

Mr, H. gives so indistinct an idea of the rock which charac- 
terises what he terms the “ quartzose district,” that I shall take 
no further notice of it. 

I am pleased to believe that the circumscription of the lime- 
stone country is more correctly traced iu Mr. Henslow’s map 
than in mine ; but the difference is not assuredly very striking. 
Without attaching too much value to a conjecture, | may inquire 
of Mr. H. how he supposes the heterogeneous substances 
which are found in amygdaloids have been formed there.* 

I now arrive at my “ great mistake” (p. 494), that of having 
supposed that the whole extent of the isthmus of Languess was 
composed of a conglomerate of quartz pebbles loosely attached 
together. This error on my part may, perhaps, exist, and I 
thank Mr. H. for having animadverted upon it; + but lam much 
disposed to believe, that the rock which, according to Mr. H. 
forms the greater part of it, ought to be called schistose grey- 
wacke, rather than argillaceous schistus. 

Mr. Henslow mistakes when he makes me say (p. 495), that 
all the interval between Scarlet and Poolvash is occupied by a 
bed of amyegdaloidal trap. I mention, on the contrary, the two 
places in which I had observed this rock. 

* It is well known that some of these substances, which are of a friable and delicate 
nature, often disappear from the paste in which they were inclosed, by the action of 
atmospheric agents. 

+ I owe it to truth to state, that not haying completed the circuit of this isthmus, as 
my companions may yet remember, I had some doubts, which were removed by Mr. 
Webster, as to colouring my map uniformly, as has actually been done. But I ought 
at the same time to remark, that I do not say in the text of my memoir, that the isth- 
mus of Langness is entirely composed of this conglomerate. I confined myself to gene- 
ral statements, which are not incorrect. ‘The small extent of the isthmus of Langness, 
compared to that of the whole isle, ought, perhaps, to disarm the extreme severity of 
my critic. 

t “ Kaal-Farane and Cromwell’s Walk, two places that separate Scarlet Point 


from the entrance of Poolvash Bay, present an unstratified bed of amygdaloid, that over- 
lies the limestone itself.” 


New Series, vow, vil. 28 


370 Dr. Berger's Reply to Mr. Henslow. [May, 


Conformably to the general opinion, I have in my memoir 
given the name of Curragh to the flat country only, situate to 
the north of the group of mountains in the Isle, for [ had never 
heard that this name was applied to the tourbiéses of the moun- 
tainous country ; the flat country which I speak of having been 
long used in agriculture, [ thought it sufficient to state the 
opinion of a respectable man (Bishop Wilson), relating to the 
trees which they procured from it especially more than 20 
years since. I have preferred to make known, by characters 
which are, I think, unequivocal, the use and profit that the agri- 
culturist now derives from the marl which is also met with in 
this district below the sandy soil, to the subject, into the details 
of which Mr. H. has entered with sufficient minuteness. The 
discovery of elk bones and of earthy phosphate of iron in this soil 
is unquestionably interesting, although it does not possess any 
thing which is very extraordinary. 

With respect to the shingly beach situate a little to the north of 
the sandy hills which I have marked in my map by the name of 
Balla-Chirrym Hills, Mr. Henslow exclaims against the annual 
increase which I assign to it, from the assertion of several inha- 
bitants of the Isle. But has he not frequently had occasion to re- 
mark, how little the accuracy of expressions used in conversation 
is observed; and was not the manner of stating this assertion, 
which I evidenly considered as an exaggeration, sufficient to 
undeceive any clear-sighted person ?* 

I have now finished a hasty examination of a criticism, which 
is undoubtedly rather prolix and inflated. I should have silently 
profited by the truth which it may contain, if it had not been of 
an injurious nature with respect to me, for it tends to induce the 
belief that I have little respect for-truth ; besides which, Mr. 
Henslow’s supplementary observations to my memoir have been 
published in the Transactions of a Society of which I am myself 
amember. Cuzque Suum. ' 


* “ Some go so far as to say that the increase is no less than two yards in a year.” 
I will add that I wrote my memoir upon the Isle of Man in a foreign language, and 
without the assistance of any person, 


1824.] Analyses of Books. ! 371 


ARTICLE XII. 


ANALYSES oF Books. 


A Selection of the Geological Memoirs contained in the Annales 
des Mines, together with a Synoptical Table of Equivalent 
Formations, and M. Brongniart’s Table of the Classification. of 
Mixed Rocks. Translated, with Notes, by H.T. de la Beche, 
Esq. FRS. FLS. MGS. &c. London, 1824. 8vo. pp. 335, 
and 11 Plates, 


WHEN we compare the small space of time during which 
geology has been pursued as a science of induction, with the 

uantity of information that we now possess of the structure of 
the globe, or at least of that portion of it which is open to the 
cognizance of man, we caunot fail to perceive, that the progress 
of geology in the mighty march of knowledge witnessed by the 
present century and the latter part of the preceding one, has 
been fully commensurate with that of the kindred sciences of 
Mineralogy and Chemistry. The principles of geological 
science have been, to a great extent, Stir established, and 
are now applying to the examination of the physical structure of 
almost every part of the earth. The geological features of south- 
ern Europe, and of the British Isles, have been most diligently 
investigated,—though with respect to these alone much yet 
remains to be accomplished—and the knowledge thus gained 
has been employed with the greatest advantage, in the compa- 
rison of them with those of other countries. The results have 
been given to the world in a numerous series of memoirs, in 
almost every language of Europe, but principally in French and 
in German. From those in the former language, published in 
the Annales des Mines, a work conducted by the General 
Council of Mines at Paris, Mr. de la Beche has in this volume 

erformed an acceptable service to British geologists, by select- 
ing, with some abbreviation, a series of the more important 
papers. His own eminence as a geologist is a sufficient gua- 
rantee for the quality of the work: and we shall therefore confine 
ourselves to a brief analysis of its contents ; appending to this, 
however, his translation of M. Brongniart’s “‘ Notice on the 
Magnesite of the Paris Basin,” of which we purposed to have 
given an abstract in the Avna/s, some time since.* The work 
commences with Mr. de la Beche’s very useful “ Synoptical 
Table of Equivalent Formations,” giving the names of the 
various rocks in English, French, and German, and to which 
are subjoined the synonymes of certain individual geologists 


* See Annals, N. ny iy, p. 389, 
2B 


O72 Analyses of Books. (May, 


where these differ from the terms in general acceptation. Mr. 
de la Beche, we observe, gives the “ new red conglomerate,” 
as the equivalent formation ‘to the “ rothe-todte-liegende,” 
placing the latter between the alpenkalkstein (magnesian lime- 
stone) and the porphyr gebirge of Keferstein (new red porphyry, 
porphyre du gres rouge), which is succeeded.by the coal mea- 
sures : and in the preface we find the following observation on 
this subject :—‘ With respect to the identity of the new red 
conglomerate with the rothe todte liegende of Germany, it may 
perhaps be right to mention, as discussions have lately taken 

lace on this subject between the Rev. W.-D. Conybeare and 

r. Weaver, that the conglomerate usually termed new red con- 
glomerate, in the neighbourhood of Exeter and Teignmouth, 
seems closely to resemble the rothe todte liegende, as has been 
already stated by Prof. Buckland ; the magnesian limestone is 
unfortunately wanting in that country, or at least has not been 
described, though traces of it are mentioned by Mr. Conybeare 
(Outlines of the Geology of England and Wales, p. 308) at Samp- 
ford Peverell, in Devonshire, for beneath that rock the German ° 
rothe todte liegende is always described as occurring.” 

The next article is M. Brongniart’s Table of the Classification 
of the Mixed Rocks, from the Sours des Mines, which we are 
glad to see in an English dress ; for, with the exception of Dr. 
Macculloch’s, we think it the only useful arrangement of those 
important substances that has yet been devised: though we are 
also of opinion that a combination of the two might be effected, 
with some additions, perhaps, from M. de Leonhard’s new 
“ Charackteristik der Felsarten,” which would be preferable to 
either. We would likewise suggest to some mineralogical geo- 
logist the propriety of determining a series of the British rocks 
according to the classification of M. Brongniart, and of publish- 
ing a table of their localities. 

The memoirs from the Annales des Mines then succeed, and 
are as follows :—Geological Sketch of the Coal District of 
Saint-Etienne ; by M. Beauier (with a geological map). 
Memoir on the Geographical Extent of the Formation of the 
Environs of Paris; by M.d’Omalius d’Halloy (with a geological 
map). Extract of a Memoir on the Possibility of causing Fresh- 
Water Mollusce to live in Salt-Water, and Marine Mollusce in 
Fresh-Water, with geological Applications; by M. Beudant. 
On Gabbro; by M. Von Buch. Memoir on the Mountain of 
Rock Salt at Cardona, in Spain; by M. P. Louis Cordier. 
Observations on the Formations of Ancient Gypsum occurring 
in the Alps, particularly on those considered as primitive ; pre- 
ceded by new Facts relative to the Transition Rocks of that 
Chain ; by M. Brochant de Villiers (with a lithographic map, 
sections, &c.) Geological Sketch of the Thuringerwald ; and 
on some Basaltic Mountains of Hesse and Thuringia ; by M.de 
Hoff. Report on the Tin of Periac (dep. of the Loire Infére.) ; by 


.1824.] De lu Beche’s. Selection of Geological Memoirs. 373 


Messrs. Junker and Dufrenoy. Considerations on the Place 
that the Granite Rocks of Mont Blanc and other central Sum- 
mits of the Alps ought to occupy in the Order of Anteriority of 
the primitive Series; by M. B. de Villiers. Memoir on the 
Geology of the Environs of Lons-le-Saunier ; by M. Charbaurt. 
On the relative Positions of the Serpentines (Ophiolites) Dial- 
lage Rocks (Euphotides), Jasper, &c. in some parts of the 
Apennines ; by Alex. Brongniart (with lithographic sections, 
&ce.). On Fossil Vegetables traversing the Beds of the Coal 
Measures; by the Same (with a lithographic print of the Coal 
Mine of Treuil, near St. Etienne, showing the Stems of large 
Vegetables). Notice on the Coal Mines of the Basin of the 
Aveyron; by M. du Bosc. Notice on the Geology of the 
Western Part of the Palatinate ; by M. de Bonnard. On the 
Zoological Characters of Formations, with the Applications of 
these Characters to the Determination of some Rocks of the 
Chalk Formation; by A. Brongniart (with a lithographic print 
of organic remains, and another of the Montagne des Fis) 
Notice on the Hartz; by M. de Bonnard. On the Calcareo- 
trappean Formations of the southern Foot of the Lombard Alps; 
by A. Brongniart. Notice on the Magnesite of the Paris Basin, 
and of the Position of this Rock in other Places ; by the Same 
(with a plate of sections). Observations on a Sketch of a 
Geological Map of France, the Pays-Bas, and neighbouring 
Countries ; by M. d’Omalius d’Halloy (with the map). On the 
Geology of the Environs of St. Leger sur Dheune (dep. of the 
Saone and Loire); by M. Levallois. 

In his table of Equivalent Formations, Mr. de la Beche has 
inserted the muschelkalk and quadersandstein of Germany as 
separate formations, in order to show the opinions at present 
entertained on the subject by some continental geologists, who 
consider the muschelkalk as distinct from our lias ; and conceiv- 
ing it to be of some importance to determine if we are or are not 
to add two new formations to our secondary rocks, he has, in an 
Appendix, subjoined to the above memoirs, the description of 
the muschelkalk and quadersandstein given by M. Humboldt in 
his “ Essai sur les Gisement des Roches,” and that inserted by 
Dr. Boué in his Memoir on Germany published in the Journal de 
Physique. 

e proceed to extract M. Brongniart’s notice on Magnesite: 

“ The distribution of the rocks and minerals entering into the 
composition of the crust of the globe, may be regarded in differ- 
ent points of view, and the different kinds of relations subsisting 
between these bodies successively examined. 

« Sometimes we take a formation composed of different kinds 
‘of rocks, whose epoch of formation is well determined in one 
place, and we follow it in other parts of the elobe, to see if it 
preserves the same position, and to study the mineralogical mo- 
‘difications it experiences : this point of view is principally geo- 


logical and secondarily mineralogical, Sometimes we study a 


374 Analyses of Books. [May, 


simple or mixed rock, of a certain nature, and following it in 
different places or in the different formations in which it occurs, 
we examine at what epochs it has been deposited on the surface 
of the globe, what are the minerals and rocks with which it is 
associated, and what peculiarities it presents in each of these 
epochs. This point of view is principally mineralogical, and 
secondarily geological : it is as productive as the first in general 
results, and consequently as proper as it to discover the laws 
which have presided at the structure of the earth, and at the 
formation ofthe minerals that enter into its composition. 

“Tt is under this last point of view that I shall consider the 
mineral which I have mentioned by the name Magnesite. 

“ The following are the minerals to which I give this name, 
I distinguish them in two principal series, which may one day 
be separated into two species when we shall have observed 
sufficiently essential characters to establish this distinetion, 

“]. Plastic magnesite (magnesite plastique), composed of 
magnesia, silex, and water, without carbonic acid. 

“ I here comprise the magnesite, so improperly named écume 
de Mer, that of the environs of Madrid, that of the environs of 
Paris, that of Salinelle, department of the Gard, &c. 

‘‘ Serpentine might, from its composition, almost be referred 
to this species ; but it is distinguished from it by its mineralogi- 
cal characters. 

“2. Effervescent magnesite (magnésite effervescente), essen- 
tially composed of magnesia and carbonic acid, sometimes asso- 
ciated with very variable proportions of silex and water. 

‘““ We may refer to this division the magnesite of Hroubschitz, 
in Moravia; those of Piedmont, of the Isle of Elba, of Baumgar- 
ten in Silesia, of Styria, &c. 

“ Having made known, as far as it appears necessary, the 
minerals 1 include under this name, I shall now describe the 
position of the magnesite of the Paris basin, and present the 
union of a few facts and observations in order to complete the 
geognostic history of these minerals, the principal object of this 
notice. 

Parisian Magnesiie. 

“T first observed the presence of magnesite in rather exten- 
sive beds at Coulommiers, 12 leagues to the E. of Paris, and 
afterwards quite close to the latter town: I shall describe this 
variety and the circumstances of its position with some detail, 
as I shall afterwards employ it as a type of comparison with the 
same mineral, found in other positions and in other places.* _ 

“ The magnesite of Coulommiers, in the purest specimens, for 
it is often mixed with other things, possess the following cha- 
racters :— ! 

* I am indebted to M. Merimée for the knowledge of this magnesite. He was 
struck with the soapy unctuosity of a stone which he found at Coulommiers, and hay- 


ing brought it to me, he put me im the way of discovering this mineral in the Paris 
basin. ; 


1824.] De la Beche’s Selection of Geological Memoirs. 375 


Its masses are soft, smooth to the touch without being 
unctuous ; its powder is rather hard, 

*« It easily absorbs water and swells out considerably, becomes 
slightly translucent, and forms a short soft paste, resembling 
jell 
we It does not effervesce with acids. , 

‘«« Exposed to the action of a porcelain furnace (at 140° of 
Wedgewood), it hardens, exfoliates a little, but does not suffer 
any other alteration; it does not show the slightest trace of 
fusion, either in its thin pieces or on the surface ; it however 
becomes rough to the touch, and hard enough to scratch steel. 

“ M, Berthier has analyzed this magnesite, chosen from the 
purest masses, and has found the following ingredients :— 


Magnesia. ..cceseccscceccesepeseee 240 
BML Hala chats slo tid m Giue otare svpioae 6 8 aet'e tote Tae 
PO SED gis ai dn wie ohats. 20 alebo.nde'e serene) gy ian) Coed 
PAINT ach hohe era wiowelin wets slarptone ie) ore OUT 


oo 


« 99°4 


“ The magnesite of Coulommiers occurs in masses, which, 
by their schistose structure and thinness, show they belong 
to thin beds. 

“ Its colour is whitish, most commonly pale grey ; it has often 
a roseate tint, but it loses that and its grey colour in the fire. 
It is associated with brownish and reddish chert (silex corné) of 
a very scaly fracture ; it 1s intimately united with it, and pene- 
trates into all its cavities, and even into its mass; it is also very 
frequently associated with marly limestone, and then effervesces 
and becomes partly fusible. 

“This magnesite occurs in thin beds, interposed between beds 
of marly limestone and calcareous marl, near Coulommiers, on 
the right of the road, entering the town on the Paris side, in a 
small hill having a north and south direction, and which having 
been cut to form a canal, exposes its interior structure and the 
following series of rocks, beginning with the uppermost. 

“1. A bed, composed of siliceous limestone, the middle of 
which is of white and cellular chert (silex corné), and the com- 
pact limestone mass filled by small shells scarcely determinable, 
and by larger shells, such as Limneus longiscatus, cyclostoma 
mumia, &c. 

“ 2. This bed rests on a bed of very irregular thickness, of a 
greyish fissile earth, resembling clayey marl, and which has been 
recognised to be an impure magnesite, i, e. mixed with calcare- 
ous marl, 

“ 3. Then follows a bed of soft and friable calcareous marl, 
containing another small bed of magnesite. 

“4, A bed of calcareous marl without silex, beneath which is 
another small bed of brown impure magnesite. 


376 Analyses of Books. [May, 


“5. A thick bed of white calcareous marl subdivided into 
many strata by marl beds, and by a bed of zoned chert (silex 
corné zonaire), almost jaspic, without either shells or magnesite. 

“6. A bed about two decimetres thick, composed of brown 
chert (silex corné) in irregular nodules, but principally flattened. 
These are the nodules that are enveloped and even penetrated 
by the Parisian magnesite of an isabella roseate grey colour. 
It is sometimes very pure, does not effervesce with acids, and is 
absolutely infusible in the heat of a porcelain furnace. . It is 
sometimes slightly translucent. 

“7, These cherts (silex) are placed on a bed of hard calcare- 
ous marl in nearly round nodules, and containing cyclostoma 
mumia. 

‘©8, Beneath is a thick bed of white calcareous marl, friable 
or only splintery, and containing neither chert (silex) nor shells. 

“The total thickness of the beds composing this hill is nine 
metres (about 29 feet). 

«As this succession of beds and rocks is isolated, as no 
other formation is seen above it, and as we do not know that on 
which it rests, we can at most suspect its position by a compa- 
ison of these rocks with those that resemble them in the Paris 
-basin ; but this is a presumption difficult to prove without the 
presence of the organic remains found in it ; now this character, 
‘which is so useful in establishing analogies between formations 
far distant from each other, possesses all its value when it is 
required to determine the position of one formation with respect 
to the others in the same basin ; it may then be here employed 
“with perfect safety, and geologists who admit these rules of 
determination, and who have seen the cyclostoma mumia and 
Limneus longiscatus cited, have immediately 1ecognized the 
‘position of the formation containing the magnesite of Coulom- 
miers. These shells are not marine, one of them is evidently a 
‘fresh water shell, consequently the magnesite belongs to a fresh 
water formation, and the two species of shells 1 have just men- 
tioned, having as yet been only found in the middle fresh water 
formation, in that situated between the two marine formations of 
the Paris basin, we should refer the magnesite of Coulommiers 
‘to that fresh water formation ; it forms part, as we have else- 
-where * shown, of that which we have named siliceous lime- 
‘stone. The hard calcareous marls, and the silex that accompa-~ 
nies the magnesite, remind us of the siliceous and calcareous 
‘characters of this deposit, and complete all the analogies. 

“ The magnesite having shown itselfin a very distinct manner, 
‘both as to its purity and quantity in the siliceous limestone of 
Coulommiers, the rules of geology teach us that we should find 
it elsewhere, by searching for it in this formation; this has in 
fact happened. Proceeding towards Paris, and at about two 


* Description Geologique des Enyirons de Paris, 1822, p. 38, and 203. 


1824.] De la Beche’s Selection of Geological Memoirs. — 377 


leagues from Coulommiers, we observe near Crecy the same 
rock with the same mineralogical circumstances ; 1. e. the lime- 
stone so compact that it resembles the fine compact limestone 
of the Jura, the chert (silex), the clayey marls, the magnesite, 
but less pure, and the same fresh water shells. 

“The short distance of these two places rendered these 
resemblances very presumable ; but transporting ourselves to 
St. Ouen, close to Paris, on the bank of the Seine and at the 
foot of Montmartre, we find the magnesite in a formation alto- 
gether similar to that of Coulommiers ; the same limestone, the 
‘same chert (silex), the same shells occur there ; the position of 
the rock beneath the gypsum is there well determined. The 
magnesite is however less pure here and less apparent; 
traces of it only occur; these traces had long since been 
‘observed. M. Armet had remarked the presence of magnesite 
in the marls of Montmartre; M. Bayen had observed, more 
than thirty years since, and had shown me that the menilite con- 
tained it. Now this belongs to the fresh water formation 
beneath the gypsum; it is probable that we should find this 
mineral either in minute quantities, or in small masses, in all the 
‘siliceous limestone rocks of this same formation, such as those 
of Champigny, Orleans, Septeuil, Nc. [ have recognised it in 
‘a greyish clayey marl which accompanies a silex resinite of the 
environs of Mans, consequently at more than 40 leagues to the 
west of Paris, and 50 leagues from the first place in which I have 
mentioned it. 


“< Geological Circumstances of the Magnesite of different Places, 
compared with those of the Parisian Magnesite. 

“We shall find this rock still further distant, in a basin se- 
ae from ours not only by a distance of more than 120 
eagues, but by chains of mountains whose structure and nature 
are altogether foreign to those which surround our basin; now, 
it is remarkable, that we find the magnesite with all the circum- 
stances which accompany it in that part of the Paris basin 
where it is most pure. 

“ Magnesite has long since been observed at Salinelle, near 
‘Sommieres, in the department of the Gard, between Alais and 
Montpellier ; but its position has only been determined a few 
td since, by the description M. Marcel de Serre has published 
‘of it. 

“ It is therefore solely to the remarkable analogy of this posi- 
tion with that of Coulommiers that I wish to call the attention 
of naturalists. The magnesite of Salinelle is schistose like that 
of Coulommiers ; it possesses the same colour, approaching grey 
with a roseate tint, with the same tenacity ; it absorbs water in 
‘the same manner ; it is composed of the same ingredients, i. e. 
20 parts of magnesia instead of 24, 51 of silex instead of 54, 
and 22 of water instead of 20. It will be acknowledged that it 


378 Analyses of Books. [May, 


is difficult to meet with more resemblance between uncrystallized 
minerals, which occur at more than 100 leagues from each other, 
and if the mineralogical species cannot be here determined by 
the form, it is sufficiently so by the composition ; the analogies 
drawn from its associated minerals, and its position, are the 
same; it is mixed with nodules of chertz (silex corné) which 
resemble our menilite ; it is accompanied and covered by marly 
limestone containing fresh water shells, consequently it belongs, 
with that of the Paris basin, to a calcareo-siliceous fresh water 
formation. 

“ But magnesite, i. e. this stone essentially composed of mag- 
nesia, silex, and water, occurs in many other places dispersed 
over the surface of Europe, and consequently placed at great 
distances from each other. Sometimes we are acquainted with 
its mode of occurrence, and then we know that it is very differ- 
ent from that I have above described; sometimes we are igno- 
rant of it, or at least we do but presume it; but in all these 
places and in all these positions we shall see the magnesite to 
occur accompanied by the same mineralogical characters and 
the same geological circumstances (circonstances geologiques) ;* 
a consideration that must not be confounded with the geologi- 
cal position (gisement). 

“The magnesite of Vallecas near Madrid is already known; 
for in 1807 I described, in my Traité de Mineralogie (t, il. p. 
492), its nafilre and properties, from the information obtained by 
the specimens received from Messrs. Sureda, Dumeril, and 
Mieg, and of its position from the same specimens, and the 
information of M. Link, who took it for a kind of clay ;\ a very 
excusable error at that time. M.de Rivero has however studied 
the same places, and has sent me an ideal section of this rock, 
with a detailed description which [I shall transcribe almost 
literally. 

«he village of Vallecus is two leagues to the south of 
Madrid ; it is situated lower than the latter town; an isolated 
hill, named the hill of Vallecas, occurs near the village : before 
we reach the top of this hill, we meet with small hillocks and 
excavations which arise from the workings of the magnesite ; 
the tour of this hill may be madein 20 minutes, From obsery= 
ing the locality, an idea is conceived of a gypsum basin on 
which the magnesian rock rests. 

“<< Tf we observe the structure of the hill, we observe, com- 
mencing at the lowest part, gypsum with clay, which belongs to 
the saliferous formations} of Villarubia: this gypsum extends 
from the walls of Madrid to the junction of the river Javama 


* ‘JT haye literally translated M. Brongniart’s expxession, though I should not have 
used it myself in the same¢ sense; M. Brongniart seems only to imply that it is con- 
stantly associated with certain minerals, without any reference whatever to its geological 
or relative position. —(Trans.)” 

+ “* New red or saliferous sandstone.—(Trans.)’’ 


1824.) De la Beche’s Selection of Geological Memoirs. 379 


with the Manzanares; it is very distinctly seen near the hermi- 
tage of Notre Dame de la Torre, 150 metres (492 feet) to the 
west of the hill of Vallecas, and near the canal of Madrid ; there 
then follows a bed of reddish clay with nodules of flint (silex 
pyromaque). Though the magnesite has not been observed 
mmediately on the clay, yet M. de Rivero conceives that it 
rests upon it, because ascending towards the hill, the magnesite 
is found to follow ; and the flint nodules are the same as those 
of the magnesite. ‘The magnesite occurs in very thick beds, 
coating flints which are disseminated through the beds: these 
beds are cleft, and in the clefts we find asbestus (asbeste papy- 
riforme), on which crystals of carbonate of lime are observed; 
they are also seen on the magnesite. This same deposit reap- 
pears close to Madrid, it may be observed as we leave the bar- 
riére by the Portello; the flint is there disseminated in the same 
manner. M. de Rivero has also met with it on the banks of the 
river Manzanares, opposite the king’s villa; it has also been 
found at Cabanas, nine leagues to the north of Madrid: the 
author, not having visited this last place, is unable to describe 
its situation. A thin bed of greenish clay containing very little 
magnesite is observed above the magnesite at Vallecas; then 
follows a reddish common opal (silex resinite) in beds of variable 
thickness, very fragile, presenting a crust of manganese on some 
parts of its surface; this opal is worked for gun flints. A very 
soft and nearly earthy magnesite is found above this fragile 
opal. 

Pee The different beds above noticed by M. de Rivero occur in 
the hill of Vallecas. The top of this hill constitutes a platform, 
on which are found many flints, and pieces of opal, with crystals 
of carbonate of iron ; crystals of pseudo-morphous quartz have 
moreover been observed, and have been taken for opal crystals. 

“ «Shells have never been met with in this formation. The 
three upper beds appear on the banks on the Manzanares, as 
we quit the gate leading to the Escurial.’” 

“ The author has above stated that magnesite is met with on 
the banks of the river, and if we ascend towards the town, we 
find beds of greenish and reddjsh clays of which bricks are made, 
and above these clays an alluvial formation, composed of fine- 
grained sand, and lastly vegetable earth on the surface. 

“ Thus the magnesite of Vallecas and Cabanas, near Madrid, 
possesses the same tenacity, thesame hardness, the same light- 
ness, the same superficial roseate tint, as those of Coulommiers 
and Salinelle. It is equally composed of 23 parts of magnesia, 
53 of silex, and 20 of water; it is accompanied, like ours, by 
chert (flint ?), which also passes into its mass, by common opal 
(silex resinite), by chalcedony, by crystallized quartz, and calca- 
reous spar altogether resembling those of our siliceous limestone. 
It affords, certainly, no organic remains; but we know that these 


380 f _ Analyses of Books. 1. (Max 


remains are rare in the siliceous limestone-of the Paris basin, of 
which our magnesite forms a part; lastly, if it appears to differ 
by its position on a saliferous gypsum, much more ancient than 
our gypsum, and calcaire grossier, it is not covered by any rock 
which appears more ancient than the latter, and it.is like them 
in horizontal beds. 

“Tf from Spain we transport ourselves to Italy, to the foot of 
the Piedmontese Alps, we shall find, at a short distance from 
Turin, the serpentine hills of Castellamonte and Baldissero, tra- 
versed in every direction by veins of magnesite which 1s tenacious 
yet plastic, light, and with that roseate superficial tint which we 
have noticed in the preceding magnesites. Its principal or fun- 
damental and characteristic composition appears to be still the 
same, i. e. of magnesia, silex, and water. Here however we have 
carbonic acid, which seems to indicate a different chemical spe- 
cies ; but its geological circumstances are still the same. I have 
already noticed them in my memoir on the geological position 
of the serpentines. 

‘«« The mineral no longer occurs in horizontal beds, or nodules 
interposed in the beds, but in numerous veins, uniting in every 
direction in the midst of the serpentine ; chert, common opal, 
and jasper, presenting many varieties of texture and colours, are 
constantly and intimately united with it, as at Coulommiers and 
Salinelle. They have been formed even in the midst of the mag- 
nesite. This circumstance of geological association is then 
remarkably constant, even when the geological position has no 
longer the same character, and it is here very ditterent. It 
appears to me well established, that this magnesite belongs to 
‘the serpentine formation of the Apennines, consequently to 
ancient rocks, nearly of the transition epoch. 

_ “There are other examples of magnesites, but the circum- 
stances of their geological position are less well known; yet 
both what is known, and their composition, still very well agree 
with what we have stated of the preceding. 

“Thus the plastic magnesite of Asia Minor, known by the 
name of Ecume de Mer, has all the exterior characters of that of 
Piedmont, and even that of Coulommiers, with a composition 
that very slightly differs ; it has, like it, the roseate superficial 
tint which also occurs in the magnesite of Houbricht in Moravia. 
‘But in this, the carbonic acid, which is in some quantity, seems 
_to establish a mineralogical difference, the importance of which 
is not yet well appreciated ; the presence of silex nodules which 
pass into the mass, reminds us of an analogy in the geological 
circumstances, which is rather remarkable.” 


Conclusions. 


“ We shall confine ourselves to these. examples: they are 
sufficient to prove the relations of formation which we wish to 


1824.] De la Beche’s Selection of Geological Memoirs. 381 


establish between the magnesite of the Paris basin and those we 
have just mentioned. The magnesite in all, whether it be or be 
not combined with carbonic acid, contains water and silex; this 
last substance does not occur only in chemical combination with 
the magnesia, it also forms isolated masses, and whatever the 
mineralogical differences may be that these varieties of quartz 
pay not only is its difference all that is necessary to esta- 

lish the geological resemblances which we desire should be 
remarked ; but it may be said that these varieties follow without 
interruption from the oldest to the newest magnesites, as the 
following table will show :— 


Crystallized quartz 
Parisian magnesite.... 4 Chert 
Several varieties of opal (silex resinite) 
Magnesite of Salinelle. . Chert 
Crystallized quartz 
\ Chertz (silex corné) 
) Chalcedony 
Several varieties of opal (silex resinite) 
Chalcedony 
White and green opal (silex resinite) 
Chert 
Chalcedony 
Varieties of opal (silex resinite) 


Jasper 


Magnesite of Madrid.. 
Magnesite of Moravia.. 
Magnesite of Piedmont 


“ Before geology had acquired in principles and facts the 
precision to which it has now arrived, the presence of magne- 
site in the Paris basin had no other result than that of adding a 
mineral species to the list of those contained in our country ; but 
this fact now possesses another interest: it has seryed to unite 
observations which were, it may be said, isolated. It informs 
us that the magnesite beds were deposited on the surface of the 
globe at very different epochs, for some (those of Piedmont) 
belong to the most ancient sediment rocks, and others (those of 
Salinelle and Coulommiers) to the newest sediment (tertiary) 
rocks ; and yet we see these deposits accompanied by nearly the 
same geo/ogical circumstances. Such a remarkable constancy in 
the association of silex and magnesia, two bodies between which 
there is no chemical analogy, will fix the attention of geologists, 
and may perhaps contribute to show us the origin of these de- 
posits, as the thermal springs of Italy deposing travertine have 
pointed out that of the freshwater limestone. [tis still Site 
from the bosom of the earth that the liquid arose which depo- 
sited these rocks ; for we find in certain thermal waters traces of 
all the ingredients of their composition: the mass of water is at 


382 - Analyses of Books. | [May, 


present immense in comparison with the matters held in solu- 
tion; but these matters exist in it: they are deposited, as M. 
Berthier has observed, at the waters of Vichy, St. Nectaire, &c.* 
not only separately, but nearly in the same order, as the calca- 
reous and magnesian formations. The first deposits, those 
which are nearest the spring, this able chemist tells us, are also 
those most charged with peroxide of iron and silex; the lime- 
stone, still ferruginous, then follows, and is the more pure and 
more separated from these two substances, the more distant it 
is from the point where the spring rises from earth; the carbon- 
ate of magnesia is the last deposited. 

“‘ Without wishing to establish any real resemblance between 
this succession and that of our rocks ; without wishing to repre- 
sent that these rocks, certain beds of which show too clearly 
the characters of mechanical aggregation for them to have been 
formed by solution, have been deposited by the mineral waters 
of the ancient world, we cannot avoid remarking that commenc- 
ing with the chalk, we find a series of rocks, the nature and 
succession of which are nearly the same as those which M. 
Berthier has observed in the deposits from mineral waters. 
Thus, first, a new formation, i. e. a new emission of dissolved 
matter would appear to commence above the chalk, at first de- 
positing silex and iron, represented, one by the beds of sand 
and sandstone, and the other by the iron ore found so abund- 
antly in the deposits of lignites and plastic clays which cover the 
chalk ; secondly, the more or less compact limestone, accompa- 
nied by iron and silex in the lower beds, and by silex in the 
upper ‘beds; the magnesite also accompanied by silex, which 
still occurs in the lower gypsum beds; this silex is partly 
soluble in alkaline liquids, like that of the calcareous deposits 
of certain mineral waters; fourthly, the gypsum, the most 
soluble substance of all those we have named, and which should 
be the last deposited. 

““We do not pretend to draw any other conclusion from 
these different resemblances; but it appeared to us right to 
hazard them, if it were only to engage the attention of chemists 
and geologists.” 

From this extract the reader will be able to judge of the man- 
ner in which Mr. de la Beche has executed his task: and we 
will conclude by recommending this work to all students of 
eeology ; to whom it will be highly useful, by enabling them to 
compare our own rocks with the similar formations on the conti- 
nent which are described in it. 


* Annales de Chim, et de Physique, t, xix. p. 134. 


SME TF Be 


1824.] Proceedings of Philosophical Societies, 383 


ArticLe XIII. 


Proceedings of Philosophical Societies. 


ROYAL SOCIETY. 


March 4 (continued).—“ Some further particulars of a case of 
Pneumato-thorax ; by J. Davy, MD. FRS.” 

Dr. Davy’s hopes of the favourable termination of the case of 
Pneumato-thorax, in which tapping was resorted to, as described 
in the Appendix to his paper in the Philosophical Transactions 
for 1823,* had proved fallacious ;—the patient had died ; and the 
object of the present paper was briefly to detail the progress of 
his disorder, and to give the examination of the air found in the 
chest. 

About a month after the date at which the history of 
the case in the Philosophical Transactions terminates, hydro- 
thorax supervened, and it was likewise found that air was 
collected in the left cavity of the chest. A consultation being 
held upon the case, a second operation was determined on, Dr. 
Davy having experienced inconvenience in penetrating the in- 
tercostal space, adopted the method of perforating amb, men- 
tioned by Hippocrates. Part of the fifth rib was accordingly 
laid bare by the scalpel, then bored through by a carpenter’s 
auger, and the pleura penetrated by a trocar: about fourteen 
ounces of clear fiuid were obtained, containing albumen, and 
a little sub-carbonate of soda, but no free carbonic acid; the 
succeeding portions, however, were more and more purulent, 
and contained gas. The total quantity of fluid thus obtained 
in the course of six weeks amounted to twenty pints. By means 
of a trocar and bladder air was obtained from the aperture at 
three several times; and being examined by lime water and 
phosphorus was found to consist of from 88 to 90 per cent. of 
azote, 2 to 4 carbonic acid, and 3 to 5 oxygen. The patient 
was at first much relieved by the operation, and seemed to be 
recovering: but he eventually became worse, and died; evi- 
dently from the mere effects of the disorder. 

On the examination of the body after death six ounces of 
pus were found in the right pleura; the right lung at first ap- 
peared healthy, but upon minute examination a number of gra- 
nular transparent tubercles were found disseminated through it. 
The left lung was much condensed, so that it could not be 
inflated by blowing with a pair of double bellows attached to 
the trachea; it communicated with the pleura by two small 
openings. The heart was displaced, having been thrown to 
the right side, obliquely on the spine. The body having been 
opened in a bath, 170 cubic inches of gas were collected from 
it, containing 16 per cent. of carbonic acid, and a little oxygen ; 


_® See our last number, p, 302, 


384 Proceedings of Philosophical Societies. [May, 


the residue being azote. This, Dr. Davy presumed, was atmo- 
spheric air, deteriorated by respiration, and altered by the 
absorption it had undergone while in the body. He had found 
in the lungs, after death, in various cases, from 9 to 12 per cent. 
of carbonic acid. ) 

March 11.—A paper was read “ On the Parallax of « Lyre;” 
by J. Brinkley, DD. FRS., &c. In this paper Dr. Brinkley 
wholly opposes and controverts the statements of Mr. Pond re- 
specting the subject of his.paper, as given in the Phil. Trans. 
for 1823, and noticed in the Annals for September last, p. 226. 

March 18.—The Lord Bishop of Limerick was admitted a 
Fellow of the Society ; and the name of the Earl of Orford was 
ordered to be inserted in its printed lists. 

A paper was read, entitled, “ An Account of Experiments on 
the Velocity of Sound, made in Holland. By Dr. G. A. Moll, 
and Dr. A. Van Beck.” 

This paper commences with some observations on the New- 
tonian formula for the velocity of sound, as modified by La- 
place : and the authors then proceed to consider the effect of 
the wind on that velocity; which, in their own experiments, 
they contrived to annihilate. These experiments were made on 
the plains of Utrecht, at two stations 9964 feet distant from 
each other ; and the velocity ascertained by determining the in- 
terval between the flash and the report of guns by means of 
clocks with conical pendulums, dividing twenty-four hours into 
10,000,000 parts. The states of the harometer and thermo- 
meter were noticed, and the humidity of the atmosphere deter- 
mined by means of Daniell’s hygrometer. The general result 
is, that at the temperature of 32° the velocity of sound is 
1089-7 feet per second. Various detailed tables of the experi- 
ments and attendant circumstances are annexed to the paper. 

March 25.—Major-General Sir John Malcom, GCB. was 
admitted a Fellow of the Society ; and a paper was read, on the 
Geological Distribution of Fossil Shells, in continuation of that 
already published in the Phil. Trans.* by L. W. Dillwyn, Esq. 
FRS. 

A letter from Thomas Tredgold, Esq. Civil Engineer, to 
Thomas Young, MD. For. Sec. RS. was likewise read: 
it contained an account of a series of experiments on: the elas- 
ticity of steel at different degrees of temper; describing the 
apparatus with which they were made, and giving their various 
results. 

_ April 1.—The reading was commenced of “ An Inquiry re- 
specting the nature of the luminous power of some of the 
Lampynides ; L. splendidula or Glow-worm, L. Italioa, or Fire- 
fly, and L. noctiluca: by Tweedie John Todd, MD.: commu- 
nicated by Sir E. Home, VPRS.” 

April 8.—The reading of Dr. Todd’s paper was resumed and 


* See Annals for March, p. 177. 


1824.] Proceedings of Philosophical Societies. 385 


concluded. This paper commences with some general remarks 
on the various causes to which the luminosity of the lampyrides 
has been ascribed; the explanation of Macartney and Macaire, 
that the light they emit is a simple product of vitality, being 
considered as the true one. Dr. Todd then proceeds to a mi- 
nute account of the apparent source and characters of the light 
im the several animals; describing the manner in which its 
emission is affected by solar and other light, by heat, and by 
certain chemical agents respectively. In the Lampyris splendi- 
dula, the light is of a fine topaz yellow colour, with a tinge of 
green, and is extremely vivid within the compass of a few 
inches, but does not extend its brilliancy far around: within 
that space the hour may be seen on a watch’by its means. The 
light of the Fire-fly is of a pale yellowish tint, with continual 
flashes of vivid light : its variations are not connected with the 
motions of the insect’s wings, nor are they produced, as some 
have affirmed, by the frequent intervention of a membrane. 
This animal may be seen shining in full moon-light; which is 
not the case with its congeners. Irritants excite the luminous 
ower in all cases, and disorganizing substances destroy it. 
r. Todd concludes that this power is solely an effect of vita- 
lity, and that the light may be considered as animal light; 
being analogous to animal heat, which arises from a power of 
separating heat from its combinations with matter. He adopts 
the hypothesis that its principal use is that of guiding the male 
insects to the female, in the season of sexual congress: the 
males always approach any light; and sometimes even the 
shining females of other species, until they come very near 
them. The fact that the larve and even the ova possess a de- 
gree of the luminous faculty, Dr. Todd does not consider as 
militating against this explanation; for various organs are par- 
tially developed in the earlier stages of many animals, which 
are only to be used by them when arrived at their perfect state. 
A paper was also read, entitled, “‘ A Comparison of the Baro- 
metrical Measurement of Altitude with that by Trigonometry : 


“by Capt. Edward Sabine, FRS.” 


This paper contains the details of a comparative measure- 
ment of the height ofan hill at Spitzbergen in July last, by the 
geometrical and barometrical methods: the instruments em- 
ployed in both operations, and in the latter especially, had been 
prepared with more than ordinary care, and the observations 
were conducted with an attention to every circumstance which, 
it was conceived, might influence the strictness of the compa- 
rison, and sufficiently repeated to diminish at least the slight 
but unavoidable errors of observation. In the geometrical de- 
termination, the base, exceeding 2000 feet, was measured on the 
frozen surface of a bay at the foot of the hill, from whence a 
polished copper cone fixed on the summit was visible: the ho- 
rizontal and vertical angles were observed by a repeating circle ; 

New Series, vol. vil, oe 


386 Proceedings of Philosophical Societies. (May, 


the height thus found was 1643 feet. The barometers were made 
under the inspection of Mr. Daniell, with iron cisterns, as de- 
scribed by Mr.. Newman the maker, in a recent number of 
the Quarterly Journal of the Royal Institution :* the one con- 
veyed to the top of the hill was stationary there several days, and 
repeated observations were made on each ; the mean height de- 
duced from them was 1640 feet and a fraction, being less than 
three feet in defect, when compared with the geometrical mea- 
surement. The height is deduced from the barometrical obser- 
vations by the method given by Mr. Daniell, in the Quarterly 
Journal. 

The near accordance of these results will, Capt. S. hopes, be sa- 
tisfactory to those who are practically acquainted with the very 
ready means which the barometer affords of measuring heights ; 
the doubt which had been thrown on its equal applicability in the 
northern regions, as in the temperate and tropical climates, by 
the great. differences which appeared in a similar comparison 
made by Capt. Phipps and Dr. Irving, in the year 1773, and 
which are now shown to have originated in error of some kind, 
being wholly removed. 

The Society, on account of the approaching festival, then 
adjourned over two Thursdays, to meet again on the 29th of 
April. 


LINNEAN SOCIETY. 


Dec. 16, 1823.—The reading of Mr. Murray’s paper on the 
Lampyris noctiluca was resumed and concluded; and the fol- 
lowing communications were read. 

“< Observations on some of the terrestrial Mollusca of the 
West Indies; By the Rev. Lansdown Guilding, BA. FLS.” 
Among the species described in this paper were Helicina occi- 
dentalis, corpore livido, dorso tentaculisque atris, oculis pro- 
minulis—TIn montibus sylvosis Sancti Vincentii; Budlimus he- 
mostomus, corpore olivaceo-nigro, corrugato: pede subtus pal- 
lido: capite bifariam crenato.—In dumetis Antillarum ; Buli- 
mulus stramineus ; and Pupa undulata. 

“« An account of some rare West Indian Crabs ; ” by the same. 
The Society then adjourned to January 21, 1824. 

Jan. 21.—Among the presents received at this meeting was a 
specimen of anew species of Cyprinus viviparus, from Don 
Vincente de Cervantes, Professor of Botany in the University 
of Mexico. 

A paper was read, “ On a new species of the genus Gadus : 
by Mr. Jonathan Couch of Polperro, in Cornwall.” This dimi- 
nutive species, called by fishermen the Mackarel Midge, is 
only an inch and a quarter in length: its proportions are 
nearly those of the Whiting. r 

The reading was commenced of a paper “ On the Natural 


* Mr. Newman’s account of these instruments will be found in the last number of the 
Annals. 


1824.] Linnean Society. 387 


Affinities that connect the Orders and Families of Birds: by 
N. A. Vigors, Esq. MA. FLS. Communicated by the Zoological 
Club of the Linnean Society.” 

Feb. 3.—Among the presents received at this meeting was a 
Collection of Plants, made by Lieut. Col. Wright, of the Royal 
Engineers ; during a journey through Circassia, Persia, and 
Georgia. 

A notice by Mr. John Hogg, of Norton, Durham, was read, 
stating that a fine specimen of Falco chrysaétos, or Golden 
Eagle, was lately shot near the mouth of the Tees; being the 
fifth known to have been killed in England. 

The reading of Mr. Vigors’ extended paper was then resumed 
and continued ; and it likewise occupied the attention of the 
Society on Feb.17 and March 2. 

March 16.—The reading of Mr. Vigors’ paper was alse con- 
tinued at this meeting ; and the following other communications 
were read. 

“ Description of Erythrina Secundiflora. By Don Felix Avellar 
Brotero, Emeritus Professor of Botany in the University of 
Coimbra; For. Mem. of the Society.” 

- “On the insect called Oistros by the ancient Greeks, and Asz/us 
by the Romans. By W.S. MacLeay, Esq. FLS. Communi- 
cated by the Zoological Club of the Linnean Society.” In this 
paper, which may interest the lovers of classical antiquity as 
well as of natural history, Mr. MacLeay has produced many 
interesting proofs that the (estrus of the ancients, 
cui nomen Asilo 
Romanum est, (stron Graii vertére vocantes.” (Vire. Geor. IT.) 
was not the insect to which the name is now given; but a 
Tabanus. Olivier first observed that it was different from the 
(strum of the moderns. Pliny uses the name J'abanus or the 
Muw}, which Aristotle says is nearly related to Cstrus, both 
being curposbeyxevrpa ; it cannot therefore be the modern CHsirus : 
he also says that both are bloodsuckers, which agrees with the 
Linnean Yabani, but is wholly inapplicable to the modem 
Qistrus. As the insect is too well known for its name to have 
been forgotten or misapplied, there can be little doubt that the 
Latin Tabanus, the Italian Tabano, Spanish Tavano, and French 
Taon are identical, which latter name Mouffet gives us the same 
with the English Breese, Clegg and Clinger, mentioned by 
Shakspeare, who, speaking of Cleopatra, says: 
‘© The Brize upon her, like a cow in June, 
Hoists sail and flies.’’ 
Some elucidation is also brought from Homer, and the Prome- 
theus of Aischylus, and it is observed that Virgil describes the 
Asilus or Cistrus as abundant and acerba sonans, whereas our 
Estrus bovis is a rare and silent insect. They were first con- 
founded by Valisnieri, who has been followed by Martyn and 
others. It is inferred that Aristotle did not even know the 
“2ce2 


388° Proceedings of Philosophical Societies. [May, 
latter, from his assertion that no dipterous insect has a sting 


behind. ea 

April 6.—-A letter was read, from the Rev. W. Whitear, of 
Harleston, in Norfolk, stating that a Little Bustard had. been 
shot, in December last, at Little Clarton, in Essex. He con- 
siders it to be a curious fact that this bird, an inhabitant of a 
southern climate, should have been met with in this country, im 
winter. 

A description was likewise commenced, of a Collection of Arctic 
Plants formed by Captain Sabine, during a voyage to the Polar 
Seas, in 1823: by W. J. Hooker, LLD. FRS. &c. Communi- 
cated by the Council of the Horticultural Society. 

April 20.—Sir T. Gery Cullum, Bart. FLS. presented some 
sections of Fir timber, pierced toa great depth by the Sirer ju- 
vencus of Linneus ; together with specimens of the insect itself. 
They were from the woods of Henham Hall, in Suffolk, the seat 
of the Earl of Stradbroke, where two hundred Scotch. Firs 
have been destroyed by this insect ; being bored through and 
through. The reading of Dr. Hooker’s description of the 
Arctic Plants collected by Capt. Sabine was continued. 

A Catalogue of the Norfolk and Suffolk Birds, with remarks ; 
by the Rev. Revett Shephard, AM. FLS., and the Rev. W. 
Whitear, AM. FLS., was read in part, and the remainder post- 
poned to a future meeting. 


ZOOLOGICAL CLUB. 


We have hitherto been prevented from noticing this useful 
association. Its first meeting was held in the apartments of the 
Linnean Society on the 29th of November last, the birth-day of 
our celebrated countryman John Ray. The Club is composed 
of members of the Society devoted to the study of zoology and 
comparative anatomy, and has been organized with the view of 
advancing the knowledge of those sciences, in all their branches, 
under the sanction of the Society. This body will not have any 
publications of its own, but will submit all original communica- 
tions made to it to the Council of the Linnean Society, who will 
decide upon them as upon all other communications. 


Before the Zoological Club proceeded to the election of their — 


officers and the other business of the day, an admirable opening 
address, explanatory of the views of the association, was deli- 
vered by the Rev. W. Kirby, FR. and LS. who had been unani- 
mously called to the chair. 

The following members were then appointed to form the Com- 
mittee and Officers for the management of the affairs of the Club 
for the ensuing year :— 

Joseph Sabine, Esq. Chairman ; J. F. Stephens, Esq. T'reasu- 
rer; N. A. Vigors, Esq. Secretary: Rev. W. Kirby; A. H. 
Haworth, Esq.; Thomas Horsfield, MD.; Thomas Bell, Esq. ; 
E. T. Bennet, Esq.; G, Milne, Esq. 


1824.] Astronomical Society. 389 


The meetings of the Zoological Club, at which all the mem- 
bers of the Linnean Society are entitled to be present, are held 
at the Society’s apartments in Soho Square, at eight o’clock in 
the evening, on the second and fourth Tuesdays of every month 
throughout the year. 


ASTRONOMICAL SOCIETY. 


March 12.—The papers read at this meeting of the Society 
were as follows : 

_ A letter from Sir Thomas Brisbane, Governor of New South 
Wales, to F. Baily, Esq. accompanied by Mr, Rumker’s, obser- 
vations of the Summer Solstice 1823 at Paramatta; the results 
of which are; ; 


For the mean obliquity of the Ecliptic. ...... 23° 27” 44:39” 
For the latitude of the place of observation. .. 33 48 42°61. 


Also the mean of twelve months’ meteorological, observations 
made at Paramatta between May, 1822, and May}d823.. — 

A letter from Prof. Schumacher, of Altona, including Mr. 
Hanson’s computations of the elements of the comet of 1823, 
1824, from observations made in the month of Jan..182435 

Two letters from Mr. Taylor, jun. of the Royal Observatory, 
Greenwich ; the first contaming the elements of the same comet 
as computed by himself from the Greenwich observations of 
January, 1824, using Boscovich’s method ; and the second, a 
comparison of anticipatory ephemerides of the places of this 
comet, from the elements computed severally by Schumacher, 
Carlini, Dr. Brinkley, and himself, with the Greenwich obser- 
vations. | 

On the Rectification of the Equatorial, by J. F. Littrow, 
Director of the Imperial Observatory at Vienna. In this paper 
the author directs his attention to those errors only which de- 
pend upon the placing and use of the instrument, which the 
observer himself must either be able to obviate or allow for ; 
and he therefore enumerates the greater part of them, and 
points out means for their rectification. ‘ 

On the Utility and probable Accuracy of the Method of deter- 
mining the Sun’s Parallax, by observations on the planet Mars 
near his opposition; by Mr. Henry Atkinson, of Newcastle- 
upon-Tyne. In this paper the author shows, that in a series of 
observations on Mars, taken with good instruments used in 
‘north and south latitudes, the probability of error is very small ; 
-anid as the synodical revolution of Mars takes place in about 
780 days, that planet will be 23 times in opposition before the 
next transit of Venus on the 8th Dec. 1874. Hence he infers, 
that if careful corresponding observations are made on each of 
‘those 23 oppositions, the probable error would be reduced nearly 
4:796 times. The author concludes his paper by. deseribing 


390 Proceedings of Philosophical Societies. [May, 
what he regards as the best means of carrying this method into 
effect. 

A new annular Micrometer by Frauenhofer was submitted to 
the inspection of the Meeting by Mr. Francis Baily. This 
instrument is called by the artist the suspended circular 
micrometer, from the circumstance of its appearing (in the 
telescope) as if suspended in the heavens without any support. 
It consists, in fact, of nothing more than a circular piece of 
plate-glass about one-inch in diameter, in the centre of which a 
circular hole is cut, of half an inch in diameter. To the inner 
edge of this glass circle a narrow ring of steel is firmly and 
securely fastened ; and, the whole being put ina lathe, the steel 
ring is turned perfectly circular, and reduced to a very thin 
edge, both at its exterior and its interior circumference. The 
glass, with its steel circle, is then burnished into a brass ring or 
cap, by means of which it may be placed, when required, in the 
focus of the telescope. 

The advantages attending this construction are, 1. The preser- 
vation of the circular form of the ring, as it comes from the 
Jathe, ‘without the risk of its being injured in attaching it to the 
telescope in.the usual manner: 2. In the use of steel instead of 
-brass, whereby a finer edge may be given to the circumferences : 
3. In rejecting the metal arms by which these rings were for- 
merly attached to the sides of the telescope, from the unequal 
expansion of which (or any external violence given thereto) the 
perfect form of the circle might be injured, without being imme- 
diately detected: 4. In thus avoiding the obstructions which 
those arms might, in some cases, by their position, occasion in 
the observations of the passage of a star before it entered the 
interior of the ring. 

April 9.—At this meeting the following papers were read, viz. : 

1. On the Elements of the Orbit of the Comet of 1823, com- 
puted from Observations made at the Royal Observatory at 
Greenwich, by Mr. W. Richardson, Assistant to the Astronomer 
Royal. These elements were computed by Dr. Olber’s method. 
The paper likewise contained a comparison of his elements with 
the Greenwich observations from Jan. 1 to Feb. 2, and in more 
than half the observations, the results of the elements did not 
differ from them so much as 2’ in longitude, or so much as I’ in 
latitude. 

2. Onthe Corrections requisite for the Triangles which occur 
in Geodesic Operations ; by Capt. G. Everest, of Bengal, Con- 
ductor of the Trigonometrical Survey in India. This paper con- 
tained the solution of two problems by formule employed in 
India since 1819, and which the author thinks preferable to 
those given by M. Delambre for the same purpose. They 
require the use merely of pocket logarithmic tables, with four 
places of decimals, of which copious examples were given; and 


1824.] Geological Society. 391 


the paper concluded by the application of these formule to the 
aan of angles actually observed in the operations in 
ndia. 

3..On the Method of determining the Difference of Meridians 
by the Culmination of the Moon ; by Francis Baily, Esq. FRS. 

. Pres. Ast. Soc. This paper was too long to permit its read- 
ing to be completed at the present sitting; and we shall, there- 
fore, reserve our remarks upon it until it is concluded. 

Several very valuable books were presented to the Society. 


GEOLOGICAL SOCIETY. 


Feb. 20.—A notice was read on the Megalosaurus, or great 
Fossil Lizard of Stonesfield, near Oxford; by the Rev. W. 
Buckland, FRS. FLS. President of the Geological Society, and 
Prof. of Mineralogy and Geology in the University of Oxford, 
&e. Ke. 

The author observes that he has been induced to lay before 
the Society the accompanying representations of various portions 
of the skeleton of the fossil animal discovered at Stonesfield, in 
the hope that such persons as possess other parts of this extra- 
ordinary reptile may also transmit to the Society such further 
information as may lead to a more complete restoration of its 
osteology. No two bones have yet been discovered in actual 
contact with one another, excepting a series of the vertebre. 

_ From the analogies of the teeth they may be referred to the 
order of the Saurians or Lizards. From the proportions of the 
largest specimen of a fossil thigh bone, as compared with the 
ordinary standard of the Lacerte, it has been inferred that 
the length of the animal exceeded forty feet, and its height 
seven. Prof. Buckland has, therefore, assigned to it the name 
of Megalosaurus. The various organic remains which are found 
associated with this gigantic lizard form a very interesting and 
remarkable assemblage. After enumerating these, the author 
concludes with a description of the plates, and observations on 
the anatomical structure of such parts of the Megalosaurus as 
have hitherto been discovered. 


MEDICO-BOTANICAL SOCIETY. 


. Feb. 13.—Some observations were made on the Acacia Cate- 
chu. A paper was also read, on a bark termed the Malambo 
Bark, lately imported from America. 

Feb. 27,—Some observations were read, on the alterations in 
the Pharmacopeeia. 

March 12.—A paper was read, entitled “‘ Observations on the 
Anthroxanthum Odoratum ; by T. Rowcroft, Esq. his Majesty’s 
Consul General at Peru: communicated by Dr. Bree, President. 

March 26.—Some observations were made on the Croton 
Tiglium ; by Mr. Pope, of Oxford-street. ; 

April 9.—A paper was read on the Resina Acaroides, by Mr 
W. Bollaert. 


392 Scientific Intelligence. {May, 


f 


ARTICLE XIV. 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS. 
CONNECTED WITH SCIENCE. 


I. The Logan Stone in Cornwall overturned. 
(To the Editor of the Annals of Philosophy.) 
DEAR SIR, Plymouth, April 18, 1824. 


Your geological readers will hear with infinite regret, that the cele- 
brated Logan Stone in Cornwall, which has for so long a period been 
regarded as an object of great national interest and curiosity, and which 
has been visited by persons from the remotest extremity of Europe, 
has within the last few days been overturned by one. of the Lieutenants 
of his Majesty’s navy, now commanding a revenue cutter, stationed 
between the Lizard and Lands End, assisted by a party of his men. 
The barbarous and wanton folly which could induce an officer bearing 
his Majesty’s commission to commit so unwarrantable an act, as to 
remove a great national curiosity from a position in which it had stood 
for ages, defying the hand of time, and affording to the enlightened 
traveller an object of such singular interest, will, it is hoped, be visited 
with the severest displeasure of the Admiralty. In a tour through 
Cornwall in the summer of 1521, I was informed by a cottager who 
lived near the spot, that an attempt was made by a party of seamen 
some years before, to remove it, but without success. Cornwall, by 
this wanton outrage, has lost one of its most interesting monuments. 

I remain, dear Sir, yours very truly, G. W. Harvey. 


Il. The Rate of a Chronometer varies with the Density of the Medium 
in which it is placed. 

Mr. Harvey, FRSE. has lately discovered that the density of the 
medium in which a chronometer is placed, has a sensible influence on 
its rate, in most cases producing an acceleration, when the density is 
diminished, or a retardation, when the density is increased. Ina tew 
time-keepers he has found the reverse to take place, viz. a decrease of 
rate from diminished density, and an increase from increased density ; 
but the former appears to be the most general effect. Mr. Harvey 
has proved this to be the case, by an extensive course of experiments, 
and in which he has subjected many chronometers to pressures, from 
half an inch of quicksilver to 75 inches; and in all cases has found, 
that if a time-keeper gained by increasing the density, it Jost by dimi- 
nishing it,.and vice versd. A difference of density denoted by an 
inch of quicksilver, is sufficient to produce in many chronometers a 
visible alteration of rate. 

The following are a few of Mr. Harvey's results :-— 

A pocket chronometer which possessed a steady: rate of 4+ 16 
under the ordinary circumstances of the atmosphere, had its rate in- 
creased to + 6'-2, when the density of the air was diminished to a 
quantity represented by 20 inches of quicksilver; and on afterwards 


placing it in air, of'a density denoted by 10 inches of quicksilver, a far- - 


ther increase of its rate to + 11/0 took place. On restoring the time- 
keeper to the ordinary e¢ircumstances of the atmosphere, its rate-re- 
turned to + 2”1, : 


ee ee 


1824.) Scientific Intelligence. 393 


In another set of experiments with the same chronometer, Mr. H. 
placed it in a condenser, under an atmospheric pressure of 45 inches, 
when its rate changed to — 4-4; and on increasing the density of the 
air to a quantity denoted by 60 inches of mercury, the daily variation 
farther declined to — 8!"2. 

In another remarkable experiment, Mr. Harvey found, that when the 
rate of a chronometer was + 23"-5, under a receiver having its air 
exhausted to a quantity denoted by half an inch of mercury, the rate 
was altered to — 17-2, when the air was increased to a density cor- 
responding to 75 inches of quicksilver; the rate of the time-keeper, 
under the ordinary circumstances of atmospheric pressure, being 
+ 4lle'7 

Mr. H. has, we understand, drawn from it several important conclu- 
sions. For example, that a chronometer. constructed in London, 
nearly on the level of the sea, would undergo.an. alteration of rate, 
from difference of atmosphere alone, if transported. to Geneva, to 
Madrid, to Mexico, or any other place, situated much above the level 
of the place where it was constructed. 


III. Cheltenham Water. 


Mr, Faraday has examined the water from the Orchard well at the 
above place. A pint of this water yielded : 


Carbonate of lime ...... a ee 

Sulphate of lime ............ veoe - 14:5. 
“- Magnesia ........... 12°4 
——-- s0da cee eeu ceca 3:7. 
Muriate of soda .......+.5.5.-5» 97°0 
129-2 


Besides which the water contained a portion of carbonic acid; and 
a small quantity of peroxide of iron had settled at the bottom of the 
bottle. By using two tests suggested by Dr. Wollaston, this water 
was also found to contain small portions of nitric acid and potash. 

On adding sulphuric acid to a portion of this water, in quantity 
abundantly sufficient to decompose all the salts subject to its action, 
and boiling the acidulated water in a flask with a leaf of gold for an 
hour, the gold either in part or entirely disappeared, and a solution 
was obtained which, when tested by protomuriate of tin, gave a deep 
purple tint. Hence the presence of nitric acid, originally in the water, 
was inferred, and that no mistake might occur, a solution made in 
pure water of all the salts, except the nitrate found in the water, 
was boiled with some of the same sulphuric acid, and tested by the 
same muriate of tin; but in this case no colour was afforded, nor any 
gold dissolved. 

The potash was ascertained to be present by evaporating a quantity 
of the water until reduced to a small portion, filtering it, and then add- 
ing muriate of platina in solution. ‘Three pints of the water, evapo- 
rated until about an ounce of fluid remained, gave an abundant pre- 
cipitate of triple salts of potash and platina. In cases where small 
quantities of the waters were tried, it was necessary to let the liquid 
stand an hour or two after applying the muriate of platina, but the 
se salt always ultimately appeared.—( Royal Institution Journal, 
vol. xvii. p, 179.) ¥ i 


394 Scientific Intelligence. [May, 
IV. Detonating Silver and Mercury. 


Dr. Liebig has analyzed both these compounds, prepared by the 
well-known process of causing alcohol to act upon the nitrates of the 
respective metals. It appears from the experiments detailed that the 
substance combined with the metallic bases is an acid, and separable 
from them by means of the alkalies and metals, and they then form 
the detonating compounds. To analyze detonating silver and mer- 
cury, 100 parts of each were mixed with 400 parts of calcined magne- 
sia, and heated in a retort, the products received were: 


From detonating silver. From detonating mercury. 
Carbonic acid........ OR clr ed ote eel 25°38 
Apmmnia: lise ianathora vl) Db onde ia pee ae 10:0 
Walebi sion ibe. aca ee de" Dealt, mt aeemadtins 52 
SiVER 431i 66 + emia - 41:0 Mercury ........ 56°9 
TGQ8S.4.5, isla zidpcianiat’ns ail 2°6 Rit» im cited 21 
100'0 100'0 


The above are the mean of four experiments ; these give as the ul- 
timate elements. 


Detonating silver. Detonating mercury. 
ORYSEN! sis's oe cl ete BAAS ANS 42000 DO a 23°39 
Hydrogen ...... vets o OA. anil 10: ahbaelde ae 2°34 
tC tS age rata TP28) aah Vtech 8°23 
Carbon Gb s vee oe. oh DEB eatin del et ieee 7°04: 
Silver 2gsity gait vee REO || neu By cadet 56°90 


The salts formed of the acid of these detonating compounds have 
been termed fulminates. With potash, the salt formed crystallizes in 
long brilliant plates, which do not affect turmeric paper, have a dis- 
agreeable metallic taste, and detonate when heated or struck. It 
consists of 85:08 acid, and 14°92 base. The fulminate of soda crys- 
tallizes in brown brilliant plates, it is more soluble in water than the 
fulminate of potash, but resembles it in other properties, and is com- 
posed of 88°66 acid, and 11°34 of soda. Magnesia, barytes, strontia, 
zinc, and copper, all combine with this acid to form compounds.— 
(Ann. de Chim. xxiv. 294.) 

V. Absorption of Air by Mercury. 

In our analysis of Sir H. Davy’s paper “ On the Electrical Pheno- 
mena exhibited in vacuo,” Annals, N. S. iv. 379, we briefly mentioned 
his statement respecting the absorption of air by mercury, and its 
emission when the mercury is heated in vacuo. In Mr. Daniell’s Me- 
teorological Essays, p. 363, we find a different view of the subject; 
and as it is one of considerable importance, we now present that view 
to our readers, 

«< During my experiments upon the filling and boiling of the baro- 
meter tubes, my attention was particularly directed to the assertion of 
Sir H. Davy (Phil. Trans. 1822, p. 74), that ‘ there is great reason to 
believe that air exists in mercury, in the same invisible state as in water, 
that is, distributed through its pores ;’ and to the disheartening fact (if 
proved), that absorption of air ‘may explain the difference of the 
heights of the mercury in different barometers; and seems to indicate 
the propriety of re-boiling the mercury in these instruments, after a 


1824.] Scientific Intelligence. 395 


certain lapse of time.’ It is with much diffidence that I am compelled 
to differ from the high authority of the President upon this interesting 
point: but there is one observation which I made, which, 1 think, 
nearly disproves the supposition. All fluids, which are known to ab- 
sorb air into their pores, invariably emit it when the pressure of the 
atmosphere is removed: but upon an attentive examination of large 
bodies of mercury, variously heated in the vacuum of an air-pump, I 
never saw a bubble of air given off from the surface of the metal. Air 
will rise from the contact of the mercury with the glass in which it is 
contained, in exact inverse proportion to the care with which it has 
been filled, but it never rises from the surface of the mercury alone. 
The difficulty of properly filling a barometer tube, I attribute to the 
attraction between the glass and the air, not to that between the mer- 
cury and air; and I believe that air will insinuate itself a little way 
between the glass and the metal, at the exposed end of a boiled tube, 
but that this cannot happen if the end be plunged in mercury; and, 
consequently, that no deterioration of barometers is to be apprehend- 
ed from this cause. Such a deterioration, indeed, if it had existed, 
must, long ago, have been detected from the instruments themselves ; 
for although the register of the Royal Society is not in such a state as 
to enable any one to reason upon its conclusions, that of the Royal 
Observatory of Paris, and some others, must have disclosed the fact.” 


VI. Connexion of Phosphorescence with Electricity. 


The sulphate of quina was shown by M. Callaud d’Annecy some 
time since to become highly phosphorescent when rubbed at a tempe- 
rature of 212°. MM. Dumas and Pelletier have ascertained that it 
becomes highly negatively electrical when rubbed on woollen cloth, 
and hence were led to the verification of a suspicion they had long 
entertained that phosphorescence was an electrical phenomenon. 
About two or three ounces of sulphate of quina were introduced into 
a glass flask, and heated for half an hour in a water bath at 212° F., 
it then by friction gave out a sufficiently intense light. The flask was 
closed by a cork, through which passed a wire pointed at the inner 
extremity, and terminated by a ball at the external end; on approach- 
ing this ball, two or three times to the knob of a voltaic electrometer 
furnished with its condenser, having taken care to shake the flask 
before each contact, the leaves became so electrical as to diverge as 
much as the instrument would admit of, the electricity being con- 
stantly positive. 

The sulphate of cinchonia, which is phosphorescent like the sul- 
phate of quina, though less so, also became electrical in the same 
manner. Its electricity, though of the same kind, was not so strong as 
that of the preparation of quina.—(Ann. de Chim. xxiv. 171.) 


VII. Preparation of Oxide of Nickel. By M. Berthier. 


Speiss, or impure nickel, is to be reduced to fine powder and roasted 
till it gives off no further vapours of arsenic, the heat being at first 
moderate to prevent fusion, and then increased. Metallic iron.in the 
state of filings or nails is to be added in a quantity which ought pre- 
viously to be determined, and the whole dissolved in boiling nitro-mu- 
riatic acid, so much nitric acid being used that no protoxide of 
‘iron remain in the solution; evaporate to dryness and re-dissolve in 


396 New Scientific Books, [May, 


water, when a large quantity of arseniate of iron will be left. Add to 
the solutions successive portions of carbonate of soda until a greenish 
precipitate appears, at which time all the arsenic and iron will be se- 
parated, and part of the copper; the rest of the copper may be 
separated by sulphuretted hydrogen, and the clear solution thus obs 
tained, when boiled with sub-carbonate of soda, yields the carbonate 
of nickel. 

Thus obtained, the carbonate of nickel contains a little cobalt; to 
separate the latter, the precipitate, as obtained above by boiling with 
sub-carbonate of soda, 1s to be well washed and diffused whilst moist 
in water, and a current of chlorine passed into it until in excess: the 
excess of chlorine is to be allowed to dissipate and the solution filtered ; 
it now contains not the smallest trace of cobalt, that remaining as a 
hydrated peroxide, with a certain portion of nickel in the same state. 
If in the mixed carbonate of nickel and cobalt, the latter is in excess; 
the residue, after the action of the chlorine, is pure hydrate of cobalt, 
and the solution contains the nickel with a small quantity of cobalt.— 
(Ann. de Chim. xxv. 95.)* 


VIII. Prussian Blue. 


Mr. Badrall, of Leek, has taken out a patent for improvements in 
dyeing with Prussian blue. The improvement consists in preparing 
the Prussian blue, -by mixing it in fine powder with strong muriatic 
acid, and stirring it until the whole becomes a smooth homogeneous 
mass of a semi-gelatinous consistence. We notice it here merely to 
remark on the circumstance that an agent in which Prussian blue is 
insoluble, should be found useful in enabling it to combine with silk, 
cotton, wool, &c. The pure ferro-prussiate of iron is soluble in water, 
but the addition of a small portion of muriatic acid immediately 
precipitates it ; wash away the acid by pure water, and the pigment 
becomes soluble again ; re-acidify, and it re-precipitates.— (Institution 
Journal.) 


ARTICLE XV. 
NEW SCIENTIFIC BOOKS. 


PREPARING FOR PUBLICATION, 


An Appendix to Capt. Parry’s Second Voyage of Discovery, con- 
taining the Natural History, &c. 4to. 

The private Journal of Capt. G, F. Lyon, of his Majesty’s Ship 
Hecla, during the recent Voyage of Discovery, under Capt. Parry, 
Svo. 

Narrative of the Proceedings of the Expedition to explore the 
Northern Coast of Africa, in 1821, 1822. By Capt. W. F. Beechiey, 
RN. and H. W. Beechey, Esq. 4to. 

Narrative of Four Voyages of Survey in the Inner Tropical and 
Western Coast of Australia, between the Years 1817 and 1822. By 
Philip Parker King, RN. Commander of the Expedition. 4to.. 


* Dr. Thomson’s process for obtaining pure oxide of nickel is much more simple, 
and I believe as efficacious as the above.x—Zdit, 


1824.] New Patents. 397 


Narrative of a Voyage of Discovery in the Interior of Africa, from 
the Western Coast to the River Niger in 1818, 1819, 1820, and 1821. 
By Brevet Major Gray. 8vo. 

- Journal of a Tour in Asia Minor. By W. Martin Leake, FRS. 8vo. 
- Lisbon in the Years 1821, 1822, and 1823. By Marianne Baillie. 
2 vols. small 8yo. 


JUST PUBLISHED. 


Bostock’s Elementary System of Physiology. 8vo. 15s. 

. The Zoological Journal, No, I. 10s, (Tobe continued Quarterly.) 
_ The History of Ancient and Modern Wines. With Embellishments 
from the Antique. 4to. 2/.2s. With the Vignettes on India paper, 
a 

_ Selection from De Humboldt, relating te the Climate, Productions, 
Mines, &c. of Mexico. By John Taylor, Treas. Geol. Soc. 8vo. 12s, 

Trayels in Brazil, in the Years 1817, 1818, 1819, and 1820, under- 
taken by the Command of the King of Bavaria. By Drs. J. Von Spix, 
and C. Von Martins. Vols.I. and II. S8vo. 1/7. 4s. 

Critical Researches in Philology and Geography. 8vo. 8s. 

The Perennial Calendar and Companion to the Almanac, as con- 
nected with History, Botany, Natural History, Astronomy, &c. &c, 
By Thomas Forster, FLS. &c,  8vo. 18s. 

Naval Battles from 1744 to 1814, critically reviewed and illustrated, 
By C. Ekins, Rear-Adm. CB. &c. 4to. with 79 Plates and numerous 
Diagrams, 31. 3s. 


ARTICLE XVI. 
NEW PATENTS. 


J. Arrowsmith, Esq. Air-street, Piccadilly, for animproved mode of 
publicly exhibiting pictures or painted scenery of every description, 
and of distributing or directing the day-light upon or through them so 
as to produce many beautiful effects of light and shade, which he deno- 
minates Diorama.—Feb. 10. 

R. Lloyd, Strand, hatter, and J. Rowbotham, of Great Surrey-street, 
Blackfriar’s-road, Surrey, hat-manufacturer, for their having invented 
and brought to perfection a hat upon a new construction which will be 
of great public utility —Feb. 19. 

H. Adcock, Summer Hill Terrace, Birmingham, gilt toy manufac- 
turer, for his improvement in making waistbands.—Feb. 19. 

W. Charch, Esq. Birmingham, Warwickshire, for certain improve- 
ments in machinery for printing. —Feb. 19. 

A. Applegath, Duke-street, Stamford-street, Blackfriars, Surrey, 
printer, for certain improvements in machines for printing.—Feb. 19. 

Rev. M. Isaacs, Hounsditch, for certain improvements in the con- 
struction of machinery, which, when kept in motion by any suitable 
power or weight, is applicable to obviate concussion by means of pre- 
venting counteraction, and by which the friction is converted into an 
useful power for propelling carriages on land, vessels on water, and 
giving motion to other machinery.—Feb, 19. 


398 New Puaéents. [May, 
J. Vallance, Esq. Brighton, for his method of communicating goods 


or intelligence from one place to another with greater expedition than: 


by means of steam-carriages, or other vessels.—Feb. 19. 

A. H. Chambers, Esq. New Bond-street, Middlesex, for his invent- 
ed improvements in preparing and paving horse and carriage ways.— 
Feb. 28. 

R. Evans, Bread-street, Cheapside, wholesale coffee-dealer, for his 
process of roasting coffee and other vegetable substances, with improve- 
ments in the machinery employed.—Feb. 28. 

J. Gunby, New Kent-road, Surry, sword and gun manufacturer, for 
a process by which a certain material is prepared, and rendered a suit- 
able substitute for leather—Feb. 28. 

J. Christie, Mark-lane, merchant, and T. Harper, Tamworth, Staf- 
ford, merchant, for their improved method of combining and applying 
certain kinds of fuel.—Feb. 28. 

W. Yetts, Great Yarmouth, merchant and ship-owner, for his 
invented certain apparatus to be applied to a windlass.—Feb. 28. 

J. W. Richards, Caroline-street, Birmingham, metallic hot-house 
maker, for his improved metallic frame and lap, applicable to all hot- 
houses, green-houses, horticultural frames and glasses, sky lights, and 
other inclined lights and glasses.—Feb. 28. 

W. Greaves, Sheffield, merchant, for certain improvements to har- 
ness, principally applicable to carriages drawn by one horse.—Feb. 28. 

W. James, Westminster, land agent and engineer, for certain im- 
provements in the construction of rail and tram roads or ways.— 
Feb. 28. 

M. de Jough, Warrington, in the County Palatine of Lancaster, 
cotton-spinner, for his mode of constructing and placing a coke oven 
under or contiguous to steam or other boilers, so as to make the heat 
arising from making coal or other intense combustion in the said oven 
subservient to the use of the boiler, instead of fuel.—Feb. 28. 

C. Bagenell Fleetwood, Gent. Parliament-street, Dublin, for his 
invented liquice and composition for making leather and other articles 
waterproof.— Feb. 28. 

J. Spiller, Chelsea, Middlesex, engineer, for improvements in the 
machinery to be employed in the working of pumps.—March 6. 

J. Heathcoat, Tiverton, Devon, lace manufacturer, for a new method 
of manufacturing certain parts of machines used in the manufacture of 
Jace commonly called bobbin net.—March 9. 

J. Heathcoat, Tiverton, Devon, lace-manufacturer, for his improved 
economical method of combining machinery used in the manufacture 
of lace in weaving and in spinning worked by power.—March 9. 

W.D. Mosley, Radford, Nottingham, lace-manufacturer, for im- 
provements in the making and working of machines used in the manu- 
facture of lace commonly called bobbin net.—March 10. 

W. Morley, Nottingham, lace-manufacturer, for various improve- 
ments in machinery now in use for the making lace or net commonly 
known by the name of bobbin net.—March 15. 

R. Kirk, Osborne-place, Whitechapel, dyer, for his new method of 
manufacturing a certain vegetable substance, growing beyond the seas, 
as a dye or red colouring matter for the use of dyers called safflower, 
so as more effectually to preserve its colouring principle.-—March 20. 


1824.] Mr. Howard’s Meteorological Journal. 399 


ArticLte XVII. 


METEOROLOGICAL TABLE. 


et 
BaAromMETER, THERMOMETER, 
_:1824, Wind. Max. Min. Max. | Min. | Evap. | Rain. 
3d Mon. 
March 1IN W| 29:94 29:82 45 28 oan 02 
2; N 29°82 29°12 38 27 _ 
3IN W| 30°02 29°12 34 27 — 05 
4IN WI 30°04 29°72 45 33 _ 
5| W 29°97 29°72 50 39 os ps 
6S Wi 29:97 29:70 52 44, “44 07 
71IS Wi 29:70 29°35 52 44 — 48 
8iS Wi 29:87 29°35 52 34, — 09 
9S Wi 29°87 29°82 48 35 ais ats 
-OIN E! 3011 29°83 45 28 == 03 
ll} W 30°16 29°71 48 30 -- 23 
12IN Wi 2971 29°52 49 34 a 16 
13IN W); 30:00 29°51 48 33 _ 03 
14, N 30:20 30°00 46 27 — i 
15| S§S 30°20 30°10 4S 36 46 06 
16|. W | 30°26 50°10 48 40 _ 
17, W | 30°35 30°26 AS 33 —_ 
4sN W_ 30°38 30°35 58 38 a 
19N Wj, 30°39 30°35 58 30 _ 
90| E | 30°39 30°05 55 Al _ 
215 wi 3005 | 2978 | 48 | 36 | — 23 
22) Var. | 29°93 29:76 43 29 — 34 
23} N | 30:08 29'93 48 35 — 07 
24IN E; 30.21 30:08 Ad 38 — 
25IN EE) 30°21 30713 | 45 37 ~— 
26|IN ._ EB, 30°13 30°01 45 34 — 
Beit IN 30°03 29°91 44 32 “46 05 
98SIN E) 30°12 30°03 43 23 — 01 
29IN W, 3012 | 2990 | 47 | 34] — 
30IN W > 29°97 29:90 43 Q ~~ 13 
31| N 30°03 29°90 36 24 25 


{ 

—_—_—.-| 

| 30°39 29°12 58 23 |) 1°61 2°05 
The observations in each line of the table apply to a period of twenty-four hours, 


beginning at 9 A. M. on the day indicated in the first column. A dash denotes that 
the result is included in the next following observation. 


400 Mr. Howard's Meteorological Journal. | [May, 1824. 


a ot 
Ad - vob 


REMARKS. _ 


Third Month.—1. Fine morning: afternoon cloudy: evening rainy. 2. Fine. 
3. Stormy, with snow, sleet, and rain, at intervals; and some hail. 4. Fine. 
5. Showers. 6. Cloudy. 7. Rainy. 8. Morning rainy, with boisteroiis wind: 
cloudy. 9. Fine. ‘10, Cloudy and showery, 11. Rainy. . 12. Stormy : showers of 
hail, rain, and sleet, during the afternoon. 13. Hail showers: sleet: driving wind. 
14. Cloudy: windy. 15. Cloudy. 16—20. Fine. 21, Rainy. 22. Rain and 
sleet.’ 23. A considerable fall of snow this. morning, in very large flakes the day was 
afterwards. fine. 24, Overcast: bleak. 25. Fine: cold. 96. Fair: bleak. 
27. Showers. 28. Showers of snow and hail, with occasional gleams of sunshine. 
29, Fine. 30, Fine: bleak: snow and hajl showers. 31, Fine: bleak: a little snow. 


. RESULTS. 


Winds: N,5; E,1; 8,1; SW, 5; W,4; NW, 9; NE,5; Var. 1. 
Barometer: .Mean height a 
Hor she) WHOntthsiielos sisakinena leis Sicieidieal.on a's iclele clave a) Dore DeaRRnICHCHs 
For the lunar period, ending the Q1st..¢sseceseceeses 29°945 
For 15 days, ending the Ist (moon south), . ........ + 29°871 
For 13 days, ending the 14th (moon north) a\ee lai sinlaloe PQ MTIOD 
For 14 days, ending the 28th (moon south) .......-+. 30°127 


Thermometer: Mean height 


Por lie Month, ..02s0 pee don devacds sews cece ce seeca ae Oeee 
For the lunar period, ... 2. ..eeccccacseencecvcvcre 40-133 
For 29 days, the sun in Pisces. ........ Rb adlinv 0 eee e 39844 


Evaporation... ....... Ree ee eae er Oe ee pe PRE Sg | FE 


RAM say acncpngnestesgnscedectees voocibeincnncecessheersievescnss QOD 


Laboratory, Stratford, Fourth Month 23, 1824. R. HOWARD. »- 


ANNALS 


OF 


PHILOSOPHY. 


JUNE, 1824, 


ArTICLE I. 


Remarks on Solar Light and Heat. By Baden Powell, MA. of 
Oriel College, Oxford. 


(Continued from p. 328.) 


(18.) In attempting an inquiry into the constitution of the 
solar rays in reference to their heating power, I made the simple 
experiment described in my former communication, under an 
impression that every step in such an inquiry ought to be taken 
with the utmost caution ; and that no position however probable 
ought to be assumed till sufficiently examined by experiment. 
Those experiments appear to me to prove that in the solar rays 
no free uncombined radiant heat exists, at least in any quantity 
sufficient to produce a rise of a quarter of a centigrade degree, 
on a thermometer coated with a wash of chalk. The same 
pont, however, may be put to a more accurate and delicate test 

y means of Leslie’s differential thermometer—an effect corre- 
ponding to the twentieth part of a centigrade degree may be 
thus rendered sensible.—(See Leslie on Heat, p.11 and 420, and 
Treatise on Instruments, p. 10.) 

Being particularly desirous of ascertaining whether it were 
possible to detect the smallest appreciable degree of simple 
radiant heat in the natural state of the solar rays, I continued 
the examination of the point by the following application of the 
differential thermometer. ‘The instrument employed was of the 
“ stationary” kind, the sentient ball was blown of black glass, 
and the halves of degrees could be very readily observed on its 
scale, 

New Series, vou, vu, 2D 


402 Mr. Powell on Solar Light and Heat. (June, 


The surfaces of both balls being alike vitreous, they would be 
equally affected by any simple heat. If, therefore, a glass screen 
were so placed as to intercept the heat coming to one, but not 
that impinging on the other, the difference exhibited between this 
and the ordinary state of the instrument would make a very 
minute quantity of simple heat conspicuous. If any heat were 
thus intercepted on the interposition of the glass, the liquor 
would obviously rise towards the plain bulb. This it might do 
from the cooling effect of the glass ; but if we observe first with 
the glass (it having remained sometime with the instrument), the 
effect would be perceived without this ane UES on removing it. 

Another photometer of the “ portable” kind had the upper 
bulb coated with indian ink, and the lower washed with chalk. 
With this similar experiments were repeated. I give the follow- 
ing out of many which were all similar in their results. 

(19.) Large photometer. Bulbs, black and plain glass. 
Graduation from the black bulb. ¥ 


Glass over 
Both exposed. plain bulb two inches 
distance, 
9:30 a.m. 69°. seeeseeseeee 70° 

GO . cece secevees 60 
GS oS te BWR pte dia, OS 

2 pate? ospllpid Lids .. 87-5 
BS oe ak anthesis . 88 


Advantage was taken of moments when the indication of the 
instrument appeared tolerably stationary, which but rarely hap- 
pens when it is used without its glass case. It here appears 
that this instrument could not detect any sensible degree of heat 
intercepted. 

(20.) Small photometer. Upper bulb, indian ink. Lower 
bulb, washed over with chalk. Graduation from the upper bulb. 


Glass over lower bulb, 


half inch distance. Both bulbs exposed. 
(1.) 12° oes he 15° 
Aes hdovie dd tate 14° 18° 10° 
LR Aas LE is tule die te 13° 
BUG 4 pATT [sip eee 4h coat 23°: 20° 


(2.) 20° 22° ES Be Ble ihe 
dE yee 4 an RRP nes Fy El of 
23° Lis ee Ribs rt We fhe Se 


Here the’ fluctuations were more considerable than before ; _ 
but on comparing all the results, it is obvious that the tendency 
is to an increase rather than a decrease when the glass was 
removed. This was probably owing to the glass acting im some 
measure as interceptive of the heat radiating from the whitened — 


1824.] Mr. Powell on Solar Light and Heat. 403 


bulb, and thus altering the state of equilibrium in favour of the 
absorption of heat on its surface from the light. 

These experiments tend to confirm the conclusion maintained 
in my former paper, and to extend the limits within which it 
holds good. I do not attribute any other importance to it than 
as contributing to lay a foundation of distinctness of ideas upon 
which to proceed in the further examination of the subject, and 
in comparing the radiant heating effect emitted from the sun 
with that from incandescent and burning bodies. 

(21.) In reference to the validity of this opinion, however, we 
may make this further observation. Those rays of the sun 
which come within the reach of our examination have been here 
shown to be entirely composed of one species characterised by 
the definition before laid down. It must, however, be admitted, 
as by no means improbable, that the sun may originally give out 
a separate radiation of heat, distinguished by other properties, 
and of the same kind as the radiant heat from hot bodies. None 
of this kind reaches us, but we must consider the very different 
degree in which any medium, as air, absorbs or intercepts the 
passage of those two sorts of radiant matter. The heat from a 
hot body will not be perceptible at a short distance, while its 
light will traverse an amazing extent of length ; and thus at 
different distances the ratio between the two will be very differ- 
ent. Some degree of simple heat, therefore, may actually be 
initially radiated by the sun, and be lost before it reaches us. 
We have no reason to believe that there is any medium between 
the different parts of the solar system capable of absorbing heat. 
The highest regions of our atmosphere into which observation 
has penetrated are uniformly the coldest; but they are known to 
have a greater capacity for heat. Thus though it is possible 
that some heat may reach to that distance and be absorbed 
without becoming sensible to us, its quantity must be very 
small: if, therefore, we suppose any simple heat to be initially 
radiated from the sun, it must be all or nearly all absorbed by 
some parts or appendages of that luminary exterior to the part 
where it is generated. 

(22.) From considering the heating power which so insepara- 
bly accompanies the rays of light, which is always developed 
wherever they impinge on a surface which, from its colour, 
absorbs the rays, and which continues to act with very little 
diminution of intensity when the rays pass through transparent 
media of considerable thickness, we are led to observe some 
remarkable instances in which such effects are produced. Such 
aninstance is afforded in the case of the eye, and the phenomena 
of vision. 

What may be the immediate cause of vision, and what effects 
light may be capable of producing on the retina and optic nerve, 
we are altogether ignorant ; but we may with tolerable certainty 
infer from well known facts and universal laws, that (among 

2pn2 


404 Mr. Powell on Solar Light and Heat, (June, 


other effects) light must produce a heating effect on the black 
surface of the retina, 

Every different shade of colour and every different intensity of 
light transmitted from objects, produces a different degree of 
heat on a black surface. It, therefore, follows, that when 
objects are painted on the retina, the rays coming from different 
parts of them communicate different degrees of heat by the 
absorption of its black coat, according to their different colour, 
brilliancy, &c. And since all our distinction of objects by the 
eye depends on their colour and reflecting power—on the differ- 
ently coloured rays, and the total intensity of rays which they 
reflect, it is at least certain that the perception of objects, and 
their different parts, must be accompanied by corresponding per- 
ceptions of a difference of heating effect, whatever other distine- 
tive impressicns the different rays may be capable of producing 
on the sentient substance. Iam far from meaning to assert the 
opinion that this is the immediate cause of vision. These obser- 
vations are merely proposed as affording a curious topic of phy- 
siological inquiry. 

The heating effect of light is produced at the moment of ~ 
absorption, and is probably of a different nature from the com- 
munication of heat either by contact or by radiation. If, there- 
fore, a non-luminous body could radiate different degrees of heat 
from its different parts so as to impinge on the retina, it would 
not produce the phenomenon of vision; but this state of cireum- 
stances cannot take place, since the transparent parts of the eye 
are not, permeable to simple radiant heat; and if they became 
heated themselves, there would not be any distinction of different 
degrees of heat communicated to different parts of the retina. 
The optic nerve is the only one in the body expanded with an 
absorbing surface so as to be exposed to the external influence 
of radiant heating agents. 

(23.) The consideration of the heating effects of light to the 
phenomena of vision must be attended to in the attempt to 
compare the illuminating with the heating power of light. 

From the experiments of Sir W. Herschel, it appears that the 
greatest zl/uminating effect belongs to the yellowish-green rays. 
According to his theory, the radiant heat is separate from the 
light, and is formed of particles having less momentum, those 
of the green rays having such a momentum as is best suited to the 
eye for the purposes of vision, either too little or too great a 
momentum (as in the violet and red rays) being equally ill 
adapted for producing a vivid impression on the sight. 

Independently of all hypothesis, the above remarks are of a_ 
nature deserving great attention in the consideration, of these 
phenomena. The illuminating power of light must be referred 
not merely to any inherent properties of the rays, but to the 
nature of our organs. Hence, according to an observation just 
made, it must be inferred that either too little or too great an 


1824.] Mr. Powell on Solar Light and Heat. 405 


absorption of light, and consequent heating effect, on the pig- 

mentum nigrum, is equally unfavourable to distinctness of vision, 

and the reason of this distinction may depend entirely on the 

Cesta of the optic nerve in regard to its susceptibility to 
eat. 

(24.) In the experiment alluded to by Newton (Optics, book 1, 
part 2, prop. 8), near the prism, white light occupies the central 
part of the spectrum, which at greater distances disappears, and 
yellow and green rays fill the space. According to his expla- 
nation of this phenomenon, it follows that the illuminating effect 
of the different parts of the spectrum must vary in their propor- 
tions at different distances from the prism. 

(25.) The experiments of Sir W. Herschel (Phil. Trans. 1800) 
on the relative powers of different substances for intercepting 
light and heat, may be brought forward by some as a proof of 
the separate existence of two such agents in the solar rays ; but 
those experiments, as it will be eyident on a more attentive 
examination, do not bear at all upon this point. 

The powers of different sorts of glass, Kc. to intercept the 
sun’s light, were measured by a comparison of the distances at 
which equal illuminating effects were prodiced when an object 
was viewed through the substance under trial, and by direct 
vision. Their powers of intercepting heat were determined by 
the comparative effects of the full solar rays on a naked thermo- 
meter. 

The surface of the bulb of a thermometer, even when not 
coated with any pigment, will still absorb a considerable portion 
of the rays of light impinging on it, and will consequently be 
affected by the inseparable heating power developed by the 
absorption of those rays; and the effect will be different accord- 
ing to the colour of those luminous rays which the glass trans- 
mits. Now the relations of the colour of the rays to heating, and 
to illuminating effect, are by the experiments of the same author 
proved to be extremely different ; so that the difference which 
appears to exist in the power which the same substance has to 
transmit light and heat is by no means a sufficient ground for 
concluding the separate existence of two sets of rays. 

(26.) The consideration of the different laws followed by the 
illuminating and heating powers of the differently coloured rays, 
might lead us to doubt the close connexion between intensity of 
light and of heating effect. Indeed this consideration must be 
attended to in the attempt to compare by means of their heating 
effect on Leslie’s photometer, light from different sources. In 
these cases there is often a considerable difierence in the preva- 
lent colour of the rays, and, therefore, from this source alone, 
some difference in their heating power is to be expected. 

In relation to the different intensities of light from the same 
source, experiment seems to have shown that the closest propor- 
tion is observed. Prof. Leslie has compared the indications of 


406 Col. Beaufoy’s Astronomical Observations, [JuNE, 


his photometer with the measurements obtained by Bouguer 
from a comparison of illuminating effects, and conceives the 
result completely favourable to the accuracy of his instrument, 
(See Leslie on Heat, Chap. 20.) 

With respect to the theory deduced from these and kindred 
phenomena by that distinguished philosopher, it cannot but 
excite admiration for its simplicity, and the readiness with which 
it explains the phenomena ; but it surely cannot be considered 
as proved, that because light has the power of exciting or com- 
municating heat in those bodies on which it impinges, that the 
light is, therefore, transformed into heat ; and after all, the mode 
in which this transformation is effected in the ‘“ igneous fluid” 
still remains to be accounted for. 

Towards ascertaining the nature of the heating power thus 
excited in the solar rays, one important step seems to me to be 
involved in the question whether the heating power does always, 
and especially at high intensities, crease precisely in propor- 
tion to the intensity of light, or number of rays impinging upon, 
or absorbed by, a given surface. 

The want of a photometer on the principle of illumination, 
and that essential difficulty, the want of a standard for compa- 
rison, are great obstacles in the prosecution of such an inquiry. 
I have, however, attempted it by adopting other means in which 
these difficulties seem to me to be got rid of. As, however, the 
detail of these experiments will occupy some space, I. must 
reserve them for a future opportunity. 


ArtTicce II, 
Astronomical Observations, 1824. 
j By Col. Beaufoy, FRS. 


Bushey Heath, near Stanmore. 
Latitude 51° 37' 44°3” North. Longitude West in time 1’ 20°93”, 


April 14. Immersion of Jupiter’s third § 9 19’ 30” Mean Time at Bushey. 
SALEMUEC, « aeiele 015/4,5 jeniwja)sinio's)= 5 9 20 51 Mean Time at Greenwich. 

April 30." Emersion of Jupiter’s first ¢10 25 00 Mean Time at Bushey. 
Satellites e, oy os veesescoe ; 10 26 21 Mean Time at Greenwich. 


* Jupiter’s limb very tremulous. 


1824.] Prof. Henslow’s Reply to Dr. Berger. 407 


Articze III. 
Remarks upon Dr. Berger’s Reply. By Prof, Henslow. 
(To the Editor of the Annals of Philosophy.) 


SIR, Cambridge, May 5, 1824. 

I reLT somewhat surprised yesterday in perusing an angry 
article in your number of the Annals of Philosophy just pub- 
lished (for May), entitled, “‘ Reply to Mr. Henslow’s Observa- 
tions on Dr. Berger’s Account of the Isle of Man.” 

The examination which I made (in 1819) of the geological 
features cf that island, was undertaken with a view of deriving 
instruction, rather than with any intention of giving it; as the 
study of geology was then almost new to me. I, therefore, pro- 
cured Dr. Berger’s paper; and here acknowledge myself indebted 
to it for almost the first rudiments of a science, which has since 
afforded me so much gratification. As I had observed a few 
omissions in that gentleman’s description, as well as some errors 
with respect to the extent of certain formations laid down in his 
map, I presented my account to the Geological Society (together 
with a collection of specimens to which my remarks might be 
referred), by way of supplement to Dr. B.’s paper. From the 
“ Reply,” it should seem that I had been misinformed, in suppos- 
ing his account was not to be viewed as so perfect a perform- 
ance as he now professes to have considered it himself. It was 
under this impression that I troubled the Society with my 
remarks. 1 might, perhaps, have written to Dr. Berger (as he 
is pleased to suggest) had I been acquainted with his address ; 
but I verily believed him to be no longer in existence. 

So far as I can collect from Dr. B.’s “ Reply,” his observa- 
tions, accusations, and concessions, may be reduced to the 
eleven following heads. Upon the fourth, fifth, eighth, and 
tenth of these, I shall offer a few remarks ; the others appear 
unworthy of any comment. The charges, then, here brought 
against me, I consider to be, j 

1. The correction of an error in the geographical position 
assigned to the mountains of the south part of the island. 

2. The mention of a granitic district unnoticed by Dr. Berger. 

3. The extension of the limits assigned to a small patch of 
granite noticed in his paper. 

4, The union of the slates under one common formation, 
instead of retaining them under the boundaries assigned by Dr. 
Berger to clayslate and greywacke. 

To this I may observe, that the distinctions of mineral cha- 
racter, to which he refers, have long since been regarded (in this 
country at least) as an insufficient guide to a difference of epoch 


408 Prof. Henslow’s Réply to Dr: Berger. — (Juni, 
in the formations of clayslate, and the infinite varieties of grey- 
wacke. Unless, therefore, a distinction can be established 
from geological position, there can be no reason for separating 
them. It is possible such a distinction may exist in the Isle of 
Man, aiid I 4m éven disposed to think it does, though the limits 
assigned by Dr. Berger appeared to me so very unsatisfactory 
that I preferred designating the whole on the map by an uni- 
form colour. The propriety of this method has been confirmed 
by the learned and experienced geologist Dr. Macculloch, who 
has adopted precisely the same plan, in his account of this 
island, in the second volume of his History of the Western Isles 
of Scotland, published after my paper was transmitted to the 
Society, but before it had been printed. 

Should Dr. Berger wish for further proof that he ought not to 
consider himself infallible on points of geology, I beg leave to 
refer him to Prof. Sedgwick’s paper on the Geology of Corn- 
wall, published in the Transactions of the Cambridge Philoso- 
phical Society.* 

5. Indistinctness with regard to my “ quartzose districts.” 

To this I am desirous of pleading guilty. I now feel but little 
doubt that these districts are merely subordinate to the clay 
slates. Want of experience, at the time I examined them, led 
me to suppose (from the marked difference of external character) 
that they might belong to a separate formation. 

6. The correctzon of the line of boundary assigned by Dr. B. 
to the mountain limestone, or I should rather say boundaries, for 


* JT may refer more particularly to the Professor’s remarks in p. 125, but shall con- 
tent myself with a few extracts from pp. 139, 140, and 141, as they happen to be 
directly applicable to the case in point, 

“« The rocks hitherto described in this section are considered by Dr. Berget as belong~ 
ing to the greywacke formation; which, according to that author, extends, almost 
without interruption, on both sides of the centtal chain. To prevent any ambiguity, he 
first defines greywacke, &c. and he then divides the formation into,common greywacke 
and greywacke slate. He afterwards adds, that in Cornwall, common greywacke is 
always found higher than greywacke slate, &c.—that it rests immediately upon the 
granite—that it is much less rich in ores than greywacke slate, &c. He then states— 
that the greywacke slate becomes more perfectly schistose as it is farther remoyed from 
the granite—that its base is fine, smooth, and nearly homogeneous—that it sometimes 
possesses the lustre of satin—that it isto this second variety exclusively that the Cornish 
miners give the name of killas, &c. 

“© We cannot help considering the whole of this account as inadequate, and in a great 
measure inapplicable. No one term is sufficient to characterize the various beds of 
this formation, &c. If we assume with Dr. Berger, that common greywacke rests 
immediately on the granite; still i¢ is not trwe that it is always found higher than the 
greywacke slate, &c. Again, if the common greywacke be much less rich in ores than 
the greywacke slate, then the part of the killas which rests immediately on the granite 
must be much less metalliferous than some other parts of the formation, and more 
remote from the fundamental rock. As a general observation, we believe this to be 
untrue, &c. But this is not all; we will venture to assert that the rock in immediate 
contact with the granite (at least in every instance in’ which we have ourselves examined 
it) bears xo resemblance whatever to common greywacke. With equal impropriety we 
Conceive the term greywacke slate applied to all the finer schistose beds, of silvery 
lustre, which abound so much in this formation: because, &c. Lastly, it is not true, 
ge is, porn miners apply the term killas exclusively to these finer schistose beds, 

c. &e. 


1824} Prof: Henslow's Reply to Dr. Bereer. 409 


there are two distinct localities for this formation in my account, 
though Dr. Berger has united them in one continuous tract on 
his map. 

7. The limitation of the old red sandstone to its true extension, 
the western shore of Langness Point, instead of extending it (as 
Dr. B. had done) over the whole of that isthmus. 

8. The having mistaken him, in stating the whole space 
between Scarlet and Poolvash to be occupied by a bed of amyg- 
daloidal trap. 

My mistake then amounts to this, that I had supposed Dr. B. 
to have been more accurate in his observations than he now 
allows himself to have been ; tor he mentions only the extreme 
points of a tract which is in fact wholly composed of trap rocks, 
although not of the peculiar variety he alludes to. A juster 
cause for observation might have been found in our difference of 
opinion with respect to the position of this trap, which he states 
to exist as an overlying mass, but which I am bold enough to 
contradict, because I think the evidence is clearly in favour of 
its intruding from below. 

9. The assertion that the term Curragh is sometimes applied 
to mountain peat-bogs, and does not exclusively belong to the 
flat district towards the north of the island. 

N. B. Although Dr. B. is pleased to ridicule the idea of cor- 
recting a marked geographical error in a geological map, we find 
him expatiating with complacency upon the utility of his obser- 
vations with regard to husbandry. 

10. The mention of the discovery of anumber of elks’ bones, and 
earthy phosphate of iron, in the marl, near Kirk-Balaff. 

Dr. Berger insinuates that I consider this circumstance as 
extraordinary. Upon a careful perusal of the passage, I cannot 
perceive the slightest evidence of any such intimation. The 
number of bones imbedded in the small extent of the marl is 
somewhat extraordinary, and the fact of an entire skeleton being 
discovered was new. That the circumstance itself was not of a 
novel description I was perfectly aware, and introduced the 
subject by stating, that here “are found the remains of the 
gigantic elk.” 

11. The want of “ clear-sightedness” in not being able to 
comprehend the latent meaning of the following sentence ; 
“ Some go so far as to say, that the increase is no less than two 
yards in a year.” Dr. B. assures us that this sentence evidently 
2 eh that he discredited the information it apparently conveys. 

shall now conclude by observing that Dr. Berger’s “ Reply” 
to my “ prolix and inflated criticism,” and the courteous hint, 
that it was dictated by “the malignity of envy,” have caused 
me no other sensation than regret—for the loss of a morning in 
enning these remarks. . 
I have the honour to be, Sir, your obedient servant, 
J, 8. Henstow,. 


410 An Account of the Logan Rock. [JuNE, 


ArTIcLE IV. 
An Account of the Logan Rock. 


[The mischievous displacing of this curious rock, noticed in 
our last, having excited much attention, we have extracted the 
following account of it froma ‘“ Guide to the Mount’s Bay and 
the Land’s End, &c. By a Physician.” The work is generally 
attributed to Dr. Paris.— Edit. | 


We now return to the Land’s End,—from which we should 
proceed to visit a promontory called Castle Treryn, where is 
situated the celebrated Logan Stone. If we pursue our route 
along the cliffs, it will be found to lie several miles south-eas: of 
the Land’s End, although by taking the direct and usual road 
across the country, it is not more than two miles distant ; but 
the geologist must walk, or ride along the coast on horseback, 
and we can assure him that he will be amply recompensed for 
his trouble. 

From the Cape on which the signal station is situated, the 
rock scenery is particularly magnificent, exhibiting an admirable 
specimen of the manner and forms into which granite disinte- 
grates. About forty yards from this Cape is the promontory 
called Tol-Pedn-Penwith, which in the Cornish language signi- 
fies the holed headland in Penwith. The name is derived from 
a singular chasm, known by the appellation of the Funnel Rock ; 
it is a vast perpendicular excavation in the granite, resembling 
in figure an inverted cone, and has been evidently produced by 
the gradual decomposition of one of those vertical veins with 
which this part of the coast is so frequently intersected. By a 
circuitous route you may descend to the bottom of the cavern, 
into which the sea flows at high water. Here the Cornish 
Chough (Corvus Graculus) has built its nest for several years, a 
bird which is very common about the rocky parts of this coast, 
and may be distinguished by its red legs and bill, and the viola- 
ceous blackness of its feathers, This promontory forms the 
western extremity of the Mount’s Bay. The antiquary willdis- 
cover in this spot the vestiges of one of the ancient Cliff Castles, 
which were little else than stone walls, stretching across necks 
of land from cliff to cliff. The only geological phenomenon 
worthy of particular notice is a large and beautiful contempora- 
neous vein of red granite containing shor]; is one foot in width, 
and may be seen for about forty feet in length. 

Continuing our route around the coast we at length arrive at 
Castle Treryn. Its name is derived from the supposition of its 
having been the site of an ancient British fortress, of which there 
are still some obscure traces, although the wild and rugged 
appearance of the rocks indicate nothing like art. 


1824.] An Account of the Logan Rock. 411 


The foundation of the whole is a stupendous group of granite 
rocks, which rise in pyramidal clusters to a prodigious altitude, 
and overhang the sea. On one of those pyramids is situated the 
celebrated Logan Stone, which is an immense block of granite 
weighing above 60tons. The surface in contact with the under 
rock is of very small extent, and the whole mass is so nicely 
balanced, that, notwithstanding its magnitude, the strength of a 
single man applied to its under edge is sufficient to change its 
centre of gravity, and though at first in a degree scarcely percep- 
tible, yet the repetition of such impulses, at each return of the 
stone, produces at length a very sensible oscillation! As soon as 
the astonishment which this phenomenon excites has in some 
measure subsided, the stranger anxiously inquires how, and 
whence the stone originated—was it elevated by human means, 
or was it produced by the agency of natural causes ?—Those who 
are in the habit of viewing mountain masses with geological 
eyes, will readily discover that the only chisel ever employed 
has been the tooth of time—the only artist engaged, the ele- 
ments. Granite usually disintegrates into rhomboidal and 
tabular masses, which by the farther operation of air and moist- 
ure gradually lose their solid angles, and approach the spheroidal 
form. De Luc observed in ‘the Giant mountains of Silesia, 
spheroids of this description so piled upon each other as. to 
resemble Dutch cheeses; and appearances, no less illustrative 
of the phenomenon, may be seen from the signal station to 
which we have just alluded. The fact of the upper part of the 
cliff being more exposed to atmospheric agency, than the parts 
beneath, will sufficiently explain why these rounded masses so 
frequently rest on blocks which still preserve the tabular form ; 


412 An Account of the Logan Rock.  . [Junz, 


and since such spheroidal blocks must obviously rest in that 
position in which their lesser axes are perpendicular to the hori- 
zon, it is equally evident that whenever an adequate force is ap- 
plied they must vibrate on their point of support. 

Although we are thus led to deny the Druidical origin of this 
stone, for which s6 many zealous antiquaries have contended, 
still we by no means intend to deny that the Druids employed it 
as an engine of superstition; it is indeed very probable that, 
having observed so uncommon a property, they dexterously 
contrived to make it answer the aa. 8 of an ordeal, and by 
regarding it as the touchstone of truth, acquitted or condemned 
the accused by its motions. Mason poetically alludes to this 
supposed property in the following lines : 

‘¢ Behold yon huge 
And unknown sphere of living adamant, 
Which, pois’d by magic, rests its central weight 
On yonder pointed rock: firm as it seems, 
Such is its strange, and virtuous property, 
It moves obsequious to the gentlest touch 
Ofhim, whose heart is pure, but to a traitor, 


Tho’ e’en a giant’s prowess nerv’d his arm, 
It stands as fix’d as Snowdon.” 


The rocks are covered with a species of Byssus long and 
rough to the touch, forming a kind of hoary beard ; in many 
places they are deeply furrowed, carrying with them a singular 
air of antiquity, which combines with the whole of the romantic 
scenery to awaken in the minds of the poet and enthusiast the 
recollection of the Druidical ages. The Botanist will observe 
the common Thrift (Statice Armeria) imparting a glowing tinge 
to the scanty vegetation of the spot, and by growing within the 
crevices of the rocks, affording a very picturesque contrast to 
their massive fabric. Here too the Daucus Maritimus, or wild 
carrot; Sedum Telephium, Saxifraga Stellaris, and Asplenium 
Marinum, may be found in abundance. 

The granite in this spot is extremely beautiful, on account of 
its porphyritic appearance ; the crystals of felspar ate numerous 
and distinct ; in some places the rock is traversed by veins of 
red felspar, and of black tourmaline, or schorl, of which the 
crystalline forms of the prisms, on account of their close aggre- 
gation, are very indistinct. Here may also be observed a con- 
temporaneous vein of schorl rock in the granite, nearly two feet 
wide, highly inclined and very short, and not having any distinct 
walls. On the western side of the Logan rock is a cavern, 
formed by the decomposition of a vein of granite, the felspar of 
which assumes a brilliant flesh-red, and lilac colour; and where 
it is polished by the sea, exceeding even in beauty the Serpen- 
tine caverns at thé Lizard. 

Mr. Majendie observed in this spot numerous veins of fitie- 
grained granite; which he is inclined to consider as cotempora- 
neous; he algo observed what, at first sight, appeared to be frag 


a ee i ee ee ee 


RD ce i ed 


1824.] Analysis of the Fulminate of Silver. 413 


ments, but which, upon closer examination, he pronounces to 
be cotemporaneous concretions ; for large crystals of felspar may 
be seen shooting from the porphyritic granite into these apparent 
fragments. These phenomena are extremely interesting ina 
geological point of view, and well deserve the attention of the 
scientific tourist. 


ARTICLE V. 


Analysis of the Fulminate of Silver. By MM. Liebig and 
Gay-Lussac.* 


Tue memoir published by one of us upon fulminating silver 
and mercury, prepared by means of nitric acid and alcohol, was 
principally mtended to show that these compounds are true salts 
formed by peculiar acids which may be separated from them, 
and combined with all other bases. Their analysis, and espe- 
cially those of the acids, opposed too many difficulties to allow 
of the flattermg conclusion, that these were given with accuracy . 
on this first essay; and being both of us persuaded of the possi- 
bility of effecting them with a greater degree of precision, we 
united to make this analysis the subject of fresh researches. 

Fulminate of silyer being very easily prepared, and its insolu- 
bility allowing of its being had perfectly pure, we selected it in 
preference to other fulminates to submit it to experiment. 

The process by which we prepared it differed but little from 
those which have been given; nevertheless it occurred to us 
that it might not be useless to state the manipulations of it. 

Put into a pint matrass 700 grs. of nitric acid, of specific gra- 
vity 1:36, or 1°38, and 54 gts. of pure silver. When the silver 
is dissolved, the solution is to be poured into 1000 grains of 
alcohol of 85 to 87 centisimal degrees. The fluid when heated 
to ebullition soon becomes turbid, and begins to deposit fulmi- 
nate of silver; the matrass is then to be removed from the fire, 
and in order to diminish the ebullition, which still continues, a 
quantity of alcohol equal to that originally employed is to be 
gradually added. When the ebullition has ceased, it is to be 
suffered to cool, the fulminate is to be put upon a filter, and 
washed till it ceases to yield any acid. The fulminate is then 
snow-white and quite pure. ‘The filter is then to be removed, 
and spread upon a plate, and covered with paper 5 it is to be 

laced upon a vessel half filled with water, which is to be kept 
Boiling for two or three hours. The weight offulminate obtained 
is usually equal to that of the silver employed; a third more 


* Annales de Chimie ct de Physique, tome xxv. p. 285. 


414 MM. Liebig and Gay-Lussac on [JuNeE, 


ought to be procured, but this third remains in solution in the 
nitric acid, and in the washings. 

Fulminate of silver does not detonate alone at a temperature 
of 212° Fahr. nor even at 266°; but it must not be exposed to 
the slightest percussion between two hard bodies, even when it 
is in water. Consequently wooden stirrers only should be 
employed, instead of glass ones, and the capsules on which: it is 
put should be placed upon several folds of paper; it is prudent 
also to remove it only with bits of paper; for the detonation of a 
few grains only of this matter occurring on the hand would infal- 
libly occasion its loss. 

We ascertained, by operating upon very small quantities of 
fulminate, that it might be rubbed on a porcelain capsule with a 
cork or the finger, after having mixed it with forty times its 
weight of peroxide of copper, and that it did not detonate when 
exposed to the action of heat ; we employed this method of deter- 
mining what were the proportions of carbon and azote in the 
fulminate of silver. Two decigrammes (grs. 3:0888) of this salt 
mixed with four times its weight of oxide of copper, and heated 
in a glass tube produced a gaseous mixture, the last portions of 
which, after the expulsion of the common air, were composed of 
two parts by volume of carbonic acid gas and one volume of 
azote ; consequently in the fulminate of silver, or rather in the 
fulminic acid, the carbon and the azote are in the same propor- 
tions as in cyanogen. 

Fulminate of silver containing two portions of oxide of silver, 
one of which serves as a base to the salt, and the other appears 
to be a constituent of fulminic acid, we endeavoured to deter- 
mine each with precision. Their total quantity is easily obtained 
by decomposing fulminate of silver by muriatic acid, and evapo- 
ration to dryness ; towards the end of the operation, alittle nitric 
acid is to be added in order to decompose a small quantity of 
muriate of ammonia, which is formed during the evaporation, 
and which is derived from the decomposition of an acid, which 
we shall presently mention. 

2°266 parts of fulminate of silver, thus decomposed, yielded 
2°171 of chloride of silver. Reducing this chloride to oxide of 
silver, 100 of fulminate contain 77°51! of oxide of silver; ina 
second experiment 1:060 of fulminate yielded 1-016 of chloride 
of silver, or 100 of fulminate contain 77°545 of oxide of silver. 

By taking the mean of these two experiments, 100 of fulmi- 
nate of silver contain 77°528 of oxide of silver, or 


Salven ace aid dey< dinwiewa.e » b dini< eid ithen eon dou Oe 
Oxy eh ws sindawd hi sis nnd M ad dome peed 


77°528 


We suppose that all the silver is in the state of oxide, and it 
will be seen that this supposition is extremely probable. 


¥ ere 
Ae ey , Ain 
ay he eee 
G £ y 


1824.] Fulminate of Silver. 415 


When fulminate of silver is put into a solution of potash, oxide 
of silver is separated, and fulminate of potash is formed ; but 
the decomposition is very incomplete ;_oxide of silver continues 
to precipitate during the evaporation of the fluid, even at the 
expiration of some days ; the results obtained are very variable, 
depending upon the quantity cf potash, and unquestionably also 
upon the formation of double compounds. 

One hundred parts of fulminate of silver produced 27:14; 
29°69 and 31°45 of oxide of silver. Being unable to employ 
this method of analysis to determine the quantity of base com- 
bined with the fulminic acid, we had recourse to chloride of 
potassium ; it does not indeed decompose the fulminic acid; it 
precipitates the oxide of silver combined with it in the state of 
chloride, and produces fulminate of potash ; 2°252 parts of fulmi- 
nate of silver thus decomposed by chloride of potassium slightly 
in excess, yielded 1-202 of chloride of silver; estimating this 
quantity of chloride in the state of oxide, 100 of fulminate con- 
tain 38-106 of oxide of silver as a base. 

The fulrinate of potash obtained in this experiment, decom 
posed by muriatic acid, yielded 1:210 of chloride of silver; or 
100 of fulminate contain 38°359 of oxide of silver regarded as a 
constituent of the fulminic acid. These two quantities of oxide 
of silver differ so little from each other that we may conclude 
the fulminate of silver to contain twice as much oxide as is requir- 
ed to saturate the fulminic acid. The total of these two quanti- 
ties of oxide amounts only to 76464, instead of 77-528, which 
ought to have been obtained ; but the conclusion which we have 
drawn from our experiment is not on this account much less 
accurate.* 

Knowing the quantity of oxide contained in the fulminate of 
silver, we endeavoured to determine its other elements, among 
which are, as we already know, carbon and azote. We decom- 
posed the fulminate of silver by oxide of copper; but as it was 
very requisite to dry the matters upon which we had to operate 
perfectly, we shall begin by describing the process by means of 
which we believe that we succeeded in effecting it; especially as 
it is applicable to the analysis of any vegetable or animal sub- 
stance. 

After having mixed the fulminate of silver with the oxide of 
copper, and introduced the mixture into a moderately thick glass 
tube, the external diameter of which was about one-third of an 
inch, and its length nearly twelve inches, a, fig. 1 (Pl. XXVIII), 
it was connected with a tube 6, containing chloride of calcium, 


* The alkaline chlorides possess the property of dissolving a small quantity of chlo- 
ride of silver : this source of error we ayoided in the following manner: we began by 
evaporation nearly to dryness, and poured some nitric acid upon the, residuum: by 
heat, the chloride of potassium was quickly converted into nitrate, while the chloride 
of silver suffered no change, 


416 MM. Liebig and Gay-Lussac on (June; 


which is itself adapted, by means of a flexible lead pipe, c, to a 
small receiver placed upon the plate p of an air-pump. 


On making a vacuum in the apparatus, the air carries with it 
the vapour of water, and re-enters the tube containing the mix- 
ture only when dried by the chloride of calcium. But in order 
still better to separate the hygrometric moisture of the mixture, 
the tube containing it is placed in a tube, d e, of greater diame- 
ter, fitted with a perforated cork, and filled with water which 
may be boiled. The vapour escapes by the tube, f, and the 
water which condenses in it falls into the vessel g. placed below 
it. By alternately filling and exhausting the apparatus, it will 
be granted that the mixture must lose all its hygrometric moist- 
ure. With respect to other substances, the decomposition of 
which there is no reason to fear at a temperature above 212°, 
the tube containing the mixture may be heated in an acid or 
saline solution, or in a bath of oil, The apparatus which has 
been described requires no copper pipe; the joinings are all 
made with cork, and when this substance is of a good quality, 
the apparatus sustains a vacuum perfectly without the use of any 
cement, or, at most, a little isinglass or tallow may be introduced 
into the pores of the cork when it appears to have any, 

The mixture of fulminate of silver and oxide of copper being 
perfectly dried, it is decomposed by the action of heat, and the 
gases resulting from this decomposition are to be received; but 
as by the usual processes, it is difficult to ascertain their real 
volume, we employed the following apparatus which gives it 
immediately. 

This consists of a footed receiver, a 0, fig. 2, into which 
are cemented, one in a, and the other in b, two rings or collars 
of cork, for the purpose of directing the small graduated receiver, 
¢, in its motion, The tube, d, which conducts the gases into the 
graduated receiver, has two vertical and parallel branches, the 
ascending one of which nearly touches the top of the graduated 
receiver when it is in its lowest place, and then passes on the 
ontside of the graduated receiver between the two openings of 
the cork rings. The plan of these rings is represented by tig. 3, 
The footed receiver being filled with mercury, and_ the as- 
cending branch of the conducting tube being placed in the 
graduated receiver, the latter is plunged in mercury, and the air 
escapes gradually by the conducting tube. The receiver is 
fixed in its first position, by supporting it from its summit 
with a cork fixed in a wooden arm, J, moying along a vetr- 
tical stand, 7, upon which it may be stopped at any situation 
byascrew, k. The tube, m, containing the mixture, is then 
adapted to the conducting tube, and the latteris confined in the 
wooden vice of the support, /, the parts of which are made to 
approach by means of a screw, and separate by their own spring. 
The mercury in the graduated receiver is put exactly on a level 


1824.] Fulninate of Silver. 417 


with that which forms the bath, and the volume of air in the gra- 
duated receiver is noted, as well as its temperature. When the 
mixture is decomposed, the gases which are evolved depress the 
mercury in the graduated tube; but by properly shifting the 
wooden arm along its support, the mercury is maintained at 
nearly its original level, it being continually added to fill the 
space which the receiver leaves by rising out of the bath. When 
the decomposition is finished, the fire is removed, and when the 
apparatus is cooled, the mercury is brought to the same level in 
the receiver and in the bath, and the temperature is noted. It is 
evident that the volume of air contained in the graduated 
receiver, after the operation, less than that which existed 
there before it, indicates exactly the volume of the gases which 
result from the decomposition, the corrections for temperature 
and barometric pressure being made; but as the whole of the 
operation continues at most but half an hour, it is seldom requi- 
site to make any corrections. 

The water which is formed during the decomposition of an 
hydrogenous substance by the oxide of copper, is usually col- 
lected by causing it to pass over chloride of calcium contained 
in a tube placed between the conducting tube and that which 
contains the mixture; but the following arrangement, which 
consists in introducing the chloride of calcium into the same tube 
as that in which the decomposition is effected, has appeared to 
us to be preferable. 

We take a very small tube, n, fig. 4, the external diameter of 
which is nearly equal to the internal diameter of the tube, m, 
containing the mixture ; to this a small tube, 0, is attached by 
melting them together, and it is made to pass tightly through 
the tube, m, and after having filled it with chloride of calcium, 
it is drawn to a point at the other end, p, leaving only a small 
aperture. Having noted the weight, it is to be placed in the 
tube, m, as shown by fig. 2; the gases have then no other pas- 
sage for escape but over the chloride of calcium, and they then 
deposit their moisture. When the mixture is introduced into the 
tube, m, care must be taken to leave an empty space, m s, below 
the upper side of the tube, that it may not be projected forward 
by the gases at the moment of their expulsion. Lastly, it has 
been often recommended to use a spirit-lamp to effect the 
decomposition of the mixture; but we find it to be much more 
convenient to place the naked tube upon a grating of iron wire, 
supported by a furnace, the door and ash-hole of which are kept 
shut, and to surround it with red-hot charcoal occasionally added. 
This method also possesses the advantage of enabling us to heat 
the whole of the tube in every part at the same time, and witha 
little practice, it is easily et fe of a dull red heat, without any 
risk of softening it. 

The process of analysis by oxide of copper being very well 

New Series, vo. vii, 25 


418 MM. Liebig and Gay-Lussac on (June, 


known, we shall limit ourselves to the relation of the results 
which we obtained, without going into further details. 

We usually experimented upon three decigrammes (4°6332 
grains) of fulminate of silver, and considering the carbon and 
azote disengaged as existing in the state of cyanogen, five suc- 
cessive experiments gave us: 


Fulminate of silver 100; cyanogen 17-379 
17515 
16-921 
16-869 
17°314 


Mean 17-160 


In the first experiment no trace of water was perceptible ; in 
the second (0616 of a grain; in the third 0°0154 grain, in the 
fourth 0°1848 grain, and in the fifth 00308 of a grain was 
obtained. 

Although in these several experiments, except in the fourth, 
the quantity of water is not considerable, we did not consider 


it as accidental until after we had ascertained in several , 


ways that its quantity was never sufficient to allow hydrogen 
to be considered as one of the elements of fulminate of silver. 
We generally operated upon three decigrammes (4°6532 grains) 
of fulminate, and supposing the hydrogen which it contains to be 
in sufficient quantity to form hydrocyanic acid with the cyano- 
gen, this quantity ought to have yielded 0:2710 grain of water, 
which certainly could not have escaped our notice. 

We shall presently adduce other proofs of the absence of 
hydrogen on the fulminates, and in the mean time, we conclude 
that this compound is formed of 


Oxygen . a oho's o'elale We 6 plate oie Cae 
Gyanogen: ikea ieds HUT onsale be hag 
BAB isiis Ss Brabus od eis ae AE EN ag Oe 

100-000 


The quantity 6°312 is evidently equal to the quantity of oxygen 
combined with the silver ; it cannot be attributed to the hydro- 
gen, which, supposing there had been any combined with the 
cyanogen to form hydrocyanic acid, would amount only to 0:651; 
nor can this loss be attributed to water, for we have never found 
a quantity nearly equal to it ; consequently it can be attributed 
only to oxygen contained in the fulminic acid. According to 
this supposition, which will be hereafter verified, fulminate of 
silver consists of 


1824.] Fulminate of Silver. 419 


Two atoms of silver, 

Two atoms of oxygen combined with the silver, 

Two atoms of oxygen combined with the elements of the 
fulminic acid. 
atoms of azote, 
atoms of carbon. 


It evidently follows from this analysis, that fulminate of silver 

does not contain sufficient oxygen to convert its carbon into 
_earbonic acid. The examination of the residuum left by the 
fulminate of silver after decomposition by oxide of copper, in 
which copper is found in its metallic state, gives an incontro- 
vertible proof of this ; but it would not be easy to determine by 
this method the quantity of oxygen really deficient. 

It would have been important to have ascertained the products 
of the immediate detonation of the fulminate of silver; and we 
did not fail to make some experiments with this intention ; but 
we were compelled to abandon it on account of the fracture of 
the vessels, which took place with a very small quantity of fulmi- 
nate, and by the danger inseparable from experiments of this 
kind. On the other hand, it appeared very easy to determine 
the products of the decomposition of the fulminate of silver by 
heat, after having mixed it with substances incapable of supply- 
ing it with oxygen: that which at first appeared preferable to us 
was glass reduced to an impalpable powder; but every time that 
we endeavoured to mix it with the fulminate, detonation took 
place, and prudence compelled us to give up this method. 

By employing chloride of potassium instead of glass, the 
mixture may be rubbed by the finger, or with a cork, without 
danger, after having mixed it as intimately as possible with a 
small slip of card. 

A portion of fulminate of silver weighing 6°131 grains (0°397 
gramme), decomposed by this process, produced 11-929 cubic 
inches of gas; with oxide of copper, this same quantity of fulmi- 
nate would have given 36°81 cubic inches. The i1°929 cubic 
inches of gas contained no oxide of carbon, and were composed 
merely of azote and carbonic acid. Now, according to this 
composition, if all the oxygen of the fulminate had been employed 
to form carbonic acid, and the azote had been disengaged with it, 
and recollecting that in the complete combustion of the fulminate 
by oxide of copper, the azote constitutes one-third of the whole 
volume, and the carbonic acid two-thirds, there should have been 
obtained 


Two atoms of cyanogen = {4 


Bzte = + Of SO'OL, = we cier ses. ee eee 
Carbonic acid = } of 36°81*. ...... 12°27 
24:54 


_ * We say one-third of 36-31, because, in our experiment, only one-half the quan- 
tity of carbonic acid could be formed that would result from the complete combustion of 
the carbon, 

252 


420 MM. Liebig and Gay-Lussac on [Junt, 


There being so great a difference between the results of calcu- 
lation and experiment, we determined to examine the residuum of 
the distillation, which was of a blackish-grey colour. We found 
by treating a portion of it with water, that it was very alkaline, and 
that which was not dissolved contained much chloride of silver. 
Thus by the agency of the silver, and the oxygen contained in 
the fulminate, a part of the chloride of potassium was decom- 
posed, and converted into potash and chloride of silver, and the 
former was combined with carbonic acid: this circumstance 
explains sufficiently why so small a volume of gas was obtained. 

During the decomposition of the fulminate of silver mixed 
with the chloride of potassium, a small quantity of carbonate of 
ammonia was obtained, which was collected in one part of the 
tube by surrounding it with a piece of paper moistened occa- 
sionally with ether to cool it. For the purpose of determining 
the quantity of carbonic acid combined with the ammonia, we 
passed up a tube over mercury some muriatic acid, and a small 
fragment of marble insufficient to neutralize it. We agitated it 
thoroughly, in order to favour the solution of the carbonic acid 
gas in the muriatic acid, and some time after we introduced into 
the solution the portion of the tube upon which the carbonate of 
ammonia had condensed ; effervescence was very perceptible ; 
but the gas disengaged was not equal to 0°09 of a cubic inch ; 
consequently the quantity of ammonia contained in the carbonate 
could not amount to 0°18 ofa cubic inch. 

The residuum of the decomposition of the fulminate of silver 
necessarily containing some carbon, it was distilled with oxide 
of copper; 17-874 cubic inches of gas were obtained, which, 
added to the 1]:929 before procured, give a total of about 29:8 
cubic inches; the difference between this quantity and 36°81 
which ought to have been obtained, is still very great; but the 
potash formed, necessarily retained a portion of carbonic acid, and 
on other accounts this experiment was not sufficiently correct. 

The chloride of potassium not having answered our purpose, 
we employed sulphate of potash, calcined and reduced to a very 
fine pewder, that it might be rubbed with fulminate of silver 
without danger. 5°32 grains of fulminate mixed with about 
twenty times as much sulphate of potash, and dried in a vacuum, 
yielded by distillation 14°68 cubic inches of gas; the same 
quantity of fulminate distilled with oxide of copper would have 
given 32:04 cubic inches. The residuum heated with oxide of 
copper afterwards gave 14-96 cubic inches of gas; but we 
remarked that it was rather red, and’ that consequently nitrous 
acid was formed: this happened unquestionably, because, in 
order that the bulk of the mixture might not be too great, too 
small a proportion of oxide of copper had been used. There was 
also produced a small quantity of carbonate of ammonia, which 
appeared to us to be smaller than that obtained in the preceding 
experiment, and no trace of water was perceptible, which seems 


4 
’ 
r 
. 
4 
} 
E 
q 


1824,] Fulminate of Silver. 421 


to prove that the formation of one of these compounds prevented 
that of the other. Now, supposing that all the hydrogen com- 
bined with the cyanogen in the fulminate of silver was combined 
with the azote to form ammonia, a very appreciable quantity of 
carbonate of ammonia ought to be obtained. 

Indeed the 5°32 grains of fulminate decomposed by oxide of 
copper ought to yield 32:04 cubic inches of gas, composed of 
two-thirds of carbonic acid and one-third of azote. And as 
there is in hydrocyanic acid as much hydrogen in volume as of 


azote, 32°04 cubic inches represent = = 10°68 of hydrogen 


gas, which, combined with their third of azote, ought to produce 
TOs + 390 = 7-12 of ammoniacal gas: this quantity would 
absorb 3°56 of carbonic acid gas to form carbonate of ammonia, 
and the total diminution which would result from the disappear- 
ance of carbonic acid gas and that of azote, would be equal to 
7°12 cubic inches. In our experiment, notwithstanding the 
formation of nitrous acid, we obtained 29-64 cubic inches, the 
difference between which and 32:04 is very far from being equal 
to that which ought to be obtained, if all the supposed hydrogen 
had been taken up to form ammonia. The hypothesis that a por- 
tion would produce water cannot be admitted ; for, as we have 
already remarked, when carbonate of ammonia is formed, not 
the slightest trace of moisture is perceptible ; and further, we 
have proved by direct experiment, that by moistening the ful- 
minate of silver, much carbonate of ammonia is obtained. 

Thus the decomposition of fulminate of silver mixed with sul- 
phate of potash furnishes us with additional proof that it does 
not contain hydrogen as one of its elements. The fulminate of 
silver in the preceding experiment having given two portions of 
gas, one with sulphate of potash, and the other with oxide of 
aes it was important to ascertain the nature of each of them. 

e made a fresh experiment directed solely to this end; but 
being desirous of obtaining the first portions evolved without 
any admixture of atmospheric air, we endeavoured to form a 
vacuum 1n our apparatus. 

To the tube containing the mixture, we adapted a copper tube, 
c, fig. 5, connected with a glass tube, d, nearly 40 inches long, 
and immersed it in a basin of mercury, m, in order to collect the 
gases. From the middle of the copper tube, another, c, projects 
at a right angle, furnished with a cock, and communicating with 
the air-pump by means of a leaden pipe, 7. On making a vacuum 
in the apparatus, the mercury cannot pass the height, /, equal 
to about thirty inches, and by then turning the cock, all commu- 
nication between the apparatus and the air-pump is shut off. 

In employing this apparatus, we found that the gas evolved 
during the distillation of the fulminate of silver with the sulphate 
of potash, is composed of two volumes of carbonic acid gas and 


422 MM. Liebig and Gay-Lussac on [JuNE, 


one of azote, and that obtained in distilling the residuum with 
oxide of copper consists of 100 volumes of the first gas and 37°4 
of the second. 

Although this result is not in perfect agreement with. the first, 
and although the experiments which we detail have not all the 
accuracy we could wish, it appears to us nevertheless probable, 
that in the decomposition of the fulminate of silver mixed with 
the sulphate of potash, only half of the carbon is converted into 
carbonic acid; that a quantity of azote is evolved which corre- 
sponds exactly with what ought to happen if the azote and the 
carbon were in the fulminate in the state of cyanogen, and that 
consequently the silver in the residuum exists in the state of 
subcyanuret. 

If the elements, which analysis has made us acquainted with, 
in the fulminate of silver are the true ones, it is easy to obtain 
the true equivalent number of fulminic acid; for admitting that 
the oxide of silver which acts as a base in the fulminic acid is 

5 
exactly half that contained in the fulminate, we have " = = 
38'764 : 61236 :: 145:161 (oxide of silver) : 229°31 : now, 
by calculation, fulminic acid will be composed of 


1 atom of oxide of silver. ........ 145°161 


2 atoms of cyanogen. ...... eseeee 65°584 
2 atoms of OXYGEN. ..seeeeeeeeeee 20°000 
230°745 


In order to verify this result, we prepared fulminate of barytes 
by decomposing fulminate of silver with chloride of barium, 
and after having dried it at the temperature of 212°, we treated 
it with muriatic acid, which formed chloride of barium and 
chloride of silver : 38°33 of fulminate of barytes produced 15:85 
of chloride of barium, and from this the equivalent number of 
fulminic acid is readily deduced, and is 228:873. The agree- 
ment between these three results is as near as can be expected 
in experiments, the danger attending which does not allow of 
their repetition, and we shall admit 230°745 as the equivalent 
number of fulminic acid, which is the result of calculation. 

Being now acquainted with the nature of the elements of ful- 
minate of silver, we shall direct our attention to the manner in 
which they are combined. 

If silver be an essential principle of fulminic acid, we must 
necessarily admit the existence of almost as many peculiar acids 
as there are metals ; for the greater part may replace silver, and 
form each a fulminic acid. With zinc alone for instance, a ful- 
minate is produced which is perfectly analogous to that of 
silver ; hut is it probable that bodies, the properties of which are 
so different, should replace each other in the same atomic pro- 
portion, and form, with cyanogen and oxygen, acids which are 


a 


eS ee 


| 


1824.] Fulminate of Silver. | 423 


perfectly similar? or is it not, on the contrary, more probable 
that the various fulminic acids are real supersalts, the acid of 
which does not contain any metal as one of its elements, and 
which is formed only of oxygen and cyanogen? It must be con- 
fessed that our experiments render this opinion extremely pro- 
bable; but the following considerations give it additional 
certainty. : 

As fulminates may be obtained without silver or mercury, 
with oxides which yield oxygen with difficulty, as, for example, 
the oxide of zinc, it necessarily follows that the various fulmi- 
nates contain a common principle of fulmination, which is inde- 
pendent of their bases, and which can be only a compound of 
oxygen and cyanogen, or, if it be preferred, a compound of oxy- 
gen, carbon, and azote. 

In addition to this, if we compare the fulminates with the 
neutral tartrates, and the various fulminic acids to the several 
bitartrates, perfect analogies exist between them. Thus aneutral 
tartrate of zinc, copper, silver, or mercury, &c. is only partially 
decomposed by potash, in the same manner as the fulminates of 
these bases; all the fulminic acids form double salts with bases 
like the bitartrates ; fulminic acid with silver as a base is preci- 
pitated by acids on account of its insolubility in the same circum- 
stances as cream of tartar; and there are many fulminates, like 
the neutral tartrates, in which acids produce no precipitate, 
because the corresponding acidulous fulminates or tartrates are 
soluble ; such are the fulminates and tartrates of zinc and cop- 
per. Lastly, the fulminates have great analogy with the hypo- 
sulphites. 

According to these analogies, it appears to us extremely 
probable, not to say certain, that the several fulminates form 
a particular kind of salts, all containing the same acid, composed 
only of an atom of cyanogen and an atom of oxygen, and which 
is unquestionably cyanic acid. The neutral fulminates would 
be cyanates, the various fulminic acids becyanales, and the equi- 
valent number of cyanic acid would be 42°792, that of oxygen 
being equal to 10. Nevertheless in proposing the name of 
cyame acid, which appears to express the nature of the fulminat- 
ing principle common to all the fulminates, we request, before 
it is adopted, that our results should be verified by chemists ; 
and on this account, we shall continue to employ, with the new 
acceptation determined by our experiments, the names of fudmi- 
nic acid and fulminates, which not indicating the nature of the 
compounds to which they are applied, will have the provisional 
advantage of not inducing any error. 

In recollecting the property of the amer described by Welter, 
of forming detonating salts with bases, we could not avoid look- 
ing for some analogy between this compound and the acid of the 
fulminates, although, on other accounts, we were fully persuaded 
that their nature is not similar. The analysis of the salts formed 


424 MM. Liebig and Gay-Lussac on (June, 


with amer was the only means of clearing up this subject; but 
having been able to give but little time to the preparation of 
this substance, and not having succeeded in attaining a quantity 
sufficiently pure, we have been compelled to defer this analysis 
to a future period. 

The nature of the fulminates appearing to be determined, we 
made some attempts to separate the fulminic acid from them; 
but they were all unsuccessful: for either the fulminates are not 
decomposed by the acids, or, when they are, the fulminic acid 
is so also, and yields peculiar products, respecting which we are 
going to offer some observations, although they are incomplete. 

The muriatic, hydriodic, and hydrosulphuric acid, decompose 
fulminate of silver, even when cold ; with muriatic acid much 
hydrocyanic acid is evolved, but neither ammonia nor carbonic 
acid is perceptible. A peculiar acid containing chlorine, car- 
bon, and azote, is formed, which is easily obtained by pouring a 
little muriatic acid upon fulminate of silver, until the filtered 
fluid is no longer rendered turbid by the acid. It possesses the 
following properties : 

Its taste is sharp ; it reddens litmus paper strongly ; it does 
not precipitate nitrate of silver; neutralizes bases; and then 
possesses the property of colouring the perchloride of iron of 
a deep red colour; it acquires it also after some hours’ ex- 
posure to the air, because a portion of it is decomposed which 
produces ammonia that saturates the other part; heat accele- 
rates this decomposition. When combined with potash and 
evaporated to dryness, ammonia is obtained, and the residuum 
effervesces with acids, and precipitates nitrate of silver. 20°70 
parts of fulminate of silver, accurately decomposed by muriatic 
acid, yielded 19-84 of chloride of silver, which were separated 
from the filter by means of ammonia. 

The new acid being mixed with hydrocyanic acid, which, as 
is well known, precipitates nitrate of silver, we employed the 
following process to determine the quantity of chlorine which it 
contains. We added to the acid potash in excess, and towards 
the end of the evaporation, carried on in a platina crucible, we 
added nitre, and made it red-hot, to decompose the cyanogen ; 
we afterwards saturated the pure alkali, and precipitated by 
nitrate of silver. The weight of the chloride of silver obtained 
amounted to 48:20 parts, which is almost two and a half times 
greater than the weight of the chloride obtained by decomposing 
the fulminate by muriatic acid. In another experiment, the 
two quantities of chloride of silver were in the proportion of 
17°62 to 44:25, which are also those of 1 to 2°5. 

If these results are correct, it cannot be admitted that all the 
chlorine exists free from hydrogen in the new acid ; forthe ful- 
minate of silver, containing only 4 proportions of oxygen and 2 
of cyanogen, could only take the hydrogen of 6 proportions of 
muriatic acid, supposing that all the cyanogen was changed inte 


1824.] Fulminate of Silver. 425 


hydrocyanic acid. A portion of it must, therefore, remain in the 
new acid, and 7 proportions of chloride of silver are obtained : 
it is evident, therefore, that a part of the chlorine is combined 
with hydrogen in the new acid. 

For the purpose of obtaining some information in this respect, 
we attempted to ascertain the quantity of hydrocyanic acid 
which is evolved when fulminate of silver is treated with muriatic 
acid. 

A known weight of fulminate of silver was put into a three- 
necked bottle, fig. 6, with water placed in a salt-water bath, and 
afterwards muriatic acid was poured through the tube, f, upon 
the fulminate. In order to facilitate the volatilization of the 
hydrocyanic acid, a current of hydrogen gas was passed into the 
fluid, from a bottle, a, containing a mixture of zinc and sulphuric 
acid. The hydrogen gas passed through a tube, d, containing 
fragments of marble with a little water, and afterwards escaped 
through a solution of nitrate of silver contained in the receiver, e. 
We were in hope of obtaining cyanuret of silver; but to our 
great surprise no precipitation took place, although we were 
certain that the same solution of silver gave an abundant preci- 
pitate when hydrocyanic acid was poured into it. 

Hydriodic acid acts upon fulminate of silver in the same way 
as muriatic acid. Hydrocyanic acid is disengaged, and a pecu- 
liar acid is formed which contains iodine, and possesses the pro- 
perty of precipitating perchloride of iron immediately of a deep- 
red colour. 

When a current of sulphuretted hydrogen gas is passed 
through water containing suspended fulminate of silver, the 
fulminate is also decomposed ; sulphuret of silver and a peculiar 
acid are obtained, of which sulphur is one of the elements, but 
no smell of hydrocyanic acid is perceptible. 

This new acid has a sweetish taste; it immediately colours 
perchloride of iron of a deep-red colour; the solution may be 
evaporated, and concentrated without decomposition. Com- 
bined with potash and evaporated to ‘dryness, it suffers no 
alteration. | 

22:68 of fulminate of silver, treated with sulphuretted hydro- 
gen, produced sulphuret of silver, which, treated with nitric 
acid, and afterwards with muriatic, gave 21:73 of chloride of 
silver. 

The new acid, saturated with potash, evaporated and heated 
to redness in a capsule of platina with nitve, saturated and pre- 
cipitated by chloride of barium, produced 18:60 of sulphate of 
barytes, representing 22-89 of chloride of silver. These two 

uantities of chloride, not being very different, seem to admit of 
the conclusion, that in fulminic acid, the sulphur exactly 
replaces the oxygen atom for atom; but a second experiment 
tay by sulphate of barytes a rather smaller proportion than 
the first. 


426 Analysis of Fulminate of Silver. [JuNE, 
Flugicaeid does not act upon the fulminate of silver; the 
cause of this is not to be found in the solubility of fluoride of 
silver, for fulminate of copper is perfectly decomposed by muria- 
tic acid. This fact appears to us important in the hitherto 
somewhat problematical history of fluoric acid. 
The three peculiar acids of which we have spoken as colouring 


the perchloride of iron of a deep-red colour, must possess a. 


common principle as the cause of this property. It is worthy of 
remark, that the slightly fulminating amer, several properties of 
which have been detailed by M. Chevreul, and the sulpho-cyanic 
acid of M. Porret, give the same red colour to perchloride of 
iron. 

Oxalic acid decomposes fulminate of copper and of silver; 
hydrocyanic acid and ammonia are produced ; no effervescence 
is perceptible, which seems to prove that no carbonic acid is 
formed. Sulphuric acid gives similar results. 

We may remark, with respect to the preparation of the alkaline 
fulminates, that fulminic acid having the property of forming 
very variable double salts, it is preferable in obtaining the 
double fulminate of silver and potash, for example, to decompose 
the fulminate of silver by chloride of potassium. It may be 
immediately obtained in a state of purity, by employing only 
exactly the quantity of chloride sufficient to precipitate half 
the silver combined with the fulminic acid, or rather a little 
less, since the fulminate of silver which is undecomposed, 
being but little soluble, would remain with the chloride of silver. 
Nevertheless the limit of the total decomposition of the fulmi- 
nate of silver may easily be ascertained by using heat, because 
the fulminate being thenslightly soluble, a precipitate is obtained, 
if any remain undecomposed, by adding a little of the chloride. 
We repeat that all the fulminates, single or double, detonate 
with great facility, even in water, and that glass stirrers should 
not be used to agitate any fluid, which contains them in a state 
of mixture. We accidentally detonated, by this method, fulmi- 
nate of silver and barytes in a porcelain capsule ; the accident 
fortunately produced no ill effects, because the greater part of 
the fulminate was suspended in the liquid, and it was scarcely 
warm; but without this union of circumstances, the conse- 
quences would have been terrible. 


— 2. oe fe 


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| 


Bae ety a See 


Sele x 


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1824.] Analyses of Chrysoberyls from Haddam and Brazil. 427 


AnxricLe VI. 


Analyses of the Chrysoberyls from Haddam and Brazil. By Mr. 
H. Seybert.* 


In the summer of 1823, I visited Haddam, in the State of 
Connecticut. Among the various substances there collected 
was the Chrysoberyl, a mineral much esteemed en account of 
its rarity. It occurs disseminated in a coarse grained granite, 
in which the predominant ingredient is a white feldspar, which 
Prof. Berzelius regards as A/bite, perfectly resembling that of 
Finbo. In the same granite this celebrated chemist observed 
the Columbite.; It is also associated with greyish quartz, man- 
ganesian garnet of a fine blood red colour, and a yellow granu- 
lar substance, which some mineralogists supposed to be a variety 
of the cymophane ; but from its inferior hardness and general 
chemical composition, I recognised it to be common beryl. 

For the earliest chemical information concerning the chryso- 
beryl, we are indebted to Prof. Klaproth. He. published his 
analysis of it in 1795,{ and gave the following constituents of it, 
viz. alumina, 71°50; lime, 6; oxide of iron, 1°50; silica, 18; 
loss, 3. Berzelius presented us with a formula founded on this 
composition ; § but from his experiments with the blowpipe he 
was led to conclude that it contained no lime, and that it was a 
subsilicate of alumina.||_ Jn this he was apparently confirmed by 
Prof. Thomson,** who quotes Klaproth’s analysis, and states that 
he examined the mineral some years ago, but having accidentally 
lost his results, he was unable to publish them. He observes, 
however, that the only constituents he found were alumina, 
silica, and oxide of iron. When I was about to prepare the 
communication which I now have the honour to lay before the 
Society, a more recent analysis of the chrysoberyl of Brazil, by 
M. Augustus Arfwedson, was observed, by me, in Tilloch’s 
Philosophical Magazine.{+ He confirmed the results of Prof. 
Thomson, and considered the chemical composition of this sub- 
stance to be—silica, 18°73; and alumina, 81°43, with a trace of 
oxide of iron. 

The cymophane, from Haddam, was sent to M. Hauy by the 
late Dr. Bruce, in 1810, to have his opinion concerning its 


* Extracted from the second volume, New Series, of the Transactions of the Ameri- 
can Philosophical Society, Philadelphia. 
+ Essai de Emploi du Chalumeau, p. 243. 
t Beitrage, vol.i. p. 97. 
§ Systeme de Mineralogie, p. 219,—C 4S + 18 A4S. 
|| Essai de ?Emploi du Chalumeau, p. 325. 
** Thomson’s Cheinistry, vol. iii. p. 213. 
++ No. for November, 1823, p. 357. 


428 Mr. Seybert’s Analyses of the (June, 


nature.* Previous to that period, the mineralogists in the 
United States supposed it to be Corundum. The late celebrated 
crystallographer observes, “La cymophane des Etats Unis a 
d’abord eté prisé pour une varieté de corindon. Effectivement 
elle se rapproche de ce mineral par sa dureté, par sa pesanteur 
spécifique, et méme par le resultat de son analyse, qui a donné 
environ 72 parties d’alumine sur 100, avec 18 de silice, et 6 de 
chaux.”+ L was anxious to examine the cymophane found at 
Haddam, especially as M. Hauy does not name the author of 
the analysis he quotes. The specimen used for my experiments 
was of a pale green colour. It did not present any of the 
chatoyant appearance so remarkable in the variety from Brazil, 
and some specimens from Saratoga in New York, where it was 
lately discovered by Dr. Steel. Its specific gravity, by two 
trials, was 3°508 and 3°597. It is not magnetic, and before the 
blowpipe it is infusible. For a further description of the physical 
characters of this mineral, I refer to Hauy and Cleaveland. 
Three grammes of the mineral were examined under the 
impression that Prof. Klaproth’s analysis was accurately made. 
It was decomposed in the usual manner with four parts of caustic 
potash, and subsequently treated with diluted muriatic acid ; 
but the solution was imperfect. The insoluble matter was col- 
lected on a filter, and it amounted to 25 or 30 per 100. It was 
repeatedly acted on in the same way, and each time it dimi- 
nished in quantity, until the fourth experiment. It then weighed 
about fifteen-hundredths, and thereafter resisted all further 
efforts to render it soluble by these means. This residue was 
then boiled in concentrated sulphuric and muriatic acids, but 
neither of them dissolved more than one-third of it. These 
solutions were tested by different reagents, and greatly to my 
surprise, the addition of subcarbonate of ammonia occasioned a 
floculent precipitate, which entirely redissolved in an excess of 
the alkaline subcarbonate. [ immediately suspected the pre- 
sence of glucina, but was much ata loss to explain its insolubi- 
lity, until I observed Berzelius’s analysis of the euclase,{ in 
which he met with a compound of glucina and oxide of tin that 
obstinately resisted acids. He also met with refractory combi- 
nations of this earth and the oxides of manganese and cerium. 
I next endeavoured to dissolve the compound by the acid sul- 
phate of potash; but this method did not succeed. I was not 
more successful with the nitric and nitromuriatic acids; nor 
could it be dissolved by means of boric acid. Berzelius having 
discovered columbium in the gangue of the cymophane from 
Haddam, the insoluble residue was tested for the oxide of that 
metal, but all my attempts were fruitless. At length, I sup- 


* Annales du Museum d’Histoire Naturelle, tome xviii. p. 57. 
+ Traité de Mineralogie, second edition, vol. ii. p, 309. 
$ Nouveau Systeme de Mineralogie, p. 239. 


1824.] Chrysoberyls from Haddam and Brazil. 429 


posed, that as barytes could be brought into contact with this 
substance more conveniently than potash at a high temperature, 
it might decompose it. With this view, a portion of the inso- 
luble matter was exposed toa strong heat, during one hour, with 
six parts of nitrate of barytes in a platina crucible. The calcined 
mass was boiled in nitric acid. In this way nearly two-thirds of 
the matter that could not be entirely attacked in any other way, 
were dissolved. The same treatment was repeated, until nearly 
the whole of it was taken up, which happened after the fourth 
€alcination. It was then no further acted on. 

After making numerous experiments on the matter that 
resisted nitrate of barytes and nitric acid, I ascertained that it 
was not acted on by alkalies nor acids when used separately, 
but after having been previously calcined with caustic potash, 
it readily dissolved in muriatic acid, yielding a solution ofa pale- 

ellow colour, which gave a reddish precipitate with an infusion 
of galls, a deep-green precipitate with the hydrosulphate of 
potash, and a white precipitate with alkalies. Hence it was 
oxide of titanium. 

After the barytes was separated with sulphuric acid, the nitric 
solutions were united, and treated with an excess of subcarbonate 
of ammonia. An abundant precipitate ensued, which entirely 
redissolved in the excess of subcarbonate. By ebullition it was 
again precipitated ; and when calcined, it was in the form ofa 
light white powder, possessing all the properties that characte- 
rise glucina. With the sulphuric and muriatic acids it formed 
very sweet astringent deliquescent salts. By caustic potash it 
was precipitated from its solutions, and the precipitate redis- 
solved in the excess of the alkali. Klaproth and Arfwedson, in 
their analyses of the chrysoberyl from Brazil, considered the 
insoluble matter remaining, after they had treated the mineral 
with potash and muriatic acid, to be silica. This will explain 
why their results differ so essentially from mine. 

After having thus satisfied myself of the composition of the 
residue above-mentioned, I resumed my preliminary experi- 
ments, and proceeded to examine the muriatic solution obtained 
from the treatment of the mineral with potash and muriatic acid. 
From this solution some silica was separated. A portion of the 
liquid was treated with caustic ammonia, and then tested for 
lime with oxalate of potash, but none of it could be detected. 
To the remaining liquor a considerable excess of subcarbonate 
of ammonia was added, and the precipitated matter was digested 
twenty-four hours. It was then separated by filtration, and the 
fluid was boiled till all the ammonia was expelled. No glucina 
was thus precipitated. Hence we conclude that the very small 
portion of titanium above-mentioned, rendered the whole of the 
glucina so refractory. ‘The alumina precipitated by the sub- 
carbonate of ammonia was mixed with a small quantity of oxide 
of iron. It was soluble in caustic potash, and with this alkali 


430 Mr. Seybert’s Analyses of the [JuNE, 


and sulphuric acid it gave regular octohedral crystals of alum. 
The liquor, when tested with phosphate of soda and ammonia, 
was found to contain ho magnesia. 

After the preliminary experiments, | commenced the following 


Analysis of the Chrysoberyl from Haddam. 


A. Five grammes of the mineral, reduced to small fragments 
in an iron mortar, were carefully porphyrised in one of agate, 
from which it acquired the additional weight of 0-13 grammes, 
The 5°13 grammes were then exposed to a red heat, and thereby 
suffered a diminution of 0:40 per 100. 

B. The calcined mineral (A) was heated, during one hour, in 
the silver crucible, with caustic potash, and the product was 
treated with diluted muriatic acid; the solution was of a lemon- 
yellow colour. There remained a white insoluble residue, 
which after calcination weighed 1:47 grammes. It was repeat- 
edly calcined with caustic potash, and treated with diluted 
muriatic acid, with the following results : | 


After the 2d experiment, it weighed 0:97 grammes. 
3d 0:89 
4th 0°85 


By the fifth treatment it was not diminished, and then pre- 
sented itself in the form of a light white powder, resembling 
pure silica in appearance. 

C. The residue (B) was repeatedly strongly calcined with six 
parts of nitrate of barytes, and subsequently boiled with nitric 
acid. 


* After the Ist treatment, there remained 0-43 grammes. 
2d 0-15 
3d 0:06 
And by the 4th operation only 0:01 gramme was dissolved. 


The remaining 0:05 gramme was essayed in the manner 
related in the preliminary experiments, and thus proved to be 
oxide of titanium. , Hence we have 1 per 100 of that oxide. 

D. The nitric solutions were united and evaporated to dry- 
ness to expel the excess of the acid. The saline mass was 
dissolved in water, and after the barytes was separated with 
sulphuric acid, an excess of subcarbonate of ammonia was 
added to the solution. An abundant precipitate appeared, 
which entirely redissolved. The glucina was precipitated by 
ebullition. After edulcoration and calcination, it weighed 0°79 
gramme, or 15°80 per 100. 

E. The several muriatic solutions (B) were united and evapo- 
rated to a dry mass, which was treated with muriatic acid, and 
there remained 0°33 gramme of silica, from which deduct 0-13 - 
gramme acquired from the agate mortar; and there will be 0:20 
gramme, or 4 per 100 as a constituent of the mineral. 


1824.] Chrysoberyls from Haddam and Brazil. 431 


F. After the silica was separated from the liquid (E), the 
alumina and oxide of iron were precipitated by means of a great 
excess of subcarbonate of ammonia. After twenty-four hours, 
the liquor was separated from the yellowish precipitate, and was 
boiled, but no glucina was precipitated from it. The matter 
precipitated by the subcarbonate of ammonia consisted of 3-68 
grammes of alumina, or 73°60 per 100, and 0-19 gramme of per- 
oxide of iron, which, on account of the colour of the mineral, 
must be estimated as protoxide. The 0:19 gramme of peroxide 
is equivalent to 0-169 of protoxide, or 3°38 per 100. 

The constituents of this chrysoberyl therefore are, 


Per 100 parts. 

Ax Moarsture (67d hate oo eee bag) OG 
©.: Oxide of titamiui « scsiee'e Soest s.. 4 200 
Bo” fer leteinia \Serc ele wt cite ce) wk state wih SER 
FP SM CRs si fds bo De ake Sire aid wha dleds otale 4:00 
Bs PINS, . ei cthic dnt wala nig mie ae eieeumenae 
Hi. Protoxige OL JEON. 2 is. ska caeka,, 308 
98°18 

100-00 

Boas 4k sees Weed. oul echt SMa rey 1°82 


As the preceding results differed so essentially from the ana- 
lyses of the chrysoberyl from Brazil by Klaproth and Arfwedson, 
determined to examine a specimen from that locality. 1:5 
gramme was analyzed in the manner above-mentioned, and the 


following results were obtained :— ‘ 
: Per 100 parts. 
Winters 2c ani Weis wlaleintdgn Sis bia siblb oa) 
Oxide of titanium ........... obishes vie O06 
CAMOMIR: det'c sleleia 6 a18 Bale-G! alelai oS MACS ohLR OOOO 
Silica) <0 Seitide sy... SeladtsGaVi tub deen eeaoe 
lnm Jil). bodeinndKe i. ee CHEE 
Protenide of irons fod die. Hk ee TSS 
98-730 
100-000 
PIT d's ypu, 9 Dra te Opal cae eed aete ii ak exis eae 


In estimating these constituents according to the electro- 
chemical theory, I believe that the oxide of titanium, notwith- 
standing its important agency in the analytical experiments, 
must be regarded as an accidental ingredient, as well as the 
oxide of iron, which in some measure may have been derived 
from the iron mortar. As the cymophane of Brazil appears to 
be constituted more conformably to the hypothesis of chemical 
proportions than that of Haddam, the following calculation may 


432 History of Poisons. [June, 


be made, founded on its composition, which gives for the essen- 
tial constituents of chrysoberyl, 


Per 100 parts. 
Silica...... 6°61 containing oxygen 3°32 
Alumina. ., 75°75 35°38 
Glucina .... 17°64 5:49 


and very nearly corresponds with the following mineralogical 
formula, A *S + 2G A+, 


ArTicLE VII. 
Of Poisons, Chemically, Physiologically, and Pathologically 


considered.* 


ToxicoLoey, or the history of poisons, forms one of the most 
important and elaborate branches of forensic medicine ; and in 
tracing the subject through all its numerous and interesting 
relations to jurisprudence, we shall experience no small degree 
of gratification by observing, how greatly and progressively this 
obscure department of science has, within the last few years, 
been enlightened by the discoveries of chemistry and physio- 
logy. 

the labours of the modern chemist, indeed, have enabled us 
to recognise and identify each particular substance by its pro- 
perties and habitudes, with an infallible delicacy, which the 
physicians of a former age could scarcely have anticipated, 
and much less practised. 

The physiologist, by an invaluable series of observations and 
experiments, has demonstrated the particular organ, or texture, 
upon which each individual poison exerts its energies ; and the 
pathologist has been thus enabled to establish the mode in which 
it depraves the health, or extinguishes the life of an animal. 
Nor has the anatomist withheld his contributions upon this 
interesting occasion, for he has demonstrated the situation, 
extent, and intensity, of the organic lesions which result from 
the operation of these terrible agents upon the living body; and 
has pointed out several appearances which occur from natural 
causes, but which might be mistaken by the unskilful or super- 
ficial observer, for the ravages of poison. It remains for the 
forensic physician to converge into one focus the scattered rays 
which have thus emanated from so many points, and thereby to 
elucidate and determine the line of conduct which the medical 
attendant is called upon to pursue, for the relief of the patient 
suffering under the torments of poison, and for the establishment 


* From Medical Jurisprudence, vol. ii, by Dr, Paris and J. S, M. Fonblanque, Esq. 


| 


‘ a ae 


rT - 7 
ee a = 3 oe 


1824,] History of Poisons. 433 


of the guilt or innocence of the party charged with the perpe- 
tration of a crime, which may be said to rob courage of its just 
security, while it transfers to cowardice the triumphs of valour. 
That engines so powerful and secret in their work of destruction 
should have universally excited the terror of mankind is a fact 
which cannot surprise us, and, when we consider how intimate 
are the relations between fear and credulity, we need not seek 
further for the solution of the many problems to which the exag- 
gerated statements of ancient toxicologists* have given origin ; 
the most extraordinary of those relate to the alleged subtlety of 
certain poisons, which was believed to be so extreme as to defeat 
the most skilful caution, and at the same time so manageable, 
as to be capable of the most accurate graduation ; so that in 
short the accomplished assassin was not only thus enabled to 
ensure the death of his victim through the most secret and least 
suspicious agents, but to measure his allotted moments with the 
nicest precision, and to occasion his death at any period that 
might best answer the objects of the assassination. The writ- 
ings of Plutarch, Tacitus, Theophrastus, Quintillian, and Livy, 
abound with such instances of occult and slow poisoning; most 
of which, however, notwithstanding the weight they may acquire 
from their testimony, bear internal evidence of their fallacious 
character. Plutarch informs us that a slow poison which occa- 
sioned heat, cough, spitting of blood, a lingering consumption 
of the body, and a weakness of intellect, was administered to 
Aratus of Sicyon. This same poison is also alluded to by Quin- 
tillian in his declamations. Tacitus} informs us that Sejanus 
caused a secret poison to be administered by an eunuch to 
Drusus, who in consequence gradually declined, as if by a con- 
sumptive disorder, and at length died. Theophrastus{ speaks 
of a poison, prepared from aconite, that could be so modified as 
to occasion death within a certain period, such as two, three, or 
six months, a year, and even sometimes two years. 

To such an extent does the crime of poisoning appear to have 
been carried, about 200 years before the Christian era, that, 
according to Livy,§ above 150 ladies, of the first families in 
Rome, were convicted and punished for preparing and distribut- 
ing poison, The most notorious and expert character of this 
kind is handed down to us by the historians and poets under 
the name of Locusta, who was condemned to die on account of 
her infamous actions, but was saved in order that she might 
become a state engine, and be numbered, as Tacitus expresses 
it, “ Inter instrumenta regni.” She was accordingly employed 


* The study of poisoning appears to have been of considerable antiquity. Ulysses 
sought poison for his weapons from Ilus, ** ¢apuaxov av8popovov’? Od. 1. 1. v. 2615 but 
__ the conscientious pharmacopolist refused to furnish his dangerous preparations to the 
: wily chief. 

/ + Taciti Annal. lib. iy. ¢.8. 

' £ Hist. Plant. lib. ix, c. 16, p. 189. 

| § Lib. viii. c. 18, 

/ New Series, vot.vu. = 2 F 

i 


434 History of Poisons, [Jo NE; 


to poison Claudius by Agrippina, who was desirous of destroy- 
ing the Emperor, and yet feared to dispatch him suddenly, 
whence a slow poison was prepared by Locusta, and. served to 
him in a dish of mushrooms, of which he was particularly fond, 
“« Boletorum appetentissimus ;” but it failed in its effects, as we 
learn from Tacitus, until it was assisted by one of a more pow- 
erful nature, ‘ Post quem nihil amplius edit.” ‘This same 
Locusta prepared also the poison with which Nero dispatched 
Britannicus, the son of Agrippina, whom his father Claudius 
wished to succeed him on the throne. This poison appears to 
have proved too slow in its operation, and to have occasioned 
only a dysentery. The Emperor accordingly compelled her by 
blows and threats to prepare in his presence one of a more 
powerful nature, and as the tale is related by Suetonius, it 
appears that it was then-tried on a kid, but as the animal did 
not die until the lapse of five hours, she boiled it for a longer 
period, when it became so strong as instantaneously to killa pig 
to which it was given. In this state of concentration it is said 
to have dispatched Britannicus as soon as he tasted it.* Vide 
Tac. An. 13.s, 15, 16. Now it would clearly appear from these 
statements that Locusta, avowedly the most accomplished 
poisoner of ancient Rome, was wholly incapable of graduating 
the strength of her poisons to the different purposes for which 
they were applied. 

The records of modern times will furnish examples no less 
atrocious than those we have just related. Tophana, a woman 
who resided first at Palermo, and afterwards at Naples, may be 
considered as the Locusta of modern history ; she invented and 
sold those drops so well known by the names of Aqua Toffania ; 
Aqua della Toffana ; Acquetta di Napoli, or simply Acquetta, 
This stygian liquor sne distributed by way of charity to such 
wives as wished for other husbands; from four to six drops were 
sufficient to destroy a man, and it was asserted that the dose 
could be so proportioned as to operate within any given period.+ 
It appears that in order to secure her poison from examination, 
she vended it in small glass phials, inscribed “ Manna of Saint 
Nicolas Bari,” and ornamented the vessel with the image of the 
Saint. Having been put to the rack she confessed that she had 
destroyed upwards of 600 persons, for which she suffered death 
by strangulation in the year 1709.t In 1670 the art of secret 
poisoning excited very considerable alarm in France ; the Mar- 
chioness de Brinvillier, ayoung woman of rank and great personal 
attractions, having intrigued with, and subsequently married an 


. * For the ingenious mode in which this poison was administered, see Tacitus. The 
prince having called for a cup of wine, it was purposely presented too hot; he desired 
cold water to be added to it, and the opportunity was then taken to infuse the poison. 
By this stratagem the taster (“¢ calida gelideque minister.” Juy. Sat. v. v. 63) escaped 
its effects, in which he must otherwise have participated with Britannicus. 

+ The reader will find a very interesting account of this diabolical woman in Labat’s 
Travels through Italy, and also in Beckman’s History of Inventions, 

t Hoffman Medicin. Rational. 


1824,] History of Poisons. 435° 


adventurer named Saint Croix, acquired from him the secret of 
this diabolical act, and practised it to an extent that had never 
before been equalled. She poisoned her two brothers through 
the medium of a dish at table. She also prepared poisoned 
biscuits, and to try their strength she distributed them herself 
to the poor at the Hotel Dieu. Her own maid was likewise the 
subject of her experiments. To her father she gave poisoned 
broth, which brought on symptoms characteristic of those 
induced by corrosive sublimate. Her brothers lingered during 
several months under muchsuffering. The detection of this wretch 
is said to have been brought about in the following manner. 
Saint Croix, whenever engaged in the preparation of his poisons, 
was accustomed to protect himself from their dangerous fumes 
by wearing a glass mask, which happening to fall off by acci- 
dent, he was found dead in his laboratory.* A casket directed 
to the Marchioness, with a desire that in case of her death it 
might be destroyed unopened, was found in his chamber, a cir- 
cumstance which in itself was sufficient to excite the curiosity 
and suspicion of those into whose hands it fell. The casket was 
accordingly examined, and the disclosure of its contents at once 
developed the whole plot, and finally led to the conviction of this 
French Medea, who, after a number of adventures and escapes, 
was at length arrested and sent to Paris, where she was behead- 
ed, and then burnt, on the 11th of July, 1676. The practice of 
poisoning, however, did not cease with her execution, and it 
became necessary in 1679 to establish a particular Court, for the 
detection and trial of such offenders; which continued for some 
time to exert its jurisdiction under the title of Chambre de 
Poison, or Chambre Ardente. 
_ With respect to the secret modes in which poisons have been 
supposed capable of acting, mankind have ever betrayed the 
most extravagant credulity, of which the numerous tales upon 
record afford ample proof; such as that reported of Parasapis 
by Plutarch, from Ctesias, in his life of Artaxerxes, who, it is 
said, by anointing a knife on one side by poison, and therewith 
dividing a bird, poisoned Statira with one half, and with the 
other fegaled herself in perfect security. We are also told of 
Livia who poisoned the figs on a tree which her husband was in 
the habit of gathering with his own hands. Tissot informs us 
that John, king of Castille, was poisoned by a pair of boots pre- 
pared by a Turk; Henry VI. by gloves ;+ Pope Clement VII. 
* This story, if we mistake not, suggested to the successful author of Kenilworth the 
tragic death of his alchymist. 


+ The belief in the possibility of poisoning by the vestments is very ancient, as is 
shown by the fabled death of Hercules. 
, ‘¢ Capit inscius heros: 
Induiturque humeris Lernee virus Echidne. 


—. 


Incaluit vis illa mali; resolutaque flammis ; 
Herculeos abiit Jate diffusa per artus.”’ 

Ovid, Metam, lib, ix, vy. 157. 
22 


436 History of Poisons. [Junez, 


by the fumes ofa taper;* and our king John in a wassail bowl, 
contaminated by matter extracted from a living toad. Tothese 


few instances of credulity may be added the offer of the priest 
to destroy queen Elizabeth by poisoning her saddle,+ and the 
Earl of Essex, by anointing his chair. — , 
Incredible and absurd as these opinions now appear, they 
continued until a late period to alarm mankind, and to perplex 
and bafle judicial investigations ; even Lord Bacon in his charge 
against the Earl of Somerset for the murder of Sir Thomas Over- 
bury, in the Tower, seemed to give credit to the story of Livia, 
and he seriously stated, that ‘“‘ Weston chased the poor prisoner 
with poison after poison; poisoning salts, poisoning meats, 
poisoning sweetmeats, poisoning medicines and vomits, until at 
last his body was almost come, by the use of poisons, to the 
state that Mithridates’s body was by the use of treacle and pre- 
servatives, that the force of poisons was blunted upon him; ” 
Weston confessing, when he was reproached for not dispatching 
him, that he had given enough to poison twenty men.{ The 
power of so graduating the force of a poison as to enable it to 
operate at any given period seems to have been considered pos- 
sible by the earlier members of the Royal Society; for we learn 
from Spratt’s history of that learned body, that very shortly after 
its institution, a series of questions were drawn up by the direc 
tion of the Fellows, for the purpose of being submitted to the 
Chinese and Indians, viz. ‘‘ Whether the Indians can so prepare 
that stupifying herb, Datura, that they make it lie several days, 
months, years, according as they will have it, in a man’s body, 
without doing him any hurt, and at the end kill him without 
missing half an hour’s time ?” 
That mankind were, in a very early stage of their existence, 
not only acquainted with the deadly effects of certain natural 
substances when applied in minute quantities, but that they 
availed themselves of such knowledge for the accomplishment 
of the worst purposes, is very satisfactorily shown by the records 
of sacred as wellas profane authors. But such is the ambiguity 
of ancient writers upon this subject, and so intimately blended 
are all their receipts with the practices of superstition, that every 
research, however learned, into the exact nature of the poisons 
which they employed, is necessarily vague and unsatisfactory: 
Of this one fact, however, we may be perfectly satisfied, that they 
were solely derived from the animal and vegetable kingdoms, 
for the discovery of mineral poisons was an event of later date ; 
owing however to the defect of botanical nomenclature, it is even 
doubtful whether the plants which are designated by the terms 
cicuta, aconitum, &c. in ancient authors, were identical with 
those we designate by the same names. (See Pharmacologia, 
fifth edit. vol. 1. p.66.) With respect to the poisons of Locusta, 


* Quast. Med. Leg. 
+ Sir Edward Coke in the trial of Sir John Hollis. 
~ Bacon’s Works, vol. ii, p, 614, 


1824.) History of Poisons. 437 


all cotemporary writers speak of the venom of the toad as the 
fatal ingredient of her potions, and in the Alexipharmaca of 
Dioscorides we find the symptoms described, which are said to 
be produced by it;* but what is very extraordinary, the belief of 
the ancients on this matter was all but universal. Pliny is 
express on the subject; AXtius describes two kinds of this rep- 
tile,} the latter of which, as Dr, Badham has suggested, was 
probably the frog, as well from the epithet, as that he ascribes 
deleterious powers only to the former. It is scarcely necessary 
to observe that this ancient belief has descended into later times ; 
we find Sir Thomas Browne treating such an opinion as one of 
the vulgar errors ; and we have before alluded to the legend of 
king John having been poisoned by a wassail bow! in which 
matter extracted from a living toad was said to have been 
infused. In still later times, we have heard of a barrel of beer 
oisoned by the same reptile having found its way into it. 
orelli and Valisnieri maintain that it 1s perfectly harmless, and 
state that they had seen it eaten with impunity. Spielmant 
expresses the same opinion, ‘‘ Minus recte itaque effectus vene- 
nati a bufonibus metuuntur.” Franck,§ on the contrary, accuses 
Gmelin of too much precipitancy in rejecting the belief respect- 
ing toad-poison.|| Modern naturalists recognise no poisonous 
species of toad ; even the most formidable of the species, to 
appearance, that of Surinam, is said to be perfectly harmless. 
If we may venture to offer a conjecture upon this subject, we 
are inclined to consider the origin of this opinion to have been 
derived from the frequency with which the toad entered into the 
composition of spells or charms, into philtres or love potions, 
and which, like the bat and the owl, most probably derived its 
magical character from the gloom and solitude of its habitation. 
Shakspeare has accordingly introduced this reptile into ‘the 
witches’ enchanted cauldron, in Macbeth. 


*¢ Round about the cauldron go; 
In the poison’d entrails throw. 
Toad that under coldest stone 
Days and nights hast thirty-one 
Swelter’d venom sleeping got, 
Boil thou first i’ the charmed: pot ! ”? 


This opinion receives further strength when it is considered 
how frequently poisons were administered under the insidious 
form of charms or incantations.** 


* © emldscey cibyuclla cwualos, pela wyedlylog eielaueng. Sugmvoew as ducqoia oBpdevecs 
To Sloman, xo Avypos avlosg Yardlos, evscle 86 nae oneppalog amgoadpelog exxpicig.” 
+. xwhogy apboyysss 2. Pwvylixog. 
t Instit. Mater, Medic. p. 116. 
§ Manuale di Tossicologia, p. 79, 245. 
. A See also Instituzioni di Med, For. di G. Tortosa, yol. ii. p. 67, and authorities there 
cited, 7 
** This fact may be illustrated by ancient as well as modern records ; from the poi- 
pom tunic of the Centaur Nessus, to the treacherous powders of the diabolical Mary 
ateman, 


438 History of Poisons. [Jenr, 

It has, however, been shown by late experiments that the toad 
has, under particular circumstances, the power of ejecting from 
the surface of the body an acrid secretion which excoriates the 
hands of those that come in contact with it; and this fact may, 
perhaps, have assisted in supporting the general belief respecting 
the poisonous nature of this reptile. Pelletier has ascertained, 
that this corrosive matter, contained in the vesicles which cover 
the skin of the common toad (Rana Bufo), has a yellow colour, 
and an oily consistence, and to consist of,—I1st, an acid partly 
united to a base, and constituting 1-20th part of the whole. 
2d, very bitter fatty matter. 3d, an animal matter bearing some 
analogy to gelatine. 

It would also appear from the writings of Dioscorides, Galen, 
Nicander, Aitius, Bian, and Pliny, that the ancients derived a 
very energetic poison from the sea hare, Lepus Marinus,—the Aply- 
sia Depilans of Linneus ; and, if we may credit Philostratus, it 
was with sucha poison that Titus was killed by Domitian. 

There is, however, ample ground for supposing that the poi- 
sons of the ancients were, for the most part, obtained from the 
vegetable kingdom, and from the class of narcotic plants ;* that 
they were compounded of a great variety of such ingredients, 
together with others that were quite inert and useless, and which 
merely served to disguise their composition, 

Ancient writers also allude to the blood of the bullock as a 
Bh Themistocles is said by Plutarch to have destroyed 

imself by this fluid; and Strabo states, that Midas died of 
drinking the hot blood of this animal, which he did, as Plutarch 
mentions, to free himself from the numerous ill dreams which 
continually tormented him. Some historians assign the death 
of Hannibal to the same draught. 

With respect to the poisons employed by Tophana, the 
Locusta of modern days, and her infamous successors, there is 
less doubt; arsenic, corrosive sublimate, sugar of lead, and anti- 
mony,} were among the most powerful of their instruments of 
torture and death. According to the declaration of the Emperor 
Charles VII. to his physician Garelli, the Aqua Toffania was a 
solution of arsenic in Aqua Cymbalarie.{ Dr. Hahneman con- 
sidered its basis to have been an arsenical salt. Others have, 
with little probability, regarded opium and cantharides as the 


* Theophrast. Hist. Plant. lx. c. 16. Strabo mentions the action of the Lauro- 
, cerasus, as a poison, and observes that it occasions a death like that of epilepsy. 

++ All these substances were found in the casket of Saint Croix. 

+ Gerarde, in his Herbal, considers the Cymbalaria to be the Pennywort of which he 
describes two varieties, viz. the Wall-pennywort, and the Water-pennywort ; ‘and he 
blames the ‘ignorant apothecaries,” for using the latter instead of the former, as 

_extremely dangerous and destructive to life. Modern botanists consider it as an Antirr- 
hinum,—A. Cymbalaria. Lin. i.e. Ivy-leaved Toad-flax. We are not aware of any 
part of this genus being poisonous. The A. Linaria, common Toad-flax, appears to be 
the only one to which any medicinal yirtues have been ascribed. Linnzus, however, 
says (Flor. Suec.) that this plant is used as a poison to flies. 


-1824.] Slow, Consecutive, and Accumulative Poisoning. 439 


active ingredients. Franck,* speaking of the Agua Toffania, 
agrees with Gmelin,+ that it is no other than a solution of 
arsenic. The Pulvis Successtonis, another instrument of death, 
whose title announces the diabolical intention with which it was 
‘administered, has been supposed to have been a preparation of 
lead ; while others have considered it to have consisted of dia- 
mond dust, and to have acted mechanically. 

Having thus noticed a few of the more remarkable and inte- 
resting features in the literary history of Toxicology, we shall 
proceed to consider the subject of poisons, in relation to their 
operation. 

A poison (Toxricum, Venenum, Virus), has been very correctly 
‘defined by Gmelin to be a substance which, when administered 
internally, or applied externally in a small dose, impairs the 
health, or destroys life. This definition is adopted by Mead, 
Sproegel, Plenck, and Tortosa, and is to be preferred to every 
other,{ not only for its simplicity, but forits independence of any 
‘theory relative to the modus operandi of such agents. But it 
will be seen that, by accepting this definition, we are necessa- 
rily led to admit the fact, that poisoning may be acute, or chro- 
‘nic ; that is to say, that it may at once destroy life, or produce 
a disease which can be protracted to any indefinite period. 
After the erroneous and vague notions which have been enter- 
tained upon the subject of “ Slow poisons,” it is highly essen- 
‘tial that the latitude of our belief should be accurately ascer- 
tained, and the precise meaning of our terms defined. 


Of Slow, Consecutive,§ and Accumulative Poisoning. 


1. Slow Poitsons.—According to the popular acceptation cf 
the term, they may be defined, substances which can be admi- 
‘nistered imperceptibly ; and a single dose of which will operate 
so gradually, as to shorten life like a lingering disease ; their 
force, at the same time, admitting of so nice an adjustment as 
‘to enable the artist to occasion death at any required period. 
‘We have now to inquire how far such alleged powers are con- 
‘sistent with the known laws of physiology. {t cannot be denied 
that certain substances have been introduced into the alimentary 
‘eanal, where they have remained for an indefinite period, with- 


* Man. de Toxicol. 

+ Hist. General de Venen, mineral. 

+ Boerhaave gives us the following definition, ‘* Venenum dico omne illud quod 
‘ingestum vel applicalum corpori, talem in corpore humano mutationem excitat, qua 
per ipsam eam mutalionem non superatur. Medicamentum praterea in co differt, quod 
ipsa, quam facit mutatio, in sanitatem tendat, vencnum vero corpus mutat, ul ex sano 
“egrum fiat, aut cadaver.” (Prelect. Acad. T. vi. p. 283.) Hoffmann has furnished 
us with a definition less exceptionable than the foregoing, but still inferior to that of 
Gmelin, “ Alit natura res, gue erigua mole et summa partium tenuitate, brevi tem- 
pereconcentum alque ordinem motuum vitalium pervertunt, vel plane destruunt; et he 
vocari solent Venena.”” (M. R.S. T. II. p. 88.) 

§ We have adopted this term, as one that has been in previous use, although we are 
by no means satisfied that a more expressive word might not be found. 


440 Slow, Consecutive, and Accumulative Poisoning, (Juxx, 


out ‘occasioning the slightest. mconvenience, and at length 
excited a disease that has, terminated fatally; in the London 
Medical and Physical Journal for February, 1816, a case is 
related in which death was occasioned by a chocolate-nut 
haying lodged in the entrance of the appendix vermiformis ; and 
in the Edinburgh Medical and Surgical Journal for July, 1816, 
we have an analogous case, communicated by Dr. Briggs of 
Liverpool, where the Appendix ceci sphacelated, owing to the 
irritation of a human tooth which was found sticking in its 
cavity, Mr. Children has lately communicated to the Royal 
Society a case where a concretion in the colon produced death; 
upon examination it was found to contain a plum-stone, as a 
nucleus, and to consist of a fine fibrous vegetable substance, 
from the inner coat enveloping the farina of the oat, and which 
was derived from the oatmeal upon which the deceased had fed. 
(Phil. Trans. 1822.) However disposed we may feel, by a forced 
construction of the term, to consider such agents as s/ow poisons, 
it is very evident that they can rarely have been made subser- 
vient to the purposes of secret poisoning; although a case » 
occurred in the practice of the authur,* in whicha girl swallowed 
six copper pence for the avowed purpose of destroying herself; 
the coin produced a disease which remained chronic for a very 
considerable period, when, after a lapse of five years, they were 
voided, and the young woman recovered. A similar attempt 
was also made by Theodore Gardelle, after his conviction for 
the murder of Mrs. King-(vide ante) ; he swallowed a number of 
halfpence, for the purpose of destroying himself, but without any 
ill effect. Dr. Baillie, in his “ Morbid Anatomy,” relates an 
instance where five halfpence had been lodged ina pouch in the 
stomach for a considerable time, without occasioning any irrita- 
tion; and Mr. A. Thomson has also furnished us with two ana- 
logous cases in children, in one of which the copper coin 
remained six months in the intestines, and in the other two 
months. ‘These facts furnish sufficient data to enable the prac- 
titioner to appreciate the degree of danger attendant upon such 
agents, and to determine how far they can ever become success- 
ful instruments in the hands of the assassin.+ 
But it has been supposed that certain bodies, as glass, ena- 
mel, diamonds,{ agates, smalt, &c. when administered in the 
form of powder, so lacerate the membranes of the stomach by the 
sharpness of their particles, as slowly to destroy life; and upon 
the same principle, it has been asserted, that human hair, 


® This case is detailed in his ‘ Pharmacologia,’ under the article Cupri Sulphas. 

+ See an interesting paper by Dr. Marcet, in the 12th volume of the Medico-Chirur- 
gical Transactions, entitled, ‘‘ Account of a Man who lived Ten Years after having 
swallowed a number of Clasp Knives.” 

+ In the reign of Louis XIV, Henrietta, Duchess of Orleans, is said to have heen 
poisoned by diamond-dust mixed with powdered sugar. The same substance is enume- 
rated among other extraordinary poisons, as haying been administered in the case of Sir 
Thomas Oyerbury. 


1824:] Slow, Consecutive, and Aécumulative Poisoning. 441 


chopped fine,* constitutes the active ingredient of a slow poison 
frequently employed in Turkey, and that it induces by irritation 
a chronic disease resembling cancer. With respect to the 
danger arising from the ingestion of diamonc dust, enamel pow- 
der, powdered glass, and the like, there still may be said to 
exist some difference of opinion. Caldani, Mandruzzato,+ and 
M. Le Sauvage, have reported experiments made upon men and 
inferior animals, in which no bad consequences followed the 
administration of such bodies ; whereas Schurigiust and Carda- 
nus§ cite instances where persons have died of ulcerations of the 
stomach from such causes ; and this opinion receives the sup- 
hol of Plouquet,|| Stoll,** Gmelin,;+ Fodere,t{ Mahon,§§ 
ranck,|\|| and many others, The modern pathologist will not 
‘find much difficulty in reconciling such conflicting testimony. 
The experimentalist may administer mechanical substances a 
thousand times without producing any ill effects, while, under 
certain circumstances, the most trivial body may lodge in the 
intestines and produce death ; but surely the occasional occur- 
rence of such accidents ought not to confer the general title of 
poison upon the substances which may happen to produce them. 
Having thus disposed of a considerable number of bodies, 
which have been classed as slow poisons, we may proceed to 
observe that most of the other substances which have found a 
place in the same division, appear to us to deserve consideration 
under a very different head, and that we shall get rid of much 
obscurity by adopting the following arrangement. 
2. Consecutive Poisoning.—Where the patient, having reco- 
vered from the acute effects occasioned by the ingestion of a 
single dose of poison, subsequently suffers a series of symptoms 
from the injured structure to which it had given origin. By 
referring to our definition of slow poisoning, we shall at once 
perceive the striking and important distinction between that 
and consecutive poisoning. The following case, related by M. 
Orfila, may serve as an illustration. Maria Ladan drank by 
mistake a spoonful of aquafortis, the most violent symptoms 
supervened, but which by judicious treatment gradually sub- 
sided, when at length she passed by stool a long membranous 
substance, rolled up, and which represented the form of the zso- 
agus and stomach, and which, in fact, was found to be the 
interior membrane of these organs ; from that moment the sen- 


* Old women in the country recommend the same remedy for the destruction of 
‘worms; probably the medicine and the poison may be equally effective. 

+ Saggi Scientif. e Letter, dell’ Accademia di Padoya, tom, iii, p, 11,p, 1. 

3 Chylologia, 

§ De Venenis. 

|| Comment. super Homicid. p. 177. 

** Ratio Medendi. Part VI. p. 60. 

++ Hist. General de Venenis Mineral. 

+t Med. Leg. tom. ii, p. 110. 

§§ Tom. ii. p. 346. 

\\|| Man, de Toxicol, 


442 Slow, Consecutive, and Accumulative Poisoning. [Junr, 


sibility of the digestive organs became excessive, and two 
months after the accident she experienced a sudden shock and 
died. Mr. Tartra, in observing upon cases of this kind, asserts 
that the symptoms produced at first by the nitric acid decrease 
insensibly ; and that at the end of a certain period, the internal 
membrane of the digestive canal is struck with death, and 
thrown off, and the person dies ofa marasmus. Fordyce* relates 
the case of a woman who was subject to cholics for the space of 
thirty years, in consequence of having once taken an infusion of 
the pulp of colocynth prepared with beer. ‘This was undoubtedly 
an extraordinary instance of idiosyncrasy, but it is probable that 
some organic lesion was occasioned by its operation, to which 
the subsequent suffering is to be referred. We have hitherto 
only considered the effects that may arise from the ingestion of 
a single dose of poison, but there are numerous and very interest- 
ing cases in which fatal results have been produced by the repe- 
tition of small doses at various intervals. We therefore propose 
a third, and new subdivision of our subject, viz. 

3. Accumulative Poisoning.—By the repeated administration 
of a substance in doses, of which no single one could occasion 
harm; but which, by gradually accumulating in the system, 
ultimately occasions disease and death. 

The familiar operation of mercury will at once suggest itself 
to the physician, as a striking illustration of that species of 
poisoning which we have ventured to name Accumulative, and 
to the forensic student the effects of this metal, in reference to 
such a quality, will form a more than ordinary object of interest, 
as involving questions which have frequently embarrassed judi- 
cial inquiry ; as, for instance, Whether it can lie dormant any 
considerable time without betraying its effects upon the consti- 
tution, and, having displayed its powers, and the symptoms 
having subsided, viz. salivation, &c. Whether they can be 
renewed without a fresh application of the substance? See 
Corrosive Sublimate. 

To how many substances this power of accumulation extends 
is at present not well understood. It may occur in those that 
act by absorption, and in those whose action is wholly local. 
Arsenic, digitalis, and several of the narcotic plants, as hemlock, 
may undoubtedly occasion serious mischief in this manner, as 
the author has more fully explained in another work,} and we 
have lately heard. of several fatal cases arising from accumulated 
masses of magnesia in the prime vie, from the habitual use of 
small doses of that earth. 

The history of many of the arts, especially those of metallurgy, 
would furnish also abundant examples of this kind of poisoning. 

These few facts are, we trust, sufficient to authorise the fore- 
going arrangement, and we apprehend that the adoption of the 


™ Fragmenta Chirurg. et Med. p. 66. 
+ Pharmacologia, fifth edit. vol. i. p. 324 


ram 


CMOS LAS Gi PAI 


1824.] Slow, Consecutive, and Accumulative Poisoning. 443 


distinctions upon which it is founded, will be of great service in 
establishing fixed and definite notions with regard to the chronic 
operation of poisons. It may perhaps be useful to present the 
reader with a synoptical recapitulation of the subject. 

A Slow Poison.—A single dose is sufficient ; which produces 
upon its administration no sensible effect, but gradually 
undermines the health. 

A Consecutive Poison —A single dose is sufficient ; producing 
the most violent symptoms, very shortly after its inges- 
tion, but which gradually subside, and the patient is sup- 
posed cured ; when, at some future period, death takes 
place from the organic lesions that had been occasioned. 

An Accumulative Poison—Many doses are required; the 
effects being produced by the repetition of doses which 
would, individually, be harmless. 

There still remains another point of view in which it is essen- 
tial to regard the operation of a poison, in order to establish a 
distinction between those substances which, in a given dose, 
will destroy life under every circumstance of constitution, and 
those ‘hich occasion death in consequence of some constitu- 
tional peculiarity in the individual to whom they may have been 
administered, and which are innocuous to the general mass of 
mankind; the gradations by which food, medicine, and poison, 
are thus enabled to branch into each other cannot be defined, 
because the circumstances with which they are related, defy 
generalization. The distinction, however, must be acknowledged 
and preserved, and we know no terms better adapted for express- 
ing it than those of Absolute and Relative poisons; and our 
readers are accordingly requested to receive them in conformity 
with this explanation, whenever they occur in the following 
pages. Every work professing to treat the subject of poisons, 
abounds with instances, in which articles that, by universal con- 
sent, are considerec innocuous, have occasioned the most dire- 
ful effects. Morgagni relates a case of a person who died from 
eating bread made with the farina of the chesnut. Dr. Winter- 
bottom* says that he is subject to severe nettle-rash after eating 
sweet almonds. Schenkius relates a case in which the general 
law of astringeuts and cathartics was always reversed. Donatus 
tells us of a boy whose jaws swelled, whose face broke out in 
spots, and whose lips frothed, whenever he eat an egg: we 
might add many more examples, but it is needless to encumber 
a subject with illustrations which is already so obvious and 
indisputable. Nor do the anomalies of constitutional idiosyn- 
crasies end here, for they not only convert food into poison, but 
they change poison into food, or at least into a harmless repast. 
The most extraordinary exemplification of this on record is con- 

* See Medical Facts and Observations, vol. v. 3 


+ See M. Pouqueville’s ** Voyage de Morée,” also Mr. Thornton's Travels ; and 
Notes to Lord Byron’s Childe Harold's Pilgrimage. 


444 On the Action and Nature of [JuNE, 


tained in the history of the old man at Constantinople, as related 
by M. Pouqueville, physician to the French army in Egypt, and 
who was a prisoner at Constantinople in the year 1798. “ This 
man,” says he, * was well known all over Constantinople, by 
the name of Suleyman Yeyen, or Suleyman, the taker of corro- 
sive sublimate. At the epoch when I was there he was sup- 
posed to be nearly 100 years old, having lived under the Sultans 
Achmet IIT. Abdul Hamet,-and Selim III. He had in early life 
habituated himself to taking opium; but, notwithstanding that 
_ he constantly increased the dose, he ceased to feel from it the 
desired effect, and then tried sublimate, the effects of which he 
had heard highly spoken of; for thirty years this old man never 
ceased to take it daily, and the quantity he could now bear 
exceeded a drachm, It is said, at this epoch he came into the 
shop of a Jewish apothecary, and asked for a drachm of subli- 
mate, which he swallowed immediately, having first mixed it in 
a glass of water. The apothecary, terrified, and fearing that he 
should be accused of poisoning a Turk, immediately shut up his 
shop, reproaching himself bitterly with what he had done; but 
his surprise was very great, when the next day the Turk came 
again, and asked for a like dose of sublimate.” 

Morbid states of the body may also exist which are capable 
of resisting to a certain extent, or of modifying, the violent 
operation of compat poisons. In the history of the Royal 
Academy of Sciences for 1703, a case is related of a woman, 
who being tired out by a protracted dropsy, under which her 
husband had suffered, charitably administered to him fifteen or 
twenty grains of opium with the intention of dispatching him; 
but the dose immediately produced. such copious evacuations by 
sweat and urine, that it restored him to health. This relation 
will immediately recall to the recollection of the classical reader 
the story recorded by Plutarch, in his life of Crassus, of Hyrodes 
king of the Parthians, who having fallen into a dropsical com- 
plaint had poison (aconite) administered to him by his second 
son, Phraates, but which, instead of destroying the king, as 
intended, cured his disease. The son, however, having thus 
failed in his attempt, shortly afterwards smothered his father 
with his pillow. 


Articie VIII. 


Speculations and Inquiries respecting the Action and Nature of 
certain Compounds of Sulphur. 


The cases in which sulphur decomposes water, and combines 
with one or both of its elements, may, perhaps, be reduced to 
three : 


1824.] certain Compounds of Sulphur. 445 


1, The action of a metallic sulphuret. 

2. The action of a metallic oxide and sulphur. 

3. The action of a metallic oxide and a metallic sulphuret. 

The simplest case is that of putting sulpburet of potassium 
into water. In this case water is decomposed, the oxygen 
forming potash with potassium, and the hydrogen hydrosulphuric 
acid with the sulphur; and supposing that an atom of sulphuret 
of potassium is decomposed, there must of course be formed an 
atom of hydrosulphate of potash consisting of 


} atom hydrosulphuric acid (1+16).. = 17 
1 atom potash (8+40)............. = 48 
65 


When potash and sulphur are boiled together, the action is of 
course more complicated. Water must be decomposed, for an 
acid added to the solutien evolves hydrosulphuric acid, and sul- 
phur is precipitated. Now hydrosulphate of potash is not 
decomposed by an acid so as to precipitate sulphur, and more- 
over, although water is decomposed, what becomes of its oxygen? 
Does the following take place ? 


L atom, hydrogen «). 0.0 je 010 ors in 0 oieis = 1p 
DASSORV RUNDE E nn nes alsioie 6's x tenige han = WO 
Hydrosulphuric acid. ........ee eens pay 


And does the atom of oxygen unite with another atom of sulphur 
to form hyposulphurous acid? Thus 


1 atom Oxygen... sessesseereccvees -os 8 
1 atom sulphur......cselecseseds ine ae AO 


Hyposulphurous acid. ......eceseseeee 24 


This appears to be probable, for it will readily be granted that 
oxygen is not evolved from the decomposition of the water, 
while its hydrogen is forming hydrosulphuric acid. The oxygen 
cannot unite with potash, for that is already an oxide, and it 
cannot convert it into peroxide, for that is decomposed by water. 
As then in this case both the elements of the water appear 
necessarily to combine with the sulphur, there are, perhaps, 
formed hydrosulphate and hyposulphite of potash. But here 
again a difficulty occurs: when hydrosulphate and hyposul- 
phite of potash are treated with an acid, although hydrosulphu- 
ric acid must be given out by the decomposition of the former 
salt, neither of them, | believe, yields sulphur, which is well 
known to be precipitated from the solution of sulphur in potash. 
Is there a third compound formed, which is merely a solution of 
sulphur in potash, and in which no water is decomposed? Is 
there in fact formed a real sulphuret of potash ? This appears to 


446 On the Action and Nature of [JuNE, 


me probable ; in which case we should have, by dissolving sul- 
phur in a solution of potash, io 


Hydrosulphate of potash, 
Hyposulphite of potash, 
Sulphuret of potash. 


Without the existence of the last compound, I do not see how 
sulphur could be precipitated by an acid; and unless the first 
existed, hydrosulphuric acid could not be evolved by the same: 
means ; and it seems requisite to suppose the existence of the 
second in order to dispose of the oxygen. 

This subject will, perhaps, admit of illustration by observing 
what happens when chlorine is passed into an aqueous solution 
of potash. The water is decomposed, its hydrogen combines 
with chlorine to form hydrochloric, and its oxygen with another 
portion of chlorine to form chloric, acid ; this then is perfectly 
analogous to what I have supposed to occur with sulphur. It 
might indeed be imagined that the sulphur is converted into 
sulphuric acid instead of hyposulphurous ; but this does not 
happen, for the solution when decomposed by muriatic acid 
affords no traces of the sulphuric on the addition of a barytic 
salt. . 

Whether a compound of chlorine and potash exists, I know 
not; but chloruret of lime is a well-known compound, and if 
chlorate, and consequently hydrochlorate of lime can also be 
formed by the action of chlorine upon water and lime, then 
the parallel between the actions of chlorine and sulphur will be 
complete; we should have hydrosulphate, hyposulphite,: and 
chloruret of lime. 

When sulphuret of antimony is boiled in solution of potash, 
what happens? We have sulphur, a metallic oxide, and a metal, 
operating upon and decomposing water ; and when sodais used 
instead of potash (which is the same for the argument), a crys- 
tallized salt is obtained, which consists cf hydrosulphuric acid, 
soda, and oxide of antimony. When sulphuric acid is added to 
this solution, hydrosulphuric acid is given out, and sulphate of 
soda formed, by the decomposition of the hydrosulphate of soda; 
but the hydrosulphate of antimony not being decomposed by the 
sulphuric acid and (unless when it forms a double salt), being 
insoluble, it is precipitated of an orange colour, consisting, there 
is no doubt, of hydrosulphuric acid and oxide of antimony. 
Now it is by no means easy to discover what happens in this 
case. Let us suppose we are operating upon an atom each of 
potash, antimony, and sulphur; if only | atom of water be 
decomposed, then protoxide of antimony, as we have reason to 
suppose is the case, would be formed by the union of 44 of anti- 
mony with 8 of oxygen. We have then 16 of sulphur to com- 
bine with 1 of hydrogen to form 17 = 1 atom hydrosulphuric 


1824:] _ certain Compounds of Sulphur. — ° 447 


acid ; but this would be sufficient only to saturate either 48 
of potash = 1 atom, or 52 of protoxide of antimony = | atom. 
This is a difficulty; but as a double salt is evidently formed, may 
we not suppose that the metallic oxides, oxide of potassium, and 
oxide of antimony, form sub-bisalts with the sulphuretted hydre- 

en? or so to speak, that they each take half an atom? We 
should then have a salt consisting of 


1 atom hydrosulphuric acid ........ Ay os 
] atom potash. ........ a by =g 
1 atom oxide of antimony.......... = 52 


- It can hardly be admitted that more than one atom of water 
is decomposed ; for in that case we should increase the difficulty ; 
since not only would there be 2 atoms of hydrogen to combine 
with 1 of sulphur ; but either hyposulphurous acid, or peroxide 
of antimony, must be formed at the same time: now for the 
former the sulphur is evidently insufficient, and peroxides lose 
oxygen by exposure to the action of hydrosulphuric acid. 

_ The action of hydrosulphuric acid upon metallic oxides. is 
reducible also to three cases. First, when they combine without 
either being decomposed, as when potash unites with it to form 
an hydrosulphate. In this case neither the hydrosulphuric acid 
yields its hydrogen, nor does the oxide give up its oxygen. The 
same appears to be the case with oxide of antimony, excepting 
that the compound is insoluble in water. The second case is 
when the hydrosulphuric acid is decomposed, but without pre- 
cipitating the metal from solution. This happens when sulphu- 
retted hydrogen is passed into a solution of peroxide of iron, 
The excess of oxygen combines with the hydrogen of the hydro- 
sulphuric acid, the peroxide becomes protoxide, and suiBhHE is 
precipitated. The third case is that of adding hydrosulphuric 
acid to solution of lead, copper, &c. In these cases water 
appears to be formed by the union of the hydrogen of the hydro- 
sulphuric acid, with the oxygen of the metallic oxide, and the 
consequence is that a metallic sulphuret is precipitated. 

These hypothetical ideas are thrown out in the hope that they 
may lead to experiments for the purpose of elucidating an 
important but yet obscure branch of chemical science; and it 
may be observed, if these speculations are just, that the disco- 
very of hyposulphurous acid is one of considerable importance in 
elucidating this subject. 


448 Mr. Underwood on the Coliseum at Rome. [JUNE 


ArticLe IX. 
On the Coliseum at Rome. By T.R. Underwood, Esq. MGS. 
(To the Editor of the Annals of Philosophy.) 


SIR, ’ Paris, May 24, 1824. 

As I am not aware that the following circumstance has been 
hitherto noticed, I shall beg the favour of the insertion of it in 
your journal. 

It is generally supposed that the ground plan of the external 
wall of the Coliseum at Rome is an ellipsis. This, however, is 
not the case, as I discovered, when examining it in September, 
1802, that the plan of the external surface of the walls between 
the columns was a straight line, and not a curve; so that this 
vast amphitheatre is in fact a polygon of 80 sides. The differ- 
ence in the effect of the whole, between this and an ellipsis, is 
not sensible in a general view, the angles of the polygon being 
covered by the columns ; but the saving of time and expence in 
constructing the arches circular in a curved plan must, as every 
architect well knows, have been very considerable indeed. ©The 
entablatures, however, over the columns are ellipses, which is 
the source of the error respecting this building. 

On my return from Italy such was the force of prejudice, even 
in professional men, English as well as French, in favour of the 
supposed ellipsis, that I could not obtain any credit for this 
statement, nor even induce any one who visited Rome, by accu- 
rate examination, to confirm or confute it, till M. A. Brongniart, 
Member of the French Institute, on his visit to Italy in 1820, 
undertook, at my request, the inquiry, and his careful examina- 
tion has confirmed its accuracy. 

I have the honour to be, your humble servant, 
T. R. UNDERWOOD. 


ARTICLE X, 


Analysis of the Argillaceous Iron Ore. 
By R. Phillips, FRS. &c. 


Ir is well known that the greater part of the immense quan- 
tity of iron yielded by the mines of this kingdom is obtained 
from what is called the argillaceous iron ore. A specimen 
which I analyzed was of that variety, which is called at Low 
Moor Iron Works near Bradford, Yorkshire, Black Lron Stone. 

Its colour, as its name imports, is nearly black ; its sp. gr. 


1824.] Mr. Phillips on Argillaceous Iron Ore. 449 


3:055, it yields easily to the knife, and becomes magnetic 
when heated by the blowpipe. 

a. 100 grains of this ore reduced to powder and moderately 
dried on.a sand bath, lost one grain, which was evidently mere 
eae moisture. 

. As it effervesces strongly when put into an acid, 100 
grains were put into a vial containing sulphuric acid, the weight 
of which and its contents were together noted. After the efter- 
vescence was over, which took place slowly, it was found that 
29°3 grains of carbonic acid were given out. The iron was evi- 
dently in the state of protoxide, for crystals. of protosulphate 
of iror were obtained. Indeed no percarbonate of iron pro- 
bably exists, or at any rate none has been described, and it 
cannot be formed artificially. 

c. 200 grains of the ore were treated with muriatic acid ; nitric 
acid was added to convert the protoxide of iron into peroxide. 
The solution was decomposed by ammonia, and the peroxide of 
iron precipitated, being washed, dried, and ignited, weighed 
97-5 grains. On repeating the experiment the mean result was 
96°15 = 48-075 per cent. The iron in the ore exists as already 
mentioned in the state of protoxide, and as 40 pevoxide are 
equivalent to 36 protoxide, 48°075 are equal to 43:26 protoxide 
of iron, which is the quantity contained in 100 grains of the ure. 

d. The residuum insoluble in muriatic acid was of a dark 
colour, and after being moderately dried, it was heated to red- 
ness in a platina crucible; by this it became perfectly white, 
and lost 5°33 grains, whichis the weight of the carbonaceous 
matter. The insoluble residuum, consisting of silica and alu- 
mina, gave a mean of 18-12 per cent. 

e. The ammoniacal solution, after the separation of the iron, 
was treated with carbonate of ammonia; by this a quantity of 
carbonate of lime was thrown down; it weighed in one experi- 
ment 7, andin the other 6°5 grains, giving a mean of 3°74 of 
lime, which of course existed in the ore in the state of carbonate. 

Jf. The ammoniacal solution, evaporated so as to expel all 
excess of ammonia, was treated with prussiate of potash; a 
precipitate of a light pinkish hue was obtained, but the quantity 
was too small to allow of determining the quantity of oxide 
of manganese which it indicated. 

It will then appear that the ore, usually, but improperly called 
argillaceous iron ore, is in fact a carbonate of iron, consisting of 

ft ul DAGPRLORE) sc pulrrie de-riccooele 10 
6 Carbonic acid ............ 29°3 
c _Protoxide of iron.......... 43°26 
F Carbonaceous matter ...... 5°33 
Silica and alumina ..,..... 18°12 
iy LAMNC ia icsarntosdbayah jeter yore s2h000 DIAS 


100°78 
New Series, vou, vil. 26 


450 Analyses of Books. (June, 


As an atom of carbonic acid is represented by 22, and one of 
protoxide of iron by 36, the 45°26 of protoxide which the ore 
contains must be combined with nearly 26-4 of the 29°3 of car- 
bonic acid, leaving 2°9 to combine with 3:74 of lime, a quan- 
tity of carbonic acid which exceeds but little the requisite propor- 
tion, and which will not account for the excess in the analysis. 
Although in this ore from Yorkshire the quantity of oxide of 
manganese is extremely small, there are some of the ores in 
Wales which contain nearly 10 per cent. of it. 


ARTICLE XI. 


ANALYSES oF Books. 
Pharmacopaia Collegit Regalis Medicorum Londinensis, 1824. 


I nave been more than once called upon by what I conceived 
to be the imperfect attempts of the College of Physicians 
towards improving the Pharmacopeeia, to speak in terms of 
almost unqualified disapprobation of their proceedings; and 
although it is impossible to deny that many of the errors com- 
mitted in the edition of 1809 have been rectified on the present 
occasion ; yet it appears to me that the performance is ofa much 
less perfect description than the public have a right to demand; 
and { shall now briefly state the cases in which I think errors 
have been committed or suffered to remain uncorrected, premis- 
ing, however, that the College appear to have exercised a sound 
discretion in refusing to admit many of the novelties of the day 
into their Pharmacopceia. 

No alteration has been made by the College with respect to 
the arrangement of the Pharmacopeia, and if that which is 
adopted be not the most scientific or perfect that might have 
been selected, it does not, that I am aware of, include any very 
marked inconsistence, and it was, therefore, most prudent to 
suffer it to remain without any alteration. 

The College have introduced into the Materia Medica, 
Acidum Aceticum fortius, which is explained to be Acidum 
Aceticum é ligno destillatum ;. its specific gravity is stated to be 
1:046, and 100 grains of it are said to decompose 87 grains of 
crystallized subcarbonate of soda. The introduction of a pure 
acid is an improvement. I have not examined any of exactly 
this strength, but admitting that 100 grs. decompose 87 of crys- 
tallized subcarbonate of soda, it must be very nearly six times as 
strong as good distilled vinegar, now called acidum aceticum dilu- 
tum. When properly prepared by the manufacturer, the stronger 
acetic acid procured by the decomposition of wood is much 
pleasanter than that derived from the mere distillation of vinegar ; 


< 


a Coat 7 
Seat + 


= 


1824.] Pharmacopeia Londinensis. 451 


and I think the College might advantageously have omitted the 
latter, using the former in all cases instead of it. Added to 
which acetic acid is scarcely a proper appellation for an acid 
containing so much mucilage, that acetates are with diffi- 
culty formed by using it. 

In the last Pharmacopeeia directions were introduced for the 
preparation of citric acid; these are still continued, although 
the acid is now also introduced into the materia medica; in 
the present Pharmacopeeia, a formula is also given for preparing 
tartaric acid, but by what I. presume to be an oversight this acid 
is not included in the Materia Medica, as it ought to have been 
for the same reasons that induced the placing of citric acid under 
that head. With respect to the tartaric acid, it may also be ob- 
served, that one-half of that which the bitartrate of potash con- 
tains is lost. The method directed is to saturate the excess of acid 
in the bitartrate by causing it to decompose carbonate oflime, and 
then the tartrate of lime formed is to be treated with sulphuric 
acid. As far as it goes this is well, but no notice whatever is 
taken of the remaining tartrate of potash, which the College 
should have directed either to be crystallized ; or to be decom- 
posed in the well-known manner by muriate of lime, this being a 
refuse product of more than one pharmaceutic preparation. 
With regard to benzoic acid, the College have adopted an 
improvement by restoring the process by sublimation, which 
they rejected from the Pharmacopeia in 1809. But the medi- 
cine is too unimportant to require any particular notice. In 
preparing muriatice acid, the College direct, as before, that its 
specific gravity should be 1-160; but they have now given the 
saturating power of crystallized carbonate of soda as a measure of 
its strength, instead of that of carbonate oflime, as formerly. I 
found that the acid procured by the College process had a speci- 
fic gravity of 1:1645, and as 100 parts of it decomposed almost 
exactly 44 of carbonate of lime, they would saturate the equiva- 
lent quantity of crystallized carbonate of soda, or 134 parts. 
The College say 124, and this, therefore, is probably almost 
correct with respect to acid of specific gravity 1°160 as directed. 

No alteration has been made in the process for preparing 
nitric acid; but with regard to the standard for ascertaining its 
saturating power, that, as in the case of muriatic acid, is changed 
from carbonate of lime to subcarbonate of soda; and although it 
is stated with great precision that 100 grains saturate 212 of crys- 
tallized subcarbonate of soda, (the quantity by calculation being 
only half a grain more,) I am yet of opinion that the method of 
using carbonate of lime is the best, for reasons which Dr. Wollas- 
ton has stated; the fact, however, is, that neither plan is at all 
needful when the specific gravity is stated. With, however, the 
near approach to accuracy which the College have now made, 
there can be no objection to the statement. I cannot con- 
ceive why the College persist re popu that the nitric acid 

26 


452 Analyses of Books. (June, 


obtained by the first part of the process which they direct, 
should be redistilled with an additional quantity of nitre. The 
acid is as pure as possible, and has the solvent power and 
specific gravity which they attribute to the rectified acid; and 
by omitting the redistillation, time, trouble, expense, waste, and 
a disagreeable operation, are avoided, without losing even the 
shadow of an advantage. 

The directions for preparing liquor ammoniz, as far as the 
proportions of the ingredients are concerned, remain unchanged, 
and so also does the quantity of the fluid to be distilled from 
them; but it is now directed that the temperature of the re- 
ceiver should not exceed 50 degrees. Now one of two things 
must happen; the strength of the product is either increased 
by this alteration, or it is not. If it be unattended with ad- 
vantage, the only remark required is obvious :—why make the 
alteration? If, on the other hand, the strength of the solution 
is increased as one might expect, why is its specific gravity, 
and consequently its strength, stated to be similar to what it 
was in the last Pharmacopeeia? The specific gravity was there 
fixed at 0:960, and it remains the same, although we are now 
directed to keep the receiver cooled to 50° for the obvious 
purpose of rendering it more powerful. 

The method of preparing potasse acetas is altered, but I much 
question whether any improvement has been introduced, except 
that of using pure acetic acid instead of distilled vinegar ; 
by this the inconveniences arising from the mucilage which the 
latter contained will certainly be obviated, and I have no doubt 
but a pure and white salt is at once procurable. In the late 
Pharmacopeeia, the directions were to boil the solution of ace- 
tate of potash to dryness, but now the solution is to be evapo- 
rated until a pellicle forms, and this being removed is to be 
preserved and dried, as acetate of potash. I have not tried this 
process, but if practicable, it must, I think, be tedious, and 
unattended with any advantage over the method of evaporation 
to dryness. , 

The next alteration which I shall notice is an unquestionable 
improvement—that of procuring carbonic acid from the decom- 
position of carbonate of lime tor the purpose of preparing car- 
bonate or rather bicarbonate of potash, instead of obtaining it 
as in the last Pharmacopeeia, (and even then in too small quan- 
tity,) from the decomposition of subcarbonate, or rather sesqui- 
carbonate of ammonia. But here my commendation must end ; 
for by a very obvious oversight, the College have directed the 
solution of carbonate (bicarbonate) of potash, to be evaporated 
for the formation of crystals, when there is not actually more 
than about one-fifth of the water present necessary for their 
solution. Indeed on account of the very strong solution of the 
subcarbonate (carbonate) of potash which the College direct for 
conversion into bicarbonate, I have but little doubt that the 


1824.] Pharmacopaia Londinensis. 453 


tubes which, on common occasions, would be used for conveying 
the gas, would soon be choked with crystals, and the whole 
apparatus would probably be blown to atoms. 

ith respect to sulphate of potash, the College would have 
acted economically in imitating the directions of the Edinburgh 
Pharmacopeeia, by saturating the excess of acid of the bisulphate, 
with lime instead of potash; by this the waste would have been 
avoided, of using a salt of greater value to obtain one of less. 
But as potasse sulphas is now also in the Materia Medica, 
the chemist may avail himself of those economical modes of 
operating which the College have too frequently neglected, and 
that without any attendant advantage. The same remarks will 
also apply to the preparation of sulphate of soda. 

The directions for preparing that important medicine, tarta- 
rized antimony, are most exceedingly and unequivocally improv- 
ed: tiere is indeed nothing new in the process, but it is simple 
and effectual; whereas the method which has given place to it 
was the worst, considering that it really was practicable, that 
ever was devised. The College have now directed the use of 
the glass of antimony, but I think that the proportion ordered 
is rather too small to convert the whole of the tartar into tartar- 
ized antimony. 

The preparation which I shall next notice is the vinum anti- 
monii tartarizati. In those preparations in which wine was 
formerly employed, the College have now directed very dilute 
spirit to be used, still retaining, however, with unquestionable 
impropriety, the appellation of vinwm. In the present instance, 
I am not aware that the change has been either beneficial 
or otherwise; but I shall presently notice a preparation in 
which the alteration has been decidedly hurtful, because the 
College, without seeming to have been aware of the fact, have 
much weakened the medicine. Added to this, dilute spirit of 
very different degrees of strength is now used instead of wine, 
which must, | think, have been more uniform in its power. 

Among metallic preparations a place has been given to subni- 
trate of bismuth. The process, which is extremely simple, I 
have not examined ; but even if the metal or acid should either 
of them be in excess, the precipitate will at any rate be obtained 
without difficulty. 

With respect to the preparations of iron, there have been 
some alterations which are to be considered as amendments; 
but I am apprehensive that the good which has been done is 
more than counterbalanced by the omission of improvements, or 
the commission of errors. 

Ferrum ammoniatum is so weak a preparation as, perhaps, 
scarcely to be worthy of notice ; the process for obtaining it has 
been altered ; it could scarcely have been rendered worse, and 
yet [ do not think it has been improved. In the late Pharma- 
copeeia this preparation was directed to be formed by subliming 


454 Analyses of Books. [JuNE, 


a mixture of muriate of ammonia and subcarbonate of iron ; the 
consequence of which was, that until the carbonic had combined 
with a considerable portion of the ammonia of the muriate, 
and formed carbonate of ammonia, no ferrum ammoniatum could 
be obtained, and then only after considerable waste. 

Instead of directing a mixture of muriate of ammonia and 
carbonate of iron to be subjected to sublimation, the College have 
now ordered the carbonate of iron to be mixed with muriatic 
acid, and the substance remaining after evaporation to dryness, 
to be mixed with muriate of ammonia, and then submited to 
sublimation. It so happens, however, that the muriatic acid 
dissolves scarcely more than one-third of the subcarbonate of 
iron; so that waste appears to be incurred. Indeed the better 
and more obvious process for procuring this medicine is simply to 
boil down a mixed solution of muriate of ammonia and permu- 
riate of iron to dryness. By this a preparation of uniform strength 
and unquestionable efficacy would be obtained ; and those prac« 
titioners would be gratified who are of opinion that muriate of 
ammonia is a useful adjunct to permuriate of iron, 

In preparing the ferri subcarbonas, the College still continue 
the wasteful process of directing nearly one-half more sulphate 
of iron to be used than the subcarbonate of soda is capable of 
decomposing. No excuse can be offered for this, since it had 
been poinied out for correction. Six parts of subcarbonate of 
soda only are directed to be used with eight parts of sulphate of 
iron, of which they can decompose only about 5:4 parts. It is 
indeed true that sulphate of iron is a cheap material, but the 
chemist should have the opportunity of using it to the best 
advantage, and errors of this description furnish those who are 
inclined to neglect the directions of the College in other 
respects with too plausible a pretext for so doing. 

Ferrum tartarizatum, the preparation next to be noticed, has 
been much improved by the alterations which the College have 
introduced. Instead of ordering the whole mass to be dried, 
and which contained a considerable quantity of iron unacted 
upon, the soluble portion only is directed to be used, and the 
aqueous solution of it evaporated to dryness constitutes ferrum 
tartarizatum. There is, however, one part of the process now 
introduced which is perfectly useless—lI allude to the directions 
for boiling the metal in the solution of tartarized iron towards the 
end of the process. No effect can surely be hoped to be pro- 
duced by ebullition for fifteen minutes, after twenty days’ expo- 
sure to the air have ceased to cause any action. 

Vinum ferri still retains its title, although deprived of any just 
claim to it by the substitution of dilute spirit for wine ; I was at 
one time apprehensive indeed that it would contain neither wine 
nor iron. ‘The directions for preparing it are to form tartarized 
iron with considerable excess of tartar; this being probably 
intended to supply the slight acidity which wine usually pos- 


1824.] Pharmacopeia Londinensis. 455 


sesses, and to which its solvent power is owing. The quantity 
of iron directed to be used appears to me to be almost exactly 
such as, ifit were all dissolved, would render the medicine of such 
a degree of strength, as I found it actually to possess when pre- 
pared with sherry wine ; namely, 22 grains of peroxide of iron in 
a pint; the College order 60 grains of iron to be converted into 
tartarized iron, and the compound formed to be dissolved in 60 
ounces of dilute spirit; and as 60 grains of iron are convertible 
into about 85 grains of peroxide, and as 60 ounces would contain 
this quantity, a pint, or 16 ounces, would hold about 22°6 grains 
in solution. 

It happens, however, unfortunately, that three causes conspire 
to prevent this medicine from possessing the strength of the 
former ; first, the whoie of the iron is not dissolved by the super- 
tartrate of potash ; secondly, a part of that which is dissolved is 
rendered insoluble by the process of drying ; and lastly, a portion 
of what the water dissolves is immediately precipitated by the 
spirit, and the quantity is so very considerable that the vinum 
ferri now contains only 16 grains of peroxide in a pint instead of 
22 as formerly. In this preparation, therefore, merely for want 
of experiment, and by taking that for granted which did not 
happen to be true, the strength has been reduced to about two- 
thirds that which it formerly possessed, and no notice what- 
ever is of course taken of the change. 

In preparing calomel, the College have introduced what 
is certainly a very considerable improvement ; namely, form- 
ing it by one sublimation, instead of first preparing corrosive 
sublimate, and then triturating that with an additional portion of 
mercury, and subliming again ; the present process consists in 
mixing bipersulphate of mercury with mercury and common 
salt, and subjecting the mixture to sublimation; the sublimed 
calomel is then to be reduced to powder, and washed with a 
solution of muriate of ammonia, in order, I presume, the more 
readily to dissolve any corrosive sublimate which may have been 
formed ; this, perhaps, might have been spared, for corrosive 
sublimate is sufficiently soluble in water to admit of its sepa- 
ration from calomel during the process of elutriation. If, 
however, no corrosive sublimate be actually found with the ca- 
lomel, the manufacturer may use the same solution of muriate 
of ammonia repeatedly, and if, on the other hand, any be dis- 
solved, it may be converted into hydrargyrum precipitatum 
album. 

In comparing, however, the processes for procuring corrosive 
sublimate and calomel, a strange disregard of proportions has 
occurred ; in order to convert 24 parts of mercury into corrosive 
sublimate, the College direct the use of 30 parts of sulphuric acid 
and 48 of common salt; while in preparing calomel, 48 parts of 
mereury are to be treated with 30 ounces of sulphuric acid, and 
only 18 of common salt. Now it must be granted upon any 


456 Analyses of Books. (Junz, 


theory that 24 parts of mercury will require exactly as much 
common salt to convert them into corrosive sublimate as to 
convert twice the weight of mercury into calomel, and yet 48 
parts of common salt are ordered for the production of an effect 
im one case, while an equal effect is to be produced in the other 
by 18 parts ; the fact is, that the 48 parts are much in excess, 
as I pointed out long since; 49 parts of sulphuric acid cannot 
decompose more than 60 parts of common salt ; but in preparing 
corrosive sublimate, after about 12 parts of the 30 of sulphuric 
acid directed to be boiled with the mercury are decomposed by 
oxidating it, the remaining 18 must be supposed capable of 
decomposing 48 of common salt; it is, therefore, evident that 
about 26 out of 48 of salt are wasted. Why the quantity was 
not diminished as to be more in agreement with the directions 
for preparing calomel, I cannot discover. 

The preparations of lead do not call for any particular obser- 
vation, excepting, that as the sulphate of copper, soda, and 
potash, are introduced into the materia medica, no reason can 
possibly exist why the acetate of lead should not also have 
been ; it is perfectly well prepared for the purposes of 
the arts, and the acetic acid of which it is made not being sub- 
ject to any duty, it may be purchased at so much cheaper a rate 
than that at which it can be prepared, the formula is therefore 
useless ; it may also be observed, that the acidum aceticum fortius 
diluted with water would have answered the purpose of making 
the liquor plumbt subacetatis. 

Oxide of zinc formerly prepared by combustion is now directed 
to be formed by decomposing the sulphate of zinc with ammonia. 
I have not examined the preparation ; there is a slight difficulty 
attending the use of the caustic alkalies in precipitating oxide 
of zinc, which is, that if accidentally added in excess, they 
redissolve the precipitate at first formed. On this account I 
prefer carbonate of soda or potash, which I recommended some 
years since for this purpose. The advantage of the new mode of 
preparation is, I think, considerable, as it prevents the presence’ 
of any minute portions of metallic zinc which were apt to render 
the oimtment of zinc gritty. 

It appears to me that the College ought to have been more 
consistent in their directions. | have already shown some 
instances of their deficiency in this respect, and the spirits of 
ammonia afford additional proofs of want of attention. In the 
Pharmacopeeia of 1787,the spiritus ammonie and spiritus ammo- 
nie aromaticus are similar in strength, varying only in the 
aromatics which the latter contained ; but in the present Phar- 
macopeeia, and indeed in the last, as I pointed out, the 
proportions of spirit, muriate of ammonia, and carbonate of 
potash, are extremely different. In preparing the spiritus 
ammonie, 32 parts of muriate of ammonia ure directed to 
be decomposed by 48 of subcarbonate of potash, a quantity 


1824.) | Pharmacopaia Londinensis. 457 


which is too small by about three-fourths of a part; in mak- 
ing the spiritus ammonize aromaticus, the proportions are 32 
of muriate and 384 parts of subcarbonate, but as 48°75 of the 
latter are requisite, it is evident that 6-8 parts of the former 
escape decomposition, and are wasted. The spirit of the simple 
preparation is rectified, whereas that of the aromatic spirit of 
ammonia consists of two parts of rectified and one of water. 
Now this quantity of water, although useless, would have been 
of little consequence in the simple spirit, because in using it for 
the spiritus ammonie fcetidus (the only purpose to which it is 
applied), the water would remain in the retort; but it is of 
importance that the aromatic spirit should contain as little water 
as possible that in preparing the tincture of guaiacum, the solu- 
tion of the resin may not be prevented. 

With regard also to the proportion of ammonia in these pre- 
parations, it will be seen that the difference is enormous: 24 
fluid ounces of the simple spirit contain the carbonate of ammo- 
nia obtained by decomposing nearly 32 drachms of the muriate, 
while an equal quantity of the aromatic spirit contains the car- 
bonate procured by decomposing rather less than 8 drachms of 
the muriate of ammonia. It is indeed true that 10 drachms are 
directed to be employed ; but by the obvious and unaccountable 
inconsistency of using only 12 instead of 15 drachms of subcar- 
bonate of potash, one-fifth of the muriate of ammonia, and even 
rather more, escapes decomposition as already noticed. 

The method of preparing the spiritus ammoniz feetidus is 
extremely wasteful, and more so even than that of spiritus ammo- 
nie ; of the 28 parts of spirit employed in the latter preparation, 
4 are wasted ; and in using the remaining 24 to prepare the fetid 
spirit, 6 more are thrown away ; consequently out of the 28 parts 
of rectified spirit originally made use of, only 18 are eventually 
employed. 

In closing my remarks upon this work, it must be fairly 
admitted, especially with respect to tartarized antimony, calomel, 
and some other preparations, that the College have removed 
much of the objectionable matter of the Pharmacopeeia of 1809, 
and of the editio altera which followed it ; but there is yet, for 
the reasons which I have now stated, much that appears to re- 
quire acorrecting hand. I will only add, that it is greatly to be 
lamented that a national Pharmacopeeia should not be formed 
by the union of the Colleges, by which greater facilities would 
be afforded to physicians in the various parts of the kingdom, 
in describing their modes of treating different diseases.— 


(Edit. 


458 Proceedings of Philosophical Societies. [JuNeE, 


ArTICLE XII. 


« Proceedings of Philosophical Societies. 


ROYAL SOCIETY. 


April 8 (addendum)—Sir Francis Shuckburgh, Bart. was ad- 
mitted a Fellow of the Society. 

April 29.—E. H. Lushington, Esq. and the Rev. Dr. E. 
Maltby, were admitted Fellows of the Society ; and the name 
of Woodbine Parish, Esq. ordered to be inserted in its printed 
lists, he being unable to attend for admission. Among the 

resents received was a portrait of Mr. Smeaton, the celebrated 
Engineer, bequeathed to the Society by his daughter, Mrs. 
ixon, 

A Letter from Dr. Tiarks to Dr. T. L. Young, For. Sec. RS., as 
Secretary of the Board of Longitude, was read: it related chiefly 
to observations made on the longitude of various places in En- 
gland in 1822 and 1823. 

May 6.—Lieut. Henry Forster, RN. was elected into the 
Society, and being on the eve of departure in the new expedi- 
tion under Capt. Parry, was immediately admitted a Fellow. 

The reading was commenced of a paper “ On Univaives ; by 
Charles Collier, Esq. Staff Surgeon:” communicated by Sir 
James Mac Gregor, Bart. FRS, 

May 13—The Earl of Orford, the Rev. Dr. Goodenough, 
Philip Barker Webb, Esq. and John Gage, Esq. were respect- 
ively admitted Fellows of the Society. 

he reading of Mr. Collier’s paper was concluded: anda 

paper was read, “On the Variation of the Rates of Chrono- 

meters with the Density of the Atmosphere; by George Har- 

vee ae FRSE:” communicated by Davies Gilbert, Esq. 
* 


May 20.—The Rev. Baden Powell was admitted a Fellow of 
the Society. 

A Letter from Professor Berzelius to the President was read, 
in which he describes the results of various chemical researches 
in which he has recently been engaged ; and several memoirs 
on which accompanied the letter. The first memoir relates to 
the analysis of the Carlsbad waters; which we have already 
noticed in the Annals, N. 8. vol. v. p. 396. The next contains 
researches on the combinations of acetic acid with oxide of 
copper: in this, Prof. Berzelius says, he has pointed out the 
errors in the analyses of these salts into which Mr. Phillips and 
other chemists have fallen. The fourth memoir relates to 
experiments on the compounds of oxide of uranium, in which 


* See our last number, p. 392, 


1824.] Royal Society. 459 


Prof. B. has confirmed the results obtained by M. Arfwedson, 
and also Mr. Phillips’s discovery of phosphoric acid in the 
uranite. He has examined the uranite of Autun, and also that 
of Cornwall: finding the former to be a phosphate of uranium 
and lime, and the latter a phosphate of uranium and copper; 
the number of atoms of water being the same in both. The 
third contains an examination of a mineral in an old collection 
at Stockholm, labelled ‘ from Mendip, near Churchhill, in So- 
mersetshire.’ This substance consists of 1 atom of chloride 
of lead, and 2 atoms of oxide of lead, and also contains car- 
bonate and molybdate of lead. Itis distinct from the murio- 
‘carbonate of Matlock. The fifth memoir relates to the combi- 
nations of fluoric acid. A portion of this memoir now printing 
describes a method by which the author has succeeded in ob- 
taining the base of silica in an insulated state. It consists in 
acting by potassium on dry silicated fluate of potash, by which 
means a mixture of various substances is obtained, which yields 
hydroguret of silicon by being well washed with water: and 
when that substance is heated in a crucible the hydrogen is 
burned off, and the silicon obtained pure. Prof. B. then pro- 
ceeds to give the results of various experiments upon this 
substance ; among which are the following. It is obtained in 
various states of aggregation, and its combustibility varies ac- 
cordingly, it much resembling carbon in this respect : as usually 
obtained it is combustible when ignited in atmospheric air and 
in oxygen gas; but in its dentsest state it may become incan- 
descent in the air without burning. It is very difficult to effect 
its complete combustion: 200 parts of silicon unite to 208 of 
oxygen to become silica. Jt will not burn when heated with 
nitre, but is brought into combustion by carbonate of potash; 
a curious circumstance which the author attributes to certain 
relations of affinities. Silicon burns when ignited in chlorine, 
forming with it a transparent colourless fluid, having the smell 
of cyanogen. It is combustible in vapour of sulphur, producing 
a grey sulphuret, but cannot in this case be completely burned. 
Prof. B. next describes the results of the same mode of 
decomposition as applied to ittria, glucina, and zirconia ; giving 
the chemical habitudes of zirconium, which can be obtained 
in larger quantities than the bases of the former earths. He 
then states that he has used the term fluate instead of fluoride 
throughout this letter, not because he thinks the President’s 
ingenious theory on the subject less probable than his own 
(though he has not been able, by his own experiments, to de- 
termine which is the true one); but because, as he was writing 
in a language foreign to him, he wished to employ the plainest 
terms: and concludes by requesting Sir Humphry to lay the 
above results before the Royal Society. 
The reading was commenced, of a paper “ On some new 
henomena effected by magnetic influence, by J. H. Abrahams,” 
of Sheffield : communicated by Mr, Tooke, FRS. 


460 Proceedi ngs of Philosophical Societies. [JuNE, 


GEOLOGICAL SOCIETY. 


March 5.—The paper entitled “ Outline of the Geology of 
the South of Russia,” by the Honourable William T. H. Fox, 
Strangways, MGS. was concluded. 

The term Steppe is applied to vast tracts of country in the 
E. and SE. of Europe. It is neither a heath, nor a moor, nor 
a down ; wold would give the best idea of it in English, and it 
is given by the Russians to any waste land which is neither 
mountainous nor wooded. The Russian Steppes are bounded 
on the west by the Carpathian chain of Transylvania and the 
Banat of Temesvar; on the 8. by Mount Hemus, the Tauric 
Chersonese, and Caucasus; on the E. by the Oural mountains 
to beyond the Caspian Sea and the sea of Aral; vaguely to the 
N. by aline from the mouth of the Kama to the Dniesters on 
the frontiers of Podolia and Kherson. Their length is about 
2000 miles, breadth 900. The soil is similar throughout; the 
geological structure very different. 

- A trough or basin stretching across from Perecop to the 
Caspian, and thence beyond the sea of Aral, forms a natural 
division of the Steppe into the N. and S. High Steppe ; this 
trough or basin Pallas and others well describe as the low sandy 
saline steppe ; the two former as the high rich calcareous and 
granitic steppe. . } ey 

~ The Northern High Steppe admits of five divisions : 

1. Steppe of red marl, salt, and gypsum, lying on both sides 
the Volga above the reach of Samara. 2. Steppe of Saubof 
and the middle Volga, from Samara to Tzaritzin; its northern 
part consists of the white central limestone, its southern of 
sandstone which connects it with the steppe of the Don. 
3. Northern calcareous steppe of the Don is composed of sand- 
stone to between Cherkask and the month of the Donetz; here 
commences an immense tract of a peculiar modern shelly lime- 
stone ; the steppe limestone probably extends across the Ukraine, 
and is connected with the calc. gross. of Volhynia and Gallicia. 
4. S. and SE. of this occurs the primitive or granitic steppe, a 
singular instance of a flat tabular, granitic country connected, 
according to Pallas, with the primitive range of the Carpathians, 
passing the Dniester at Doubosar, and traversing Moldavia. 
5. Middle calcareous steppe, of steppe limestone separated by 
a sandstone from the preceding ; this is a prodigious mass ex- 
tending throughout Wallachia, Bessarabia, the south of Mol- 
davia, and Government of Kherson. The trough or basin be- 
fore alluded to forms the steppe of the old sea, which involves 
the singular problem of the connexion and extension of the 
Caspian and Black Seas. To the south of this lies the southern 
calcareous steppe, comprehending the Crimea, and stretching 
to the foot of Caucasus, is composed of steppe limestone resting 
on calc. gross. The high steppes, from the occurrence of ma- 
rine plants and other causes, have been supposed to have once 


SS Se 


1824.) _ Geological Society. 461 


formed a vast sea; but their height, in some places 700 feet 
above the Black Sea, and 1000 feet above the Caspian, pre- 
cludes the possibility of this. 

The author, after enumerating and describing the series of 
the above-mentioned beds, and their accompanying fossils, 
concludes with remarks on the probable extension of the Cas- 

ian Sea, and the sea of Aral, and their connexion with the 
Black Sea by means of the low steppe. 

A letter from Mrs. Maria Graham to Henry Warburton, Esq. 
VPGS. was read, giving an account of the effects of the Earth- 
quakes which visited the coast of Chili in 1822 and 1823. 

The first shock by which the towns of Valparaiso, Melipilla 
and Quillota were nearly destroyed, was felt at a quarter past 
11 o’clock on the evening of Tuesday the 19th of November, 
1822; and from this time continual shocks were felt daily until 
the 18th of January, when the authoress ceased to reside in 
Chili. These shocks are said not to have terminated wholly so 
late as September last. The sensation experienced during the 
more violent shocks was that of the earth, being suddenly heaved 
up in a direction from N. to S. and then falling down again, a 
transverse motion being now and then felt. On the 19th of 
November a general tremour was felt, and a sound heard like 
that of vapour bursting out, similar to the tremour and sound 
which the authoress observed while standing on the cone of 
Vesuvius during the jets of fire at the eruption of 1818. In all 
the alluvial valleys in the neighbourhood of Quintero, 30 miles 
N. of Valparaiso, quantities of water and sand were forced up, 
which covered the plain of Vina a la Mar with cones or hillocks 
four feet high. 

The promontory of Quintero, consisting of granite covered 
by sandy soil, was cracked in various directions down to the 
sea; and the cracks occasioned by the earthquake in the gra- 
nite on the beach were parallel to the more ancient rents in the 
same rock, 

On the morning of the 20th, after the first earthquake the 
whole line of coast from N. to 8S. to the distance of 100 miles 
was found to have been raised out of the sea; the elevation at 
Quintero being about four feet, that at Valparaiso about three 
feet, beds of oysters aud muscles, adhering to the rock on 
which they grew, being seen lying dry on the beach, 

Similar lines of beach with shells are found parallel to the 
coast to the height of 50 feet above the sea, which probably 
have been occasioned by earthquakes which have in former 
years visited Chili. 

The earthquake of the 19th was felt along the coast to the 
distance of 1400 miles at least. 

March !9, 1824.—A paper entitled “ Sketch of the Geology 
of New South Wales and sic Diemen’s Land,” by the Rev.’ 
H. Scott, was read in part. 


462 Proceedings of Philosophical Societies. [Junn, 


April 2.—The paper entitled “Sketch of the Geology of New 
South Wales and Van Diemen’s Land,” by the Rev. T. H. 
Scott, was concluded. : 

The coast of New Holland, from Cape Howe to Port Stephens, 
including Botany Bay, Port Jackson, &c. as examined by Mr. 
Scott, consists of an uninterrupted series of the coal measures. 
At Illasvarro, or the five islands, a seam of coal is found at the 
surface. Between Broken-Bay and Port Hunter, a horizontal 
seam of coal is bared by the action of the sea on the cliffs. 
Very good coal is worked at Newcastle on Hunter’s river, 37 
yards from the surface, 3-feet 1-inch thick ; it is intersected by 
trap dykes in some places ; and vegetable remains of a large 
leaved fern, thought by the people to be an Euculyptus, are 
picked up at the base of the Chiff. Limestone alternates with 
the sandstone, and iron ore occurs. The wells at Sydney, 
being not more than 30 feet deep, the water is not good; one 
well, sunk 82 feet to a great mass of sandstone, gives excellent 
water. From Paramatta the coal measures continue, and are 
broken by trap dykes at the Nepean to Emuford ; where the 
ascent of the blue mountains commences, near the summit of 
which, the coal measures rest on the old red sandstone. 
The escarpment of this rock on the east side presents the as- 
si of a perpendicular wall, at the top of which the old red 

andstone is found in contact with primitive rocks : these occur 
in the vale of Cleuyd and Clareneers hilly range ; where the 
Macquarrie rises, and, after a north-east course of 300 miles, ter- 
minates in a vast swamp. Returning westward, porphyritic 
rocks and clay slate accompany the primitive rocks near 
Bathurst and the Sidmouth range, to lake George and the 
Cookbundoon river, which continue to the cow pastures, where 
the coal measures of the colony again appear. 

The geology of the Island of Van Diemen’s Land is con- 
formable to that of the continent of New Holland. Both 
Hobart-town and George-town are upon the coal formation. 
Between the former and Elizabeth-town, a limestone full of 
shells is found, probably of the oolite series, and the same rock 
occurs near George-town on an island in the Tamar. In the 
middle of the island at Bagdad, a rock, which answers to the 
description of the millstone grit, and salt, are found on the river 
Macquarrie. To the east and the west of the inhabited tract 
between the two towns, high mountains and elevated primitive 
ridges are alone discoverable, so that the island probably con- 
tains little other fertile soil to tempt future emigration when 
this space shall have peopled, which is not the case in New 
South Wales. 

A letter was read on a section obtained in sinking a well at 
Streatham, by Mr. J. S. Yeats, communicated by G. H. Brown, 


sq, 
A well having been sunk at Streatham to the depth of 286 feet, 


Sa ee es 


oS we fe ee ee 


4 
by 


1824.] Geological Society. 463 


the greatest depth which has been pierced in that part of the 
country, the following section was exhibited. From the depth of 
2 feet to 29 feet, stiff reddish brown clay; from thence to 35 
feet, clays with septaria ; from thence to the depth of 180 feet, 

blue clay, in which, in from 70 to 100 feet, were found various 
shells and fragments of bituminous wood with iron pyrites ; 
from 200 feet to the depth of 230 feet, blue clay, sometimes 
sandy, in which numerous shells and bituminous wood occurred ; 
at 230 feet, round black pebbles of flint like those of Blackheath 
were found, this appearing to be the point of junction between 
the London and plastic clays; next a bed of sand, and after- 
wards various coloured clays, were pierced; at the depth of 
270 feet, and continuing to 285 feet, sand and sandy clays 
occur, the greater part of which is full of green earth exactly 
resembling that of the oyster bed at Reading. The paper was 
accompanied by specimens of each of these strata. 

A letter was read from Alexander Gordon, Esq. to D. 
Gordon, Esq. of Abergeldie, describing three successive forests 
of fir imbedded in a peat moss ; accompanied by specimens. 

The moss of Auidguissack in Aberdeenshire, Scotland, presents 
an inclined plane of rather uneven surface, and varies in depth 
from 18 inches to 10 feet from the lower part of the hill to the 
river. 

Upon digging up the ground in two different parts of the 
moss, large roots of Scotch fir trees were found about one foot 
below the ordinary average level of the moss. Below the bot- 
toms of these roots there is a stratum of about a foot and a half 
of moss below which other roots or trunks appeared, and on 
digging still further down (about six or seven feet below the or+ 
dinary level of the moss), a third set of roots and truncated 
stems of trees were discovered. 

It appeared to Mr. Gordon impossible that these roots could 
have supported different trees, all growing at the same time, for 
the distinct ramifications of these (horizontally like Scotch firs 
at the present day), are bedded in moss perpendicularly above 
each other. 

April 23.—A paper was read, entitled ‘“‘ Some Observations 
on the Lakes of Canada, their Shores, Communications, &c. by 
Lieut. Portlock, RE.” 

In this memoir the author describes the various nature of the 
shore, of Lakes Huron, Michigan, Erie, and the other lakes of 
Canada, and annexes a plan, in which a tabular view is pre- 
sented of the comparative level of these lakes and their com- 
munications with each other. At the falls of Niagara, he ob- 
serves, the upper stratum is a firm compact limestone resting on 
strata of a very schistose nature. It is not by erosion of the 
surface that the falls are made to recede, but the waters, after 
falling 150 feet, strike the bottom, and are reduced to foam ; 
they are then driven up into the air far above the rock whence 


464 Proceedings of Philosophical Societies. [JuNE, 


they had descended: this penetrating foam acts on the lower 
argillaceous strata, till the overhanging rock is undermined. 
Lieut. Portlock remarks that there has been a gradual fall in the 
level of the lakes at Canada. He also offers some considera- 
tions on the proximity of the sources of several rivers which 
flow in opposite directions. 

May 7.—A paper on the Geology of the Ponza Islands in 
the Mediterranean, by G. P. Scrope, Esq., MGS. was read in 

art. ; 

A letter was read from Thomas Borfield, Esq., MGS. accom- 
panied by a collection of bones and horns of the Deer, and 
bones of Man and other animals, found in a cleft of the rock at 
a quarry at Hincks’ Bay (near the Old Park iron-works) in the 
parish of Dawley and county of Salop. Their adhesion when 
applied to the tongue showed that the animal gelatine was 
nearly gone, which does not take place till after a long period of 
inhumation. 


METEOROLOGICAL SOCIETY. 


Feb. 11.—Dr. Burney communicated the results of a Meteo- 
rological Journal, for January 1824, kept at his observatory at 
Gosport, Hants. 

A note was read, on some curious effects of the Radiation of 
Heat; by Luke Howard, Esq. FRS. and M. Met. Soc. 

The reading was commenced of a “‘ Memoir on the Varia- 
tions of the Reflective, Refractive,sand Dispersive Powers of the 
Atmosphere, &c.; by T. Forster, MB. FLS. and M. Met. Soc.” 

March 10.—The reading of Dr. Forster’s memoir was con- 
cluded. It relates to certain branches of the subject of 
atmospheric refraction, belonging to the province of meteoro- 
logy, which the author states to have been particularly neg- 
lected: these are, the variation in the refractive, dispersive, and 
reflective powers of the atmosphere, resulting from the diffu- 
sion therein of different modifications of cloud, which are 
themselves affected by local circumstances, and which vary 
greatly at different times; and the effects of that variation, on 
the colour of the light transmitted by the planets and fixed 
stars, and on the declination of the latter. After some general 
remarks on reflection, refraction, and prismatic dispersion, the 
author proceeds to consider the subjects just mentioned in three 
sections. In the first, ‘On the variation in the refractive 
power of the atmosphere at different times of the night and day, 
and on different occasions and seasons,’ he ascribes that varia- 
tion, principally, to the quantity and nature of the aqueous 
vapour diffused in the air: and he supports this opinion by 
various observations on the planets and stars, made at different 
times and seasons. In observing the planets and brightest stars 
through prismatic glasses, he found that the spectrum was less 
oblongated, whilst the red colour was more distinctly apparent, 


1824.) Meteorological Society. 465 


at the period of the vapour point, than at almost any other time of 
the same nights. On other occasions, at the same period of even- 
ing, the violet and in general the colours of the most refrangi- 
ble rays were most conspicuous, and the spectrum was more 
oblongated than ordinarily. Dr. F. at length ascertained that 
the greater prevalence of the red in the spectrum, uniformly 
accompanied that state of the atmosphere, when the cirrostratus 
diffused itself, after sun-set; whilst the more oblongated spec- 
trum, with the violet, and most refrangible colours, attended an 
atmosphere, in which the condensing vapours assumed the form 
of stratus. He infers from these and other observations, that 
the changes in the qualities of the diffused vapour in the air 
must produce great variation in the atmospherical refraction. 
In the second section of his memoir, he suggests that local cir- 
cumstances may produce great variation in the mean refractive 
power of the atmosphere at different places ; and that the dis- 
cordances in the places assigned to the fixed stars in different 
catalogues of them may have resulted from such variation. 
In the third section, entitled ‘ Of Varieties in the Composition 
and Nature of the Light of different Stars, considered as still 
further varying the Etfects of Atmospherical Refraction, Reflec- 
tion, and Dispersion,’ Dr. Forster details a number of minute 
observations upon those varieties ; proceeds to inquire into their 
causes ; and concludes with an account of some experiments on 
the decomposition of the light of the moon, the planets, and 
certain fixed stars. : 

A paper by Dr. Forster was also read, “ On the great de 
pression of Temperature which occurred in January, 1520.” 

The remarkable depression of temperature related in this 
paper, took place at Hartfield, in Sussex, to the neighbourhood 
of which place it appeared to be confined, during the period 
between sun-set on January 14, and midnight of January 15, 
1820. At 10 p.m. on the I4th an out-door Fahrenheit’s ther- 
mometer exposed to the NE. was at zero, and at 11 o’clock it 
indicated — 5°. Sometime between the hours of 1] and 8 a.m. 
on the 15th, it sunk to—10°, as shewn by a Six’s Thermometer. 
lt thence gradually rose, until at midnight on the 15th, it 
attained the elevation of +23. A thermometer exposed to the 
NW. indicated 1° higher in each observation. During this 
period of excessive cold, the air was calm and clear, a few ill- 
defined cumuli only were seen on the 15th; the snow which 
had fallen on the 13th lay on the ground. Dr. F. received oily 
one notice of a distant observation, made at Canterbury, where | 
a Thermometer in-doors indicated 0°; which was also the tem- 
perature in-doors at Hatfield, on the morning of the 15th. 

Dr. Burney communicated the Results of his Meteorological 
Journal, for Bebra: 

April 14.—A note was read on certain Phenomena of the 

New Series, vou. vil. 2H 


466 Proceedings of Philosophical Societies. [JuNE, 


late Cold Weather, &c.; by Luke Howard, Esq. FRS. M. Met. 
Soc. ; and Dr. Burney communicated the Results of his Journal 
for March. 

May 12.—Dr. Burney communicated the Results of his Jour- 
nal for April ; and the following paper was read : 

“An Account of the principal Phenomena of Igneous Meteors 
which were observed in the Year 1823; forming part of a 
Review of the Progress of Meteorological Science during that 
Period: with remarks on the Characters of certain Meteorites.” 
By E. W. Brayley, Jun., ALS. and M. Met. Soc. In this paper 
the author first describes from various authorities, the Fire-balls 
which were observed, respectively, on Jan. 26, 1823, at Gosport ; 
on the 23d of May, at Kiel in Denmark; and on the 20th of 
August, at Ragusa. The latter, being contemporaneous with an 
earthquake at the same place, gives occasion for an inquiry how 
far the appearance of Igneous Meteors may be considered as an 
attendant phenomenon of earthquakes : several meteors of this 
kind, it is observed, were seen in the province of Cutch, at the 
time of the extensive earthquake in India in 1819, the most 
violent motion of which was experienced in that province and 
its vicinity; and two Fire-balls appeared, one at Zante, and 
the other at Cephalonia, on the day after the earthquake that 
desolated the former island in 1820: other instances of this 
connexion are likewise adduced. Mr. Brayley then pro- 
ceeds to an examination of the phenomena attending the fail of 
several Meteorites, at Nobleborough, in the State of Maine, in 
North America, on the 7th of August last. He next points out 
a remarkable affinity, in mineralogical characters, subsisting 
between these meteorites, and those which fell, respectively, at 
Loutolox in Finland, in 1822, at Jonzac, in France, in 1819, 
and at Juvenas, in the same country, in 1821; several speci- 
mens of the latter being laid before the Society, for the purpose 
of illustration. This affinity partly consists in the strong re- 
semblance which they all bear to certain products of volcanos ; 
whilst the meteorites of several other descents connect them, 
by a gradual transition, with those whose characters are more 
peculiar. From these and other circumstances, in conjunction 
with that of the frequent presence of Olivine in meteorites, the 
author infers, that the agencies which give rise to volcanic 
phenomena, whatever these may be, and however exerted in 
this case, are probably concerned in the production of Igneous 
Meteors and the bodies which descend from them. He con- 
cludes by recommending the investigation of this curious sub- 
ject to the members of the Society; promising to lay before 
them, after the recess, the results of some further researches 
upon it. 

The Society then adjourned, over the Summer recess, to meet 
again on Wednesday the 13th of October next. 


1824.) Medical Society. 467 


MEDICAL SOCIETY OF LONDON. 


The fifty-first Anniversary Meeting of this Society was 
holden at the London Coffee House, Ludgate Hill, William 
Shearman, MD. President, in the chair. 

The Officers and Council for the ensuing year are as follow : 
President : William Shearman, MD.—Vice-Presidents: Henry 
Clutterbuck, MD.; Henry James Cholmely, MD.; Sir Astley 
Paston Cooper, Bart. FRS., and Thomas. Callaway, Esq.---. 
Treasurer: John Andree, Esq.— Librarian: Dayid Uwins, MD. 
—Secretaries: T.J. Pettigrew, Esq., and Thomas Callaway, 
Esq.—Secretary for Foreign Correspondence: Robley Dungli- 
son, MD.—The other members of the Council: Drs. Walsh- 
man, Hancock, J. G. Smith, Blicke, Blegborough, Hopkinson, 
Stewart, Ley, Darling, Haslam, Pierce, Cox, and Burne; 
Messrs. Sutcliffe, Drysdale, Wender, K. Johnson, Dunlap, 
Kingdon, Ward, Thomas Clarke, Burton Brown, Lake, Ash- 
well, Edwards, Handey, E. Leese, Skair, Cordell, Bell, Ellerby, 
Amesbury, T. Bryant, and Burrows.—Registrar: James Field, 
Esq.—The Fellow elected to deliver the annual oration, in 
March 1825, Eusebius Arthur Lloyd, Esq. 

The President informed the meeting that the time allotted 
for the perusal of the dissertations offered for the Fothergillian 
medal, during the last year, having been unexpectedly short- 
ened, the Society had not yet adjudicated the prize medal : 
this however would be done forthwith, and the Medal would 
be presented to the successful candidate at a Special General 
Meeting of the Society to be holden on the 3rd of May, at 
eight o’clock in the evening. 

The annual oration was then delivered by Dr. John Gordon 
Smith, the Ex-Vice President; the subject was, ‘‘ The Duties 
and Perplexities of Medical Men as professional Witnesses in 
Courts of Justice.” 

A numerous body of Fellows and their friends, amounting in 
all to 86, afterwards dined together in the great room of the 
Tavern, the President being in the chair; and the remainder 
of the day was marked by harmony and conviviality. 

Conditions of the Fothergillian Medal—In conformity with 
the will of the late Anthony Fothergill, MD. FRS., the Society 
resolved to give, annually, to the author of the best Essay on 
a subject propcsed by them, a gold medal, value 20 guineas, 
called the Fothergillian Medal; for which the learned of all 
countries are invited as candidates. 

1. Each dissertation must be delivered to the Registrar, in 
the Latin or English language, on or before the first day of 
December. 

2. With each dissertation must be delivered a sealed packet, 
with some motto or device onthe outside, and within the author’s 

2u 2 


468 Scientific Intelligence. (June, 


name and designation, that the Society may know how to ad- 
dress the successful candidate. 

3. No paper in the hand-writing of the author will be re- 
ceived ; and if the author of any paper shall either directly or 
indirectly discover himself to the Committee of papers, or to 
any member thereof, such paper will be excluded from all com- 
petition for the medal. 

4, All the dissertations, the successful one excepted, will, if 
desired, be returned with the sealed packets unopened. 

5. The prize medal will be presented to the successful can- 
didate, or his representative, at the Anniversary Meeting of the 
Society in March 1825. 

The subject of the Dissertation to be offered for the Prize 
Medal for March 1825, is, “ The Pathology and Treatment of 
Periodical Asthma.” 


ArTICLE XIV, 


SCIENTIFIC INTELLIGENCE, AND NOTICES OF SUBJECTS 
CONNECTED WITH SCIENCE, 


I. Hydriodate of Potash. 


M. Taddei proposes the following method of preparing this salt : 
dissolve iodine in spirit of wine, and pour repeatedly a solution 
of hydrosulphuret of potash into the solution of iodine; the fluid 
becomes turbid, and changes from the blackest brown to a ches- 
nut colour, and this, diminishing in intensity, gradually becomes flesh 
coloured, and afterwards milk white. At this period the conversion 
of the iodine into hydriodic acid is effected; and if the liquid does not 
become turbid on the addition of a few drops of hydrosulphuret of 
potash, the operation may be regarded as complete. After standing 
a few minutes, the precipitated sulphur is to be separated by decan- 
tation or by the filter, the mixture is then to be distilled to procure 
the alcohol employed, and the residuum is to be evaporated to dry- 
ness in an open vessel to obtain the hydriodate of potash.—(Giornale 
di Fisica, etc. 1823.) 


II. Action of Hydrocyanic Acid on Vegetable Life. 


M. Becker has made many experiments, from which it results that 
hydrocyanic acid, prepared according to Vauquelin’s process, destroys 
vegetables nearly in the same manner that it does animals. Seeds 
soaked in this acid are equally killed by it, and lose their germinat- 
ing power. Delicate plants are killed sooner than those which are 
stronger.—(Journal de Pharmacie, p. 174, April 1824.) 


Ill. Diurnal Variation of the Barometer. 


The Edinburgh Philosophical Journal, conducted by Dr. Brewster ; 
the Journal of the Royal Institution of Great Britain, conducted by 
Professor Brande; the Bulletin Universal des Sciences et de |’Indus- 


1824]. - Scientific Intelligence. 469 


trie, published under the direction of Baron Ferassac, have announced 
that, according to a discovery made by Col. Wright, the mercury of 
the barometer, near the equator, rises and falls twice in 24 hours, 
with so much regularity, that this instrument may almost be employed 
as a measure of time. 

We beg those readers of the Annales de Chimie, &c. who think 
that we communicate this discovery rather late, to remark that Goden, 
Bouguer, and Laundamire, made the same discovery nearly a ceu- 
tury since; that since these academicians all travellers to the equi- 
noxial regions have been engaged on the subject; that M. Humboldt, 
in 1807, published a very excellent work for the express purpose of 
making known the true hours of the wazima and minima, and the ex- 
tent of the oscillation (vide Geograph. des Plantes) ; that Lamanon in 
the expedition under de Lapeyrouse, Horner in that of Krusenstern, 
&c. &c. undertook similar researches ; that by means of the averages, 
Duc-Lachapelle, at Montauban, M. Ramond, at Clermont-Ferrand, 
the astronomers of the observatory at Paris, M. Marqué Victor, at 
Toulouse, &c. &c. have proved that this diurnal variation exists also 
in our climates: lastly, that we never omit, in our accounts of meteo- 
rological observations for the year, to give the amount of the daily 
falling of the barometer, from nine o’clock in the morning till three 
in the afternoon, and also of rising, which is evident between the last- 
mentioned time, and nine at night—(Annales de Chimie et de Phy- 
sique, t. xxv. p. 334.) 


IV. On the Cause of the Rotatory Motion of Camphor in Water. 


(To the Editor of ‘the Annals of Philosophy.) 
SIR, Cambridge, May 7, 1824. 


The curious phenomenon of rotatory motion, which a particle of 
camphor presents when placed on the surface of water, | have fre- 
quently seen mentioned, but no where that 1am aware of is there a cause 
assigned, In making a few experiments upon the subject, I was led 
to discover what I conceive to be the cause. It is a known Jaw in 
hydrostatics that if a body floats on a fluid, the centre of gravity of 
the body and of the fluid displaced, must, when the body is at rest, be 
in the same vertical line; otherwise a rotatory motion is given to the 
body. In confirmation of this, if a perfectly smooth and square par- 
ticle of camphor be placed on the surface of water, the camphor re- 
mains at rest. But if an uneven particle be made use of, then the 
centre of gravity of the body and of the water displaced are not in 
the same vertical line, and a rotatory motion is produced, 

1 remain your’s, &c. E. A. 


V. On the Transmission of Electricity through other Fluids. 
DEAR SIR, Charing Cross, May 12, 1824. 
Your number for April contains a letter from Mr. Woodward on 
the transmission of electricity through other fluids; allow me through 
the same channel to inform Mr. W. that the experiment of firing loose 
gunpowder by passing the charge of a Leyden phial through tubes 
filled with water, and also on the conducting power of alcohol, ether, 
and acids, were made by a Mr. Lewthwaite, in May 1821, and are 
published in the eleventh volume of the Institution Journal: it was 


470 New Scientific Books. [JuNE, 


from reading this letter that I became acquainted with the experi- 
ment, and have been pursuing it under a variety of forms, and with 
liquids of different conducting powers, which experiments, when well 
matured, shall be submitted to your consideration. Would suggest 
that Mr. W. should repeat the experiment with the water tube. I am 
disposed to think Mr. W. is in error, when he says the intensity 
(measured we are to suppose by a pith hall electrometer), indicated 
was from 10° to 15°. 1 have repeated the experiment several times, 
but always found a quart jar required an intensity of 65° to 70°; per- 
haps the pith ball attached to the electrometer was rather large ; it 
would have been more satisfactory if the degree at which the jar 
spontaneously discharged itself had also been stated. 
Yours, truly, T. Js 


VI. Volatility of Salts of Strychnia, 


M. Ferrari gives the following process for this purpose: solutions 
of salts of strychnia slightly acid when exposed to a heat of 212°, so 
as to be concentrated, then become volatile and the salt evaporates. 
This property has been remarked in the sulphate, nitrate, muriate, and 
acetate, and is believed to belong to all the salts. It has been re- 
marked by M. Collaud and others, that the sulphate of quina is also 
volatile, and M. Ferrari, on repeating the experiments with the mu- 
riate and nitrate of quino, found it also to happen with them. The 
solutions on being heated in a tinned copper vessel, gave out vapours 
which, when breathed, were found to be highly bitter. The salts vary 
in the extent of this property, and it is also affected by the degree of 
acidity, and of concentration of the solution.—(Gior. de Fisica, vi. 
460.) 

VII. Crystallization of the Sub-carbonate of Potash. 


M. Fabroni describes the following process for the crystallization of 
this salt. Make a solution of pearlash in water, and evaporate it 
until of specific gravity 1:57. Allow it to cool, when all extraneous 
salts will be deposited ; separate the fluid and again concentrate it 
until of specific grav. above 1‘6. The fluid will now be of a light 
green colour, and strong alkaline odour; place it in deep vessels, as 
glass jars for instance, and the sub-carbonate will soon crystallize in 
Jong rhomboidal white lamin, situated vertically and parallel to each 
other; one extremity will touch the bottom of the vessel, and the 
other be attached to a saline crust on the surface of the liquid. When 
cold the mother liquor will be found of specific grav. 1°6, but if further 
consecrated and again cooled, more crystals will be obtained; and 
thismay be continued until the whole has been crystallized.— (Ibid,45.) 


ArTICLE XIV. 
NEW SCIENTIFIC BOOKS. 


PREPARING FOR PUBLICATION. 
Mr. Harris Nicolas has in the press, nearly ready for publication, a 
small work intended for the use of Antiquaries, Historians, and the 
Legal Profession, containing Tables that show exactly the year of our 


1824.} New Patents. a7 


Lord corresponding with the year of the reign of each Monarch; an 
Alphabetical and Chronological Calendar of Saints’? Days, and other 
Festivals, on which ancient records are dated ; Tables showing on what 
day of the month and week each moveable Feast occurred ; an account 
of the Provincial Registries of Wills, with a list of the Parishes in each 
Diocese subject to Peculiar Jurisdictions; and a full description of 
the Contents of all the Works published by the Commission for the 
Preservation of the Public Records; with other useful matter. 

Shortly will be published, in one volume, Svo. An Excursion 
through the United States and Canada, in the Years 1822 and 1823; 
by an English Gentleman. 

No. II. of the Zoological Journal, conducted by Messrs. Bell, Chil- 
dren, and Sowerby, will appear on the 15th of June. 


JUST PUBLISHED. 


Wade’s Observations on Fever. 8vo. 4s. 

Coddington’s Optics. Svo. 8s. 

Boyle’s Advice to Settlers in Tropical Climates. 18mo. 2s. 6d. 

Plumbe on Diseases of the Skin, coloured Plates. Svo. 14s. 

Wollaston’s Fasciculus Astronomicus, 1800. 4to. Wl. 

Key on the Prostrate Gland. 4to. 12s. 

Mementoes, Classical and Historical, of a Tour in France, Switzer- 
land, and Italy. 2vols. 8vo. 11. 4s. 

Prior’s Life of Burke, with Portrait, &c. S8vo. 16s. 

Hayward on Horticulture. 8vo. 12s. 

Bell on the Spine and Thigh Bone. 16s. 

Travers on the Eye. Third Edition. 17. 5s. 

Bostock’s Elementary System of Physiology. 8vo. 15s, 

Kitchener’s Economy of the Eyes. 12mo. 7s. 


ARTICLE XV. 
NEW PATENTS. 


J. H. Petelpiere, Chalton-street, Somers Town, engineer, for his 
engine or machine for making the following articles from one piece of 
leather without any seam or sewing whatever ; that is to say, all kinds 
of shoes and slippers, gloves, caps, and hats, cartouch boxes, scab- 
bards and sheaths for swords, bayonets, and knives——March 20. 

J. Rogers, Marlborough, Wilts, surveyor, for his improved instrument 
for determining or ascertaining the cubic contents of standing timber. 
—March 20. 

J. Lingford, Nottingham, lace machine manufacturer, for certain 
improvements upon machines now in use for the purpose of making 
that kind of lace commonly known by the name of bobbin-net or 
Buckinghamshire lace net.—March 20. 

J. Heathcoat, Tiverton, Devonshire, lace manufacturer, for certain 
improvements in machinery used in spinning cotton, wool, or silk,— 
March 20. 

H. Berry, Abchurch-lane, London, merchant, for improvements on 
a machine for more readily producing light,~—March 20. 


472 New Putents. . [JuNE, 


J. J. Stainmare, Belmont distillery, Wandsworth-road, Vauxhall, 
for improvements in the process of distilling —March 20. 

C. Demeny, Fenchurch-street, merchant, for an apparatus for pro- 
ducing gas from oil and other oleaginous substances, of burning such 
gas for the purpose of affording light, and of replacing the gas con- 
sumed.—March 22. 

N. Goodsell, Leigh-street, Burton Crescent, engineer, for a certain 
machine for breaking, scutching, and preparing flax and hemp for use, 
upon an improved method, and threshing out the seed thereof, and 
also for shelling clover and other seeds.—March 25. 

E. Jordan, Norwich, engineer, for improvements in the construction 
of water-closets.—March 27, 

J. Spencer, Belper, Derbyshire, nail manufacturer, for improvements 
in furnaces for the preparation of iron or steel, and for manufacturing 
nails and other articles from the said materials.— April 7. 

J. Schofield, Rastrick, Halifax, Yorkshire, manufacturer, for certain 
improvements in the manufacture of cloth or fabric which he denomi- 
nates British cashmere.—April 7. 

T. Ryalls, Sheffield, warehouseman, for his apparatus for shaving, 
which he denominates “ the useful and elegant facilitator.”—A pril 8. 

S. Hall, Basford, Nottinghamshire, cotton manufacturer, for his 
improved steam-engine.—April 8. 

J. Tulloch, Savage Gardens, gentleman, for improvements in the 
machinery to be employed for sawing and grooving marble and other 
stone, or in producing grooves or mouldings thereon.—April 12. 

H. P. Bevet, Devizes, Wiltshire, ironmonger, for his improvement 
in the construction of cranks, such as are used for bells and other pur- 
poses.—April 14. 

W. By, Joy Cottage, Ivory-place, Brighton, stationer and booksel- 
ler, for his method or apparatus for the preservation of books and 
covers.—April 14. 

J. Gunby, New Kent Road, Surry, sword and gun manufacturer, 
for his improvement in the manufacturing of cases for knives, scissars, 
and other articles.— April 14. 

D. Gordon, of Basinghall-street, for certain improvements in porta- 
ble gas lamps.— April 14. 

J. Beven, Manchester, dealer in cotton twist and weft, for his appa- 
ratus for dressing varicus kinds of cotton, flaxen, woollen, or silk manu- 
factures.—April 14. 

YT. Gettien, Henry-street, Pentonville, for his improvements in the 
machinery of making metallic rollers, pipes, cylinders, and certain 
other articles.—April 15. 

D. Tonge, Liverpool, ship-owner, for an improved method of reefing 
sails.—April 15. 

A. Dallas, Northumberland-court, Holborn, engineer, for his 
machine to pick and dress stones of various descriptions, particularly 
granite stone.—April 27. 

J. Turner, Birmingham, brass and iron founder, for his machine for 
crimping, plaiting, and goffering linen, muslins, frills, and other arti- 
cles.—-April 27. : 

G. Vaughan, Sheffield, Yorkshire, for his improvements on steam- 
engines, by which means power will be gained, and expense saved.— 
May 1. 


<> 


—- 


1824.) ‘ Mr, Howard’s Meteorological Journal. 473 


ArTICLE XVI. 


METEOROLOGICAL TABLE. 


emma 
BAROMETER, THERMOMETER, 
1824, | Wind. Max. Min. Max. | Min. Rain. 
4th Mon 
April 1} W 29:90 20:29 44 35 — Ad 
2 W| 30°17 29°52 43 28 — 02 
3) N 30°39 30°17 50 30 —_ 
E| 30°56 30°39 49 28 —_ 
E| 30°56 $0°55 52 30 — 
E| 30°55 | 30°30 51 34 — — 
W)| 30°38 30°29 A5 33 — 02 
E| 30°38 30°21 54 38 _ 
E| 30°21 29°53 50 38 — 13 
W! 29°59 29°54 44 30 —_ 12 
W) 29°57 29°55 45 30 —_— Ol 
W| 29°80 29°57 52 30 — 
W|. 30°00 29°80 55 30 ¢ “85 thet 
W! 30°00 29:99 52 25 _ — 
E 29°99 29°50 56 38 — 06 
E 29°60 29°46 A4, 40 —_ 80 
FE] 30°18 29:60 48 34 — 20 
ISIN. E! 30°39 30°18 58 28 —_ 
E} 30:43 30°36 59 33 _ 
E 30°43 | 30:23 65 34, — 
E 30°23 30°02 62 51 _ 04 
W| 30:07 | 29:69 65 48 — 09 
23} Var. | 30°09 | 29°65 | 64 | 45 ‘95 | 08 
24IN W| 30:27 30:09 60 39 — 
W!| 30°24 29°85 64 51 — 
E} 29-92 29°85 62 43 —_— — 
W | 30°04 29°92 63 52 — 
W| 30°04 29°92 60 50 — 02 
Wi 29°92 29°79 73 51 — 
W| 30°05 Q9: 79 66 50 ‘96 01 
30°56 "| 99: 29° oh 73 | 25 2-76 | 2°05 _ 


The observations i in each line of the table apply to a period of twenty-four hours, 
beginning at 9 A.M. on the day indicated in the first column. A dash denotes that 
the result is included in the next following observation. 


474 Mr, Howard’s Meteorological Journal. [Junx, 1824. 


REMARKS. 


Fourth Month.—1. Fine till five, p.m.: wind cold; night rainy. 2. Some rain 
this morning: cloudy: windy. 3—6. Fine. 17. Cloudy. 8,9. Fine. 10. Rainy 
morning: stormy day: showers of hail and rain: gusty. 11. The ground covered 
with snow this morning: snow showers, 12. Cloudy. 13. Fine: two or three trifling 
showers. 14. Ditto. 15, Fine: very high wind during the night: a large solar halo, 
slightly tinged with prismatic colours, which lasted about half an hour just before sunset. 
16. Very rainy morning, with high wind. 17. Rainy morning: wet till four, p. m. 
18. Very fine morning. 19—22. Fine. 23. Showery morning: overcast: windy. 
24, 25. Fine. 26, Very much overcast this morning: showers, p.m. 27. Overcast. 
28. Showers. 29, 30, Fine. 


RESULTS. 


Winds: N, 13 E,4; SW, 5; SE, 2; W,2; NW, 8; NE, 7; Var. I. 
Barometer: Mean height 


For/the aibnth as? 006s PSs Soh ec eosin aes slowoa s GU: DNONMCHER, 
For the lunar period, ending the 20th......6....+++-- 30°025 
For 13 days, ending the 10th (moon north) .......... 30°088 
For 14 days, ending the 24th (moon south) .......-.. 29°955 


Thermometer: Mean height 


For the month........ Sb ob dwididd o's de cctteuaaecovea sts | Saree 
For the lunar period. ............ cccosevevccccccccs 40216 
For 30 days, the sun in Aries . .......seeeeeeeereee 39-966 


Evaporation... ....++ eee cn cctces cence raccsccccccctee seeseccecsess 2°76 ins 


Raioresasrcesetsevetereeereverret ss. os cece evecee eeoeeesesase 2°05 


Laboratory, Stratford, Fifth Month, 22, 1824. R. HOWARD. 


s,s 


oo 


IN 


EX. 


—_—- 


CID gas, carbonic, conversion of, to 
a fluid form, 95. 

—muriatic, conversion of, to 

a liquid, 92. 

sulphurous, conversion of, 

to a fluid form, 93. 

boracic and tartaric, on their 

atomic weights, 245. 

hydrocyanic, its action on vege- 

table life, 468. 

muriatic, on the existence of, 
in the stomachs of animals, 147. : 

Acetate of barytes, crystalline form of, 
365. 


—_—— 


— 


— lime, phosphorescence of, 235, 

—_— strontia, crystalline form of, 
288. 

Albite, composition of, 51. 

Alkalies, vegetable, composition of, ac- 
cording to different authorities, 314, 
Ammonia and magnesia, sulphate of, 

crystalline form of, 117. 

Ammoniacal gas, conversion of, to a fluid 
form, 97. 

Analcime, analysis of, 353. 

Ancient bronze, composition of, 73. 

Annual mean, results of meteorological 
registers, 281, 

Anorthite, composition of, 58. 

Arago, M. account of volcanos at present 
in activity, 201. 

Arfwedson, M. examination of oxidum 
manganico-manganicum, 267—on ura- 
nium, 253—on the decomposition of 
metallic sulphates by hydrogen gas, 
329—analysis of cinnamon-stone, 343 
—Brazilian chrysoberyl, 345—boracite 
from Luneburg—borax, 347. 

Arsenic, on the detection of small quan- 
tities of, 131. 

— tests of, on the methods of em- 
ploying of, 30. 

Astronomical observations, 29, 121, 197, 
278, 328, 406, 

Autun, uranite of, analysis of, 235. 


B. 


Babingtonite, a new mineral, account of, 
275, 

Baily, Mr. F. on the ensuing opposition 
of Mars, 107, 


Barlow, Mr. observations and experi- 
ments on the daily variation of the hori- 
zontal and dipping needle, &c, 183. 

Barometers, mountain, account of ims 
provements in, 313. ) 

-————— variation, diurnal, 468. 

ae acetate of, crystalline form of, 
365. 


— nitrate of, crystalline form of, 
21. 

——-— uraniate, analysis of, 261. 

Teeaufoy, Col. on the stability of floating 
bodies, 81—astronomical observations 
by, 29, 121, 197, 278, 328, 406—mean 
results of the meteorological register 
kept by him, 251. 

Becker, M. experiments on the action of 
hydrocyanic acid on vegetable life, 468. 

Berger, Dr. reply to Mr. Henslow’s ac- 
count of the Isle of Man, 367—re- 
marks on his reply, 407. 

Berthier, M. on the preparation of oxide 
of nickel, 395. 

Berzelius, Prof. notices of his paper on 
silicon, &c. 459. 

Biggs, Mr. on the expansion of gases, 

33. 

Birds, migration of, on the, 66. 

Bismuth, sulphuret, analysis of, 355. 

Bitartrate of potash, crystalline form of, 
161, 

Blue, prussian, patent for dyeing with, 
396. 

Books, new, scientific, account of, 77, 
156, 237, 317, 470. 

Boracic acid, atomic weight of, 248, 

Boracite, analysis of, 347. 

Borax, analysis of, 347, 

Bowdich, Mr. accountof the death of, 317. 

Brain, on the comparative anatomy of the 
human, 65, 

Brande, Mr. analysis of cinchonia, quina, 
and morphia, 315, 

Brinkley, Dr. notice of his paper on the 
north polar distances of the principal 
fixed stars, 149. 

British Museum and Edinburgh Review, 
76. 

Bronze, ancient, on the composition of, 
73. 

Brooke, Mr. on the crystalline form of 
artificial salts, 20, 117, 161, 287, 364 
—account of childrenite, somervillite, 


476 Index. 


and kupferschaum, 317—on a new 
mineral called nuttallite, 366. 

Brucia, composition of, 47. 

Buckland, Rev. W. notice of his paper on 
the megalosaurus, 391. 

Bucklandite, description of, 134. 


C. 


Cafein, composition of, 47. 

Camphor, rotatory motion of, cause of, 
AGY. 

Carbon, perchloride of, crystalline form 

. of, 364. 

Caves, on animal remains found in, 198. 

Cheltenham water, exauiination of, 393. 

Children, Mr. examination of babington- 
ite, 277. 

Childrenite, a new mineral, account of, 
316, 

Chronometer, rate of, varies with the 
density of the medium, 392. 

Chrysoberyl, analysis of, 345. 

Ciachonia, composition of, 47, 314. 

Cinnamon-stone, analysis of, 343. 

Cleaylandite, on the occurrence of, in the 

. older rocks, 118. 

—— from Finland, analysis of, 


155. 
Cobalt, muriate of, crystalline form of, 
364. 


sulphate, analysis of, 337. 

Colebrooke, Major, notice of his paper on 
the structure of St. Jago, 310, 

Coliseum at Rome, on the, 448. . 

Colours, Egyptian, examination of some, 
115. 

Conybeare, Rey. W. D. on the skeleton 
of the plesiosaurus, 311. 

Cooper, Mr. on the composition of the 
ancient ruby glass, !05—on an improved 
apparatus for the analysis of organic 
products, 170—on the composition of 
the nitrates of strontia, 289. 

Copper and potash, sulphate of, crystalline 

_ form of, 118. 

pytites, analysis of, 353. 

sulphate of, as a test for arsenic, 


38. 

Crauhall, Mr. account of instruments for- 
merly used in blasting in the lead mines, 
&c. 214, 

Crichton, Mr. on expansions, and particu- 
larly of those of glass and mercury, 
241. 

Crystalline form of artificial salts, on the, 
20, 117, 161, 287, 364. 

Cumberland, Mr. on animal remains 
found in caves, 198. 

Cumming, Prof. on a new thermoelectric 


instrument, 46— apparatus for produc- 
ing instantaneous light, 365. 
Cyanogen, conversicn of, to a fluid form, 


D. 


Daniell, J. F. reply to some observations 
on his Essay upon the Constitution ef 
the Atmosphere, 26. 

Davy, Dr. notice of his paper in a case of 
pneumato-thorax, 383. 

— Sir H. on a new phenomenon of 
electromagnetism, 22—sketch of his 
discourse before the Royal Society on 
St. Andrew’s day, 69—notice of his pa- 
per on a mode of preventing the corro- 
sion of copper sheathing by sea water, 
229. 

De la Beche, Mr. analysis of his Selection 
of the Geological Memoirs, contained 
in the Annales des Mines, &c. 371. 

Dillwyn, Mr. on fossil shells, 177. 

Deebcreiner’s eudiomcter, 316. 

Dumas and Pelietier, on organic salifiable 
bases, 47. 


‘ 


E. 


Edinburgh Review, and British Museum, 
76. 
reviewer, hints to, 285. 
Egyptian colours, examination of some, 
115. 
Electrical fluid, effects of transmitting it 
through other fluids, 283. 
Electricity and phosphorescence, connex- 
ion between them, 395. 
transmission of, through fluids, 
469. 
Electromagnetism, ona new phenomenon 
of, 22. 
Emetin, composition of, 47. 
Equivalent numbers, table of, 185. 
Evaporation, theory of, addition to Mr. 
Herapath’s, 349. 
Euchlorine, conversion of, to a fluid form, 
95. 
Eudiometer, Deberciner’s, 316. 
Expansion of gases, on the, 133. 
of glass and mercury, on the, 
241. 


Ee 


Fabtoni, on the crystallization of subcar- 
bonate of potash, 470. 

Faraday, Mr. on the liquefaction of chlo- 
rine and ether gases, 89—on Chelten- 
ham water, 393. 

Felspar, on, 50. 

Fleming, Dr. on a submarine forest in the 
Frith of Tay, &c. 290, ‘ 


EK SS ee 


Index. 


Fluid, electric, effects of transmitting it 
through other fluids, 283. 

Fluids, transmission of electricity through, 
469. 

Fluorine, on some compounds of, 100. 

Force, cohesive, of iron, effect of heat in 
lessening the, 75. 

Forest, submarine, on the Frith of Tay, 
290. 

Forms, primary, of sulphur, 234. 

Fossil shells, on, 177. 

Fraser, Mr. notice of his paper on the 
geology of Persia, 309. 

Frith of Tay, account of a submarine 
forest in the, 290, 

Fulminate of silver, analysis of, 413. 


G. 


Gases, on the expansion of, 133. 

—— liquefaction of, 89. 

Gay-Lussac and Liebig, MM. analysis of 
fulminate of silver, 413. 

Germany, salt springs of, table of, 109. 

Giddy, Mr. table of comparative temper- 
ature of Pisa and Penzance, 200— 
mean results of the meteorological re- 
gister kept by him, 280. 

Glass, ancient ruby, on the composition 
of, 105. 

—and mercury, on the expansions 
of, 241. 

Gough, Mr. notice of his paper on the 
winds of the north of England, 312. 
Gray, Mr. reply to the observations upon 

his Elements of Pharmacy, 123. 
Guilding, Rev. L.. notice of his paper on 
iguana tuberculata, 233, 
Greenwich catalogue, corrections ia right 
ascension of 37 stars of the, 37. 
observations, on the correctness 


of, 76. 
H. 


Harvey, Mr. on the variation of the rate of 
the chronometer, in media of different 
densities, 342. 

Heart, on the active power of dilatation 
of, 181, 

Henslow, Mr observations on his account 
of the Isle of Man, %7—yremarks on 

~Dr. Berger's reply, 3007. 

Herapath, Mr. addition to his theory of 
evaporation, 349, 

Herschel, Mr. notice of his paper on the 
phenomena exhibited by mercury, &c. 
when placed within the influence of an 
electric current, &e. 133. 

Hints to an Edinburgh reviewer, 285. 

Hodgson, Rey. Mr. on the ancient tin 
trade, as described by him, 175. 


477 


Home, Sir E. notice of his paper on the 
comparative anatomy of the human 
brain, 65—notice of his paper on the 
walrus and seal, 307. 

Howard, Mr. meteorological tables kept 
at Stratford, 79, 158, 239, 319, 399, 
473. 

Hydrate of strontia, crystalline form of, 
287. 

Hydrocyanic acid, its action on vegetable 
life, 468. 

Hydrogen, sulphuretted, 
arsenic, 31. 

gas, sulphuretted, conversion 
of, to a fluid form, 94, 

Hydriodate of potash, method of preparing, 
468. 


as a test for 


I. 


Instruments used for the purpose of 
blasting in the lead mines, &c. 214. 
Tron, effect of heat in lessening the cohe- 

sive force of, 75. 
ore, argillaceous, analysis of, 448. 
—— smelting of, supposed origin of, 72, 
Jenner, Dr. notice of his paper on the mi- 
gration of birds, 66. 
Jupiter, inquiry respecting the utility of 
observing the eclipses of his third and 
fourth satellites, 217. 


K. 


Keferstein, M. table of the salt springs in 
Germany, and the neighbouring coun- 
tries, 109, 

Kent, S. L. and W. Phillips, on the 
rocks of Mount Sorrel, 1. 

Kupferschaum, analysis of, 317. 


L. 


Labradorite, composition of, 56. 

Iaugier, M. analysis of the uranite of 
Autun, 235. 

Lead, nitrate of, erystalline form of, 21. 

uranite of, analysis of, 260, 

Levy, M. observations on M. Rose’s 
paper on felspar, albite, &c. 59—on 
forsterite, 62—on a new mineral called 
bucklandite, 134—on a new mineral 
called babingtonite, 875. 

Light and heat, solar, remarks on, 321, 
401, 

Lime, acetate of, phosphorescence of; 
235. 

Lines, dark and bright, traversing the 
spectrum, 154. 


478 Index. 


Tagen stone in Cornwall overturned, 
92. 

—-—rock, account of, 419, 

Lupulin, asa medicine, on, 29. 


M. 


Mac Leay, Mr. notice of his paper on the 
oistros of the Greeks, and the asilus of 
the Romans, 387. 

Manganese, oxides of, composition of, 
274. 

Mars, opposition of, on the, 107, 

Mercury, absorption of air by, 394. 

Meteorite, analysis of, 237. 

Meteorological tables kept at Stratford, 
79, 158, 239, 319. : 

registers for 1823, 279. 

Mill, Mr. on lupulin as a medicine, 29— 
phosphorescence of acetate of lime, 235, 

Moll and Van Beck, MM. account of their 
paper on sound, 384. 

Morphia, composition of, 47, 315. 

Motion, rotatory, of camphor, cause of, 
469. 

Mount Sorrel, on the rocks of, 1. 

Moyle, Mr. mean results of the meteoro- 
logical register kept by him, 279—on 
an improved clinometer, 122. 

Muriate of cobalt, crystalline form of, 
364, 

Muriatic acid, on the existence of, in the 
stomachs of animals, 147. 


N. 


Narcotin, composition of, 47. 

Newman, Mr. account of his improve- 
ments in mountain barometers, 313. 

Nickel and copper, sulphate of, crystal- 
line form of, 117. 

oxide of, preparation of, 395. 

Nitrate of barytes, crystalline form of, 21. 

lead, crystalline form of, 21. 

silver, as a test for arsenic, 38. 


ee crystalline form of, 161. 

strontia, crystalline form of, 
288—hydrou}, 288—composition of, 
289. 

Nitric acid and potash in Cheltenham 
water, 393, 

Numbers, equivalent, table of, 185. 

Nuttallite, a new mineral, description of, 
366, 


0. 


Observations, astronomical, 29, 121, 197, 
278, 328, 406. 

Oxide, nitrous, conversion of, to a fluid 
form, 96, 


Oxide of uranium, method of preparing, 
244—composition of, 258—yellow, 
composition of, 259. 

of manganese, composition of, 


274, 

Oxidum, manganico-manganicum, analy- 
sis of, 267. 

Organic products, improved apparatus for 
tha analysis of, 170, 


Ps 


Parhelia, account of, 75. 
oo and Fonblanque’s history of poisons, 
33. 

Patents, new, list of, 78, 157, 237, 318, 
AT}. 

Pelletier and Dumas, on organic salifia- 
ble bases, 47. 

Perchloride of carbon, crystalline form of, 
364, 

Pharmacopeia Collegii Regalis Medico- 
rum Londinensis, analysis of, 450. 

Phillips, Mr. R, on the methods of em- 
ploying the various tests of arsenic, 30 
—chemical examination of the skoro- 
dite, 99—remarks on Mr. Gray’s an- 
swer to his review of the Elements of 
Pharmacy, 128—analysis of the argil- 
laceous iron ore, 448. 

W. and S. L. Kent, on the 

rocks of Mount Sorrel, &c. 1. 

on a new locality of the 
skorodite, 97—on cleaylandite in the 
older rocks, 1]S—hints to an Edin- 
burgh reviewer, 285. 

Phosphorescence of acetate of lime, 235, 

—_— — and electricity, connexion 
between them, 395. 

Pianoforte wire, manufacture of, 156. 

Poisons, history of, 432. 

Potash, bitartrate of, crystalline form of, 
161. 


hydriodate of, method of prepar- 
ing, 468. ‘ 
subcarbonate of, crystallization of, 


A70. 

sulphate of, crystalline form of, 
20. 

tartrate of, crystalline form of, 
161. 


and nitric acid in Cheltenham 
water, 393. 

Powell, Mr. notice of his paper respecting 
the supposed heating effect beyond the 
red end of the spectrum, 148—remarks 
on solar light and heat, 321, 401. 

Prout, Dr. notice of his paper on the na- 
ture of the acid and saline matters ex- 
isting in the stomachs of animals, 147. 

Prussian blue, patent for dyeing with, 
396, 


aa 


Index. 


Pyrites from Orijarva, analysis of, 155. 
copper, analysis of, 355, 


Q. 


Quinina, composition of, 47, 314. 


R. 


Register, meteorological, 1823, 279. 

Remains, animal, found in caves, 198. 

Remarks upon Mr. Gray’s answer to the 
review of his Elements of Pharmacy, 
128, 

Rocks of Mount Sorrel, on the, 1. 

Rose, M. on felspar, albite, labradorite, 
and anorthite, 49—analysis of analcime, 
copper pyrites, and sulphuret of bis- 
muth, 353. 

Ruby glass, ancient, on the composition 
of, 105. 


Ss. 


Sabine, Capt. account of his paper on the 
comparison of the barometrical measure- 
ment of altitude with that of trigono- 
metry, 385. 

Salifiable bases, organic, on, 47. 

Salts, artificial, on the crystalline forms 
of, 20, 137, 161, 364. 

— of uranium, nature and composition 
of, 266. 

Scapolite, from Pargas, analysis of, 155. 

Scoresby, Mr. notice of his paper on the 
development of magnetical properties in 
iron and steel by percussion, 230, 

Shells, fossil, on, 177. 

Silver, nitrate of, as a test for arsenic, 38 
—crystalline form of, 161. 

fulminate of, analysis of, 413. 

Skerodite, locality, new one of, 97—ana- 
lysis of, 99. 

Smelting of iron, on the supposed origin 
of, 72. 

Smithson, Mr. on some compounds of 
fluorine, 100—examination of some 
Egyptian colours, 115. 

Society, Astronomical, proceedings of, 152, 
308, 389. 

Geological, proceedings of, 153, 

309, 391, 

Linnean, proceedings of, 150, 


386. 


Medical, proceedings of, 467. 
Medico-botanical, proceedings of, 
312, 391, 460. 

Meteorological, proceedings of, 
153, 311,464. = 
Royal, analysis of Transactions 
of, 62, 143. 


479 


Society, Royal, proceedings of, 65, 147, 
229, 305, 383, 456. 

Soda, sulphate of, crystalline form of, 21, 

Solar light and heat, 321, 401. 

Somervillite, a new mineral, account of, 
316. 

South, Mr. corrections in right ascension 
of 37 stars of the Greenwich catalogue, 
&c. 37, 136, 247—on the correctness 
of Greenwich observations, 76—inquiry 
into opinions respecting the utility of 
observations of the eclipses of Jupiter’s 
third and fourth satellites, 217, 

Spectrum, dark and bright lines traversing 
the, 154. . 

Springs, salt, of Germany, table of, 109. 

Stockton, Mr. mean results of the meteo~ 
rological register kept by him, 281. 

Strontia, acetate of, crystalline form of, 
288, 


— hydrate of, crystalline form of, 
287. 


— nitrate of, crystalline form of, 
288—anhydrous, 288—composition of, 
289. 

———- nitrate, anhydrous, crystalline 
form of, 288—hydrous, 288—compo- 
sition of, 289, 

Strychnia, composition of, 47. 

———— salts of, volatility of, 470. 

Subcarbonate of potash, crystallization of, 
470. 

Sulphate of ammonia and magnesia, crys- 
talline form of, 117. 

cobalt, analysis of, 337. 

copper, as a test for arsenic, 


38. 


nickel and copper, crystalline 
form of, 117. 

— soda, crystalline form of, 2]. 
potash, crystalline form of, 


20. 


potash and copper, crystalline 
form of, 118. 

— uranium and potash, analysis 
of, 262. 

Sulphur, primary forms of, 234. 

— compounds of, speculations and 
inquiries respecting, 444. 

Sulphuret of bismuth, analysis of, 355. 

zinc, analysis of, 337. 

Sulphuretted hydrogen, as a test for are 
senic, 31. 


T. 


Table of equivalent numbers, 185. 

— meteorological, kept at Stratford, 

719, 158, 239, 319, 399, 473. 

Taddei, M. on the preparation of hydrio« 
date of potash, 468, 

Tartari¢ acid, atomic weight of, 245, 


480 


Tartrate of potash, crystalline form of, 
161, 

Temperature, comparative, of Pisa and 
Penzance, table of, 200. 

Thermoelectric instrument, new one de- 
scribed, 46. 
Thomson, Dr. on the atomic weight of 
boracic and tartaric acids, 245. \ 
Tin trade, ancient, as described by Mr. 
Hodgson, on the, 175, 

Todd, Dr. notice of his paper on the lu- 
minous power of insects, 384. 

Traill, Dr. on the detection of small quan- 
tities of arsenic, 131. 

Transactions of the Royal Society, ana- 

__ lyses of, 62, 143, 227, 298. 


U and V. 


Variation, diurnal, of the barometer, 468. 

of the horizontal and dipping 
needle, 183. 

Vegetable alkalies, composition, according 
to different authorities, 314. 

Veratria, composition of, 47. 

Volcanos in activity, account of, 201. 

Underwood, Mr. on theColiseum at Rome, 
A48. 


Index. 


Uraniate of barytes, analysis of, 261. 
——~ lead, analysis of, 260. 


' Uranite from Autun, analysis of, 235. 


Uranium, on, 253. 

——- oxide of, method of preparin 
aed ey: 

— —— salts of, nature and composition 
of, 266. 


Ww. 


Walker, Mr. on some geometrical princi- 
ples connected with the trisection of an 
arc, 356. 

Williams, Dr. on the active power of di- 
latation of the heart, 151. 

Webster, Dr. analysis of a fragment of a 
metcor which fell in Maine, 236. 

Woodward, Mr. on the effects of transmit- 
ting electrical through other fluids, 28%. 

Wollaston, Dr. notice of his paper on the 
same decussation of the optic nerves, 
305. 


Z. 


Zinc, sulphuret of, analysis of, 337. 
Zoological club, proceeding of, 388. 


Printed by C. Baldwin, New Bridge-street, London. 


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