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E INTERNATIONAL SCIENTIFIC SERIES. 


VOLUME I. 


Sau y nAL Ne VAN A te \] 4 er 


THE 


INTERNATIONAL SCIENTIFIC SERIES. 


Each book complete in One Volume, 12mo, and bound in Cloth. 


1. THE FORMS OF WATER IN CLOUDS AND RIVERS, ICE AND GLA- 
CIERS. By J. Tynpatt, LL. D., F.R.S. With 35 Illustrations. $1.50. 
2. PHYSICS AND POLITICS; or, Thoughts on the Application of the Prin- 
ciples of ‘‘ Natural Selection’? and ‘Inheritance *’ to Political Society. 
By WALTER BAGEHOT. $1.50. 
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trations. $1.75. 
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LL.D. With 4 Illustrations. $1.50. 
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With 31 Illustrations. $2.00. 
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LL. D,, F.R.S. With 14 Illustrations. $1.50. 
: 8. ANIMAL LOCOMOTION ; or, Walking, Swimming, and Flying. By J.B. 
PETTIGREW, M. D., F. R.S8., etc. With 130 Illustrations. $1.75. 
9. RESPONSIBILITY IN MENTAL DISEASE. By Henry Maupstey, M.D., 
$1.50. 
10. THE SCIENCE OF LAW. By Professor SHELDON Amos. $1.75. 
11. ANIMAL MECHANISM: A Treatise on Terrestrial and Aérial Locomotion. 
By Professor E. J. MAREy, Coliege of France. With 117 Illustrations. $1.75. 
12. THE HISTORY OF THE CONFLICT BETWEEN RELIGION AND SCI- 
ENCE. By J. W. DRAPER, M.D., LL.D. $1.75 
13. THE DOCTRINE OF DESCENT AND DARWINISM. By Professor Oscar 
Scumipt, Strasburg University. With 26 Illustrations. $1.50. 


14. THE CHEMISTRY OF LIGHT AND PHOTOGRAPHY IN THEIR AP- 
PLICATION TO ART, SCIENCE, AND INDUSTRY. By Dr. HERMANN 
VocEL, Royal Industrial Academy of Berlin. With100Ilustrations. $2.00. 

15. FUNGI: Their Nature and Uses. By M. C. Cooke, M.A., LL.D. Edited by 
the Rey. M. J. Berkeley, M. A., F. L.S. With 109 Illustrations. $1.50. 

16. THE LIFE AND GROWTH OF LANGUAGE. By Professor Witi1am 
DwicHTt WHITNEY, Yale College. $1 50. 

17. MONEY AND THE MECHANISM OF EXCHANGE. By W. STANLEY 

JEVons, M.A., F. R.S. $1.75. 

18. THE NATURE OF LIGHT, with a General Account of Physical Optics. By 
Dr. EUGENE LOMMEL. With 188 Illustrations and a Table of Spectra in 
Colors. $2.00. 


19. 


21. 


27. 


30. 


31. 


% 


m & 


35. 


37. 


The International Scientific Series.—(Continued.) 


ANIMAL PARASITES AND MESSMATES. By Professor P. J. VAN BEN- 
- EDEN, University of Louvain. With 83 Illustrations. $1.50. 


. FERMENTATION. By Professor P. ScHuTzENBERGER. With 28 Illustra- 


tions. $1.50. 


THE FIVE SENSES OF MAN. By Professor JuLius BERNSTEIN, Univer- 
sity of Halle. With 91 Illustrations. $1.75. 


. THE THEORY OF SOUND IN ITS RELATION TO MUSIC. By Pro- 


fessor PIETRO BLASERNA, Royal University of Rome. With numerous 
Illustrations. $1.50. 


. STUDIES IN SPECTRUM ANALYSIS. By J. NoRMAN LOcKYER, F.R.S. 


With 7 Photographic Illustrations of Spectra, and 52 other Illustrations. 
$2.50. 


. A HISTORY OF THE GROWTH OF THE STEAM-ENGINE. By Pro- 


fessor R. H. THurston, Cornell University. With 163 Dlustrations. $2.50. 


. EDUCATION AS A SCIENCE. By ALEXANDER Batn, LL.D. $1.75. 
26. 


STUDENTS’ TEXT-BOOK OF COLOR; or, Modern Chromatics. With 
Applications to Art and Industry. By Professor Oe¢DEN N. Roop, Colum- 
bia College. With 130 Illustrations. $2.00. 


THE HUMAN SPECIES. By Professor A. DE QUATREFAGES, Museum of ~ 


Natural History, Paris. $2.00. 


. THE CRAYFISH: An Introduction to the Study of Zodlogy. By T. H. 


Hvuxtety, F.R.S. With 82 Illustrations. $1.75. 


.THE ATOMIC THEORY. By Professor A. Wurtz. Translated by E. 


Cleminshaw, F.C. S. With Illustrative Chart. $1.50. 

ANIMAL LIFE AS AFFECTED BY THE NATURAL CONDITIONS OF 
EXISTENCE. By Professor KARL SEMPER, University of Wirzburg. 
With 106 Illustrations and 2 Maps. $2.00. 

SIGHT: An Exposition of the Principles of Monocular and Binocular Vision. 
By Professor JoszepH Lz Conte, LL. D., University of California. With 
132 Illustrations. $1.50. 


. GENERAL PHYSIOLOGY OF MUSCLES AND NERVES. By Professor 


I. RosENTHAL, University of Erlangen. With 75 Illustrations. $1.50. 


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VOLCANOES; What they Are and-What they Teach. By Professor JoHN 
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. SUICIDE: An Essay in Comparative Moral Statistics. By Professor HENRY 


MorsEtu1, M. D., Royal University, Turin. With 4 Statistical Maps. 
$1.75. 

THE FORMATION OF VEGETABLE MOULD, THROUGH THE AC- 
TION OF WORMS. With Observations on their Habits. By CHARLEs 
Darwin, LL.D., F. R.S. With 15 Illustrations. $1.50. 


The International Scientific Series.—(Continued.) 3 


38. 
39. 


40. 
_ DISEASES OF MEMORY: An Essay in the Positive Psychology. By TH. 


51. 


52. 


53. 


55. 


57. 


THE CONCEPTS AND THEORIES OF MODERN PHYSICS. By J. B. 
Stato. $1.75. 5 


THE BRAIN AND ITS FUNCTIONS. By J. Luys, Hospice Salpétriére, 
Paris. With 6 Illustrations. $1.50. 


MYTH AND SCIENCE. By Tiro Vienoui. $1.50. 


Rreor, author of ‘‘ Heredity.”” $1.50. 


. ANTS, BEES. AND WASPS. A Record of Observations of the Habits of 


the Social Hymenoptera. By Sir Joun Lupzock, Bart., F. R.S., etc. $2.00. 


_THE SCIENCE OF POLITICS. By Professor SHELDON Amos. $1.75. 
_ ANIMAL INTELLIGENCE. By Gzoree J. Romanes, M.D., F.R.S. $1.7. 
._ MAN BEFORE METALS. By Professor N. Jory, Science Faculty of Tou- 


louse. With 148 Illustrations. $1.75. 


THE ORGANS OF SPEECH AND THEIR APPLICATION IN THE 


FORMATION OF ARTICULATE SOUNDS. By Professor G. H. von 
MEYER, University of Ztirich. With 47 Illustrations. $1.75. 


. FALLACIES: A View of Logic from the Practical Side. By ALFRED 


Sipewick, B. A., Oxon. $1.75. 


. ORIGIN OF CULTIVATED PLANTS. By ALPHONSE DECANDOLLE. $2.00. 
. JELLY-FISH, STAR-FISH, AND SEA-URCHINS. A Research on Primi- 


tive Nervous Systems. By Groree J. Romanes, M.D., F. R.S. With 63 
Tilustrations. $1.75. 


. THE COMMON SENSE OF THE EXACT SCIENCES. By Wriu14m Kine- 


DON CLIFFORD. With 100 Figures. $1.50. 

PHYSICAL EXPRESSION : Its Modes and Principles. By Francis WaR- 
NER, M.D., Assistant Physician, London Hospital. With 51 Tlustrations. 
$1.75. 

ANTHROPOID APES. By Professor RoBERT HARTMANN, University of 
Berlin. With 63 Illustrations. $1.75. 

THE MAMMALIA IN THEIR RELATION TO PRIMEVAL TIMES. By 


Professor Oscar ScHMIDT, University of Strasburg. With 51 Dlustrations. 
$1.50. 


. COMPARATIVE LITERATURE. By Professor H. M. Posnert, M. A., Uni- 


versity College, Auckland. $1.75. 


EARTHQUAKES AND OTHER EARTH MOVEMENTS. By Professor JoHN 
Mine, Imperial College of Engineering, Tokio. With 38 Figures. $1.75. 


. MICROBES, FERMENTS, AND MOULDS. By E. L. Trovzssart. With 


107 IJustrations. $1.50. 


THE GEOGRAPHICAL AND GEOLOGICAL DISTRIBUTION OF ANI- 
MALS. By Professor ANGELO HEILPRIN, Academy of Natural Sciences, 
Philadelphia. $2.00. 


. WEATHER. A Popular Exposition of the Nature of Weather Changes from 


Day to Day. With 96 Diagrams. By Hon. RatpH ABERCROMBY. $1.75. 


62. 


63. 


68. 


69. 


70. 


“A. 


72. 


73. 


The International Scientific Series.—(Continued.) 


. ANIMAL MAGNETISM. By ALFRED BINET and CHARLES FERE, Assistant 


Physician, Hospice Salpétriére, Paris. With 15 Figures. $1.50. 


. INTERNATIONAL LAW, with Materials for a Code of International Law. 


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. THE GEOLOGICAL HISTORY OF PLANTS. With 79 Illustrations. By 


Sir J. Witt1am Dawson, LL. D., F.R.S. $1.75. 
ANTHROPOLOGY. An Introduction to the Study of Man and Civilization. 
By EDWARD B. Tytor, D.C.L., F.R.S. With 78 Illustrations. $2.00. 
THE ORIGIN OF FLORAL STRUCTURES, THROUGH INSECT AND 


OTHER AGENCIES. By the Rev. Gtorert HENsLow, M.A., etc. With 
88 Illustrations. $1.75. 


. THE SENSES, INSTINCTS, AND INTELLIGENCE OF ANIMALS, WITH 


SPECIAL REFERENCE TO INSECTS. By Sir Joun Lussock, Bart., 
F.R.S., etc. With 118 Illustrations. $1.75. 


. THE PRIMITIVE FAMILY IN ITS ORIGIN AND DEVELOPMENT. 


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. PHYSIOLOGY OF BODILY EXERCISE. By F. Lacranez, M.D. $1.7. 
. THE COLORS OF ANIMALS: Their Meaning and Use. By EpwarpD 


BAGNALL PouLTon, F.R.S. With 36 Illustrations and 1 Colored Plate. 
$1.75. 

SOCIALISM: New and Old. By Professor WILLIAM GRAHAM, M. A., Queen’s 
College, Belfast. $1.75. 


MAN AND THE GLACIAL PERIOD. By Professor G. FREDERICK WRIGHT, 
D.D., Oberlin Theological Seminary. With 108 Illustrations and 3 Maps. 
$1.75. 


HANDBOOK OF GREEK AND LATIN PALAOGRAPHY. By Epwarp 
MAUNDE THompPpson, D.C.L., etc. $2.00. 


A HISTORY OF CRUSTACEA. Recent Malacostraca. By the Rev. 
. THomas R. R. Stespine, M.A. With 51 Tlustrations. $2.00. 


RACE AND LANGUAGE. By Professor ANDRE LEFEVRE, Anthropological 
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MOVEMENT. By E. J. MArry. Translated by Eric PRITCHARD, M.A. 
M.B., B. Ch. (Oxon.). With 200 Illustrations. 


New York: D. APPLETON & CO., 72 Fifth Avenue. 


B74. 


a L SCIENTIFIC SERIES. 
ie - THE INTERNATIONAL § 


B40X 
«ce THE FORMS OF WATER 


CLOUDS & RIVERS, ICE & GLACIERS 


BY 


Joun ‘Tynpaui, LL.D. FRA. 


PROFESSOR OF NATURAL PHILOSOPHY IN THE ROYAL ‘"NSTITUTION 


WITH THIRTY-FIVE ILLUSTRATIONS DRAWN AND ENGRAVED 


UNDER THE DIRECTION OF THE AUTHOR 


NEW YORK 
mr ATPLETON AND COMPANY 
1896 


ENTERED, according to Act of Congress, in the year 1872, 
By D. APPLETON & CO., 
In the Office of the Librarian of Congress at Washington. 


AMERICAN PREFACE 


TO THE 


INTERNATIONAL SCIENTIFIC SERIES, 


THE rapid development of science in the present age, 
aud the increasing public interest in its results, make it 
desirable that the most efficient measures should be adopted 
to elevate the character of its popular literature. The ten- 
dency of careless and unscrupulous book-makers to cater to 
public ignorance and love of the marvellous; and to foist their 
crude productions upon those who are too little instructed to 
judge of their real quality, has hitherto been so strong as to 
cast discredit upon the idea of “popular science.” It is 
highly important to counteract this evil tendency by fur- 
nishing the public with popular scientific books of a superior 
character. The publication of the present volume is the first 
step in carrying out a systematic enterprise of this kind. It 
initiates a series of such works on a wide range of scientific 
subjects, to be prepared by the leading thinkers of different 
countries, and known as the “INTERNATIONAL SCIENTIFIC 


SERIES.”’ 


vi AMERICAN PREFACE. 


It is designed to consist of compendious scientific trea. 
tises, representing the latest advances of thought upon sub- 
jects of general interest, theoretical and practical, to all 
elasses of readers. The familiar phenomena of surrounding 
Nature, in their physical and chemical aspects, the knowledge 
of which has recently undergone marked extension or revision, 
will be considered in their latest interpretations. Biology, or 
the general science of life, which has lately come into promi- 
nence, will be explained in its leading and most important 
principles. The subject of mind, which, under the inductive 
method and on the basis of its physical accompaniments and 
conditions, 1s giving rise to a new psychology, will be treated 
with the fulness to which it is entitled. The laws of man’s 
social development, or the natural history of society, which 
are now being studied by the scientific method, will also re- 
ceive a due share of attention. While the books of this 
series are to deal with a wide diversity of topics, it will be a 
leading object of the enterprise to present the bearings of 
inquiry upon the higher questions of the time, and to throw 
the latest light of science upon the phenomena of human 
nature and the economy of human life. 

As the first requisite of such a series of works is trust 
worthiness, their preparation has been confided only to men 
of eminent ability, and who are recognized authorities in 
their several departments. As they are to address the non- 
scientific public, it is a further requisite that they should be 
written in familiar and intelligible language. It 1s not to be 
expected that the authors will all attain to the same stand: 
ard in this respect, but they are pledged to the utmost sim: 


AMERICAN PREFACE. Vii 


plicity of exposition that is possible consistently with cleaz 
and accurate representation. 

As science is now the supreme interest of civilization, and 
roncerns alike the people of every country, and as, moreover, 
it affords a common ground upon which men of all races, 
tongues, faiths, and nationalities, may work together in har- 
mony; it seemed fitting that an undertaking of this kind 
should be of comprehensive scope and stand upon an inter- 
national basis. With the growing sentiment of sympathy 
and brotherhood amorg the most widely-separated students 
of Nature, and the extensive facilities of business intercourse 
that now exist, there appeared no reason why an interna- 
tional combination of authors and publishers should not be 
effected that would be equally favorable to their own private 
interests and advantageous to the public. To gain this end 
and guarantee to authors better remuneration for their work, 
is a distinctive purpose of the present enterprise. But there 
was this difficulty in the way of any such arrangement, that, 
while the rights of foreign authors are guarded by all other 
civilized governments, they are not protected by the gov- 
ernment of the United States. To escape this difficulty, and 
secure American coéperation, the first thing needed was to 
obtain the consent of an American publishing-house to 
grant voluntarily to foreign authors the justice which our 
government denies them. ‘It was agreed by Messrs. Apple- 
ton that they would pay the foreign contributors to this 
series the full rates of copyright that are usually allowed to 
American authors. When this was done, engagements 
were made with distinguished scientists of England, France, 


iil AMERICAN PREFACE. 


Germany, and the United States, to prepare works for the 
series, and with Henry 8. King & Co., of London, Germer 
Bailliére, of Paris, and Messieurs Brockhaus, of Leipsic, to 
publish them. Negotiations are pending for the reproduc- 
tion of the series in other countries, but the present arrange 
ments secure to the authors the benefits of the four leading 
markets of the world. : 

t is a fact not without significance, that the proposal of 
this enterprise was received with the most cordial favor by 
the eminent scientific men who were solicited to aid in carry- 
ing it forward. Most of them ccnsented at once; but, while 
some were so heavily burdened with work that they could 
enter into no immediate engagements, not one of them de- 
clined to codperate, and all promised to do so at the earliest 
practicable opportunity. The feeling of the desirableness 


of such an undertaking was strong and unanimous. ‘The old 


dislike of the cultivators of science to participate in the work 
of popular teaching, seems very much to have passed away ; 
and in England, France, and Germany, alike it was freely ac- 
knowledged that savanits have an imperative duty to dis- 
charge in relation to the work of general scientific educa- 
tion, As remarked by Prof. Virchow, of Berlin, “the des- 
tiny of science is the service of humanity.” 

It was stipulated by the authors that they should have 
ample time for the preparation of their books, and, as the 
arrangements were recently made, only a few of the works 
are yet ready. Several, however, are now in press, and will 
shortly appear. 


Those interested in the series are under many obligations 


1 


ee ee hae 


a, 


AMERICAN PREFACE. ik 


to Prof. Tyndall for his kindness in consenting to furnish 
its commencing volume. Being prepared in a short time, 
amid great pressure both of laboratory and literary work, it 
contains somewhat less matter than may be expected in the 
ensuing volumes. It treats of subjects upon which he is per: 
haps the highest living authority; and is an admirable ex- 
ample of that vivid, stirring, impressive style for which its 
author is so distinguished. Prof. Tyndall is not only a mas- 
ter in the “ scientific use of the imagination,” but in kindling 
tke action of that faculty in his readers. He writes in pict- 
ures, So as to make them see what he sees. Jn this volume 
he addresses himself directly to his juvenile friends, groups 
them around him, takes them with him to his favorite moun- 
tains, and thus adds a dramatic element and the effect of 
personal sympathy to familiar colloquial exposition. 

The “ INTERNATIONAL SCIENTIFIC SERIES” will form an 
elegant and valuable library of popular science, fresh in treat- 
ment, attractive in form, strong in character, moderate in 
price, and indispensable to all who care for the acquisition 
of solid and serviceable knowledge; and it is commended to 
American readers as a help in the important work of sound 
public education. 

EK. L. Y. 

Naw York, Seplember, 1872 


AUTHOR'S PREFACE, 


ATER an absence of twelve years, I visited the Mer 
de Glace last June. It exhibited in a striking degree 
that excess of consumption over supply, which, if contin- 
ued, will eventually reduce the Swiss glaciers to the mere 
spectres of their former selves. When I first saw the 
Mer de Glace its ice-cliffs towered over Les Mottets, and 
an arm of the Arveiron, issuing from the cliffs, plunged 
as a powerful cascade down the rocks. The ice has now 
shrunk far behind them. A huge moraine, left behind 
by the retreating glacier, will mark, for some time to 
come, its recent magnitude. The vault of the Arveiron 
has dwindled considerably. The way up to the Chapeau 
lies on the top of a lateral moraine, reached a few years ago 
by the surface of the glacier, the present surface lying far 
below. ‘The visible and continual breaking away of the 
moraines, left thus stranded on the mountain-flank, ex- 


plains the absence of ancient ridges on the mountains 


xii PREFACE. 


where the slopes are steep. ‘The ice-cascade of the Géant 
has suffered much from the general waste. Its crevasses 
are still wild, but the 1ce-clifis and séracs of former days 
are but poorly represented to-day. 

The great Aletsch and its neighbors exhibit similar 
evidences of diminution. J found, moreover, this year, 
that the two ancient moraines mentioned in paragraph 
364 are parts of the same great lateral moraine which 
flanked the glacier for a long period, during which its 
magnitude must have remained practically constant. The 
place occupied by the ancient ice-river is rendered strik- 
ingly conspicuous by this well-preserved boundary. 

During my residence at the Bel Alp this year, a 
catastrophe occurred which renders, for the time being, 
the description of the Miargelin See given in § 50 inap- 
propriate. In company with two young friends I had 
descended the glacier and passed through the gorge of 
the Massa. On our return to the Bei Alp we found the 
domestics of the hotel leaning out of the windows and 
looking excitedly towards the glacier. From it pro- 
ceeded a sound which resembled the roar of a cataract. 
The servants remarked that the Margelin See must have 
broken loose. This was the case. For a time, however, 
the water flowed beneath the glacier; but at a point 
about midway between the Bel Alp and the Atgoisch- 
horn, it broke forth on the Avggischhorn side, and formed 


PREFACE. Xill 


a torrent between the glacier and the slope of the moun: 
tain. In some places this river was more than sixty 
yards wide, at others it was contracted to less than one- 
fifth of this width. Broken cascades of great height were 
formed here and there by successive ledges of ice, the 
torrent leaping with indescribable fury from ledge to 
ledge, and sending a smoke of spray into the air. At one 
place the bottom of the torrent was deep soft sand, which, 
after the water had passed, could be seen to have been 
tortured into huge funnels by the whirling eddies over- 
head. 

Soon after we reached the Bel Alp, on the occasion 
just referred to, the front of the torrent appeared at the 
opposite side of the valley carrying everything movable 
before it, and immediately afterwards swept through the 
hollow that we had traversed a little earlier in the 
day. When at the end of the glacier I was struck by 
the force and volume of the Massa, and the grandeur 
of its vault, but I could not then account for the huge 
blocks of ice which it incessantly carried down. Doubt- 
less the eruption above had been partial before the grand 
rush set in. The Rhone was considerably swollen, crops 
were damaged or ruined, and the driver of the diligence 
was sorely perplexed to find himself in three feet of 
water, without any apparent reason, on the public high- 
way. ‘wo or three days subsequently I learned at the 


xiv PREFACE. 


AAggischhorn that an engineer had been sent up to re- 
port on the possibility of opening a channel, so as to pre- 
vent any future accumulation of water in the Margelin 
See. If this be done, a useful end will be gained, by the 
abolition, however, of one of the most beautiful objects in | 
Switzerland. 


J. TYNDALL, 
September, 1872. 


PREFACE TO THE FOURTH EDITION. 


Ara meeting of the Managers of the Royal Institution 
held on December 12, 1825, ‘the Committee appointed to 
consider what lectures should be delivered in the Institu- 
tion in the next session,’ reported ‘that they had consulted 
Mr. Faraday on the subject of engaging him to take a part 
in the juvenile lectures proposed to be given during the 
Christmas and Easter recesses, and they found his avoca- 


tions were such that it would be exceedingly inconvenient 


for him to engage in such lectures.’ 

At a general monthly meeting of the members of the 
Royal Institution, held on December 4, 1826, the Managers 
reported ‘that they had engaged Mr. Wallis to deliver a 
course of lectures on Astronomy, adapted to a juvenile 
auditory, during the Christmas vacation.’ 

In a report dated April 16, 1827, the Board of Visitors 
express ‘their satisfaction at finding that the plan of juve- 
nile courses of lectures has been resorted to. They feel sure 
that the influence of the Institution cannot be extended too 


ea PREFACE TO THE FOURTH EDITION. 


far, and the system of instructing the younger portion of 
the community is one of the most effective means which the 
Institution possesses for the diffusion of science.’ 

Faraday’s holding aloof was but temporary, for at 
Christmas, 1827, we find him giving a ‘Course of Six Ele- 
mentary Lectures on Chemistry, adapted to a Juvenile Au- 
ditory.’ * 

The Easter lectures were soon abandoned ; but from the 
date here referred to to the present time the Christmas lect- 
ures have been a marked feature of the Royal Institution. 

In 1871 it fell to my lot to give one of these courses. 
I had been frequently invited to write on Glaciers in ency- 
clopzedias, journals, and magazines, but had always declined 
to do so. I had also abstained from making them the sub- 
sect of a course of lectures, wishing to take no advantage 
of my position here, and indeed to avoid writing a line or 
uttering a sentence on the subject for which I could not be 
held personally responsible. In view of the discussions 
which the subiect had provoked, I thought this the fairest 
course. 

But, in 1871, the time (I imagined) had come, when, 
without risk of offence, I might tell our young people some- 
thing about the labours of those who had unravelled for their 
instruction the various problems of the ice-world. My 

* There is no record to show that Mr. Wallis gave the Astronomical lect- 


ares referred to, and our librarian believes that the Chréstmas courses were 


orexed by Faraday. 


PREFACE TO THE FOURTH EDITION. xvil 


iamented friend and ever-helpful counsellor, Dr. Bence 
Jones, thought the subject a good one, and accordingly it 
was chosen. Strong in my sympathy with youth, and re- 
membering the damage done by defective exposition to my 
own young mind, I sought, to the best of my ability, to 
confer upon these lectures clearness, thoroughness, and life. 

Wishing, moreover, to render them of permanent value, 
I wrote out copious Notes of the course, and had them dis- 
tributed among the boys and girls. In preparing these 
Notes I aimed at nothing less than presenting to my youth- 
ful audience, in a concentrated but perfectly digestible 
form, every essential point embraced in the literature of the 
glaciers, and some things in addition, which, derived as they 
were from my own recent researches, no book previously 
published on the subject contained. 

But my theory of education agrees with that of Emer- 
son, according to which instruction is only half the battle, 
what he calls provocation being the other half. By this he 
means that power of the teacher, through the force of his 
character and the vitality of his thought, to bring out all 
the latent strength of his pupil, and to invest with interest 
even the driest matters of detail. In the present instance I 
was determined to shirk nothing essential, however dry; 
and, to keep my mind alive to the requirements of my 
pupil, I proposed a series of ideal rambles, in which he 
should be always at my side. Oddly enough, though I 
was here dealing with what might be called the abstract 


KV1ll PREFACE TO THE FOURTH EDITION. 


idea of a ba7, I realized his presence so fully as to enter 
tain for him, before our excursions ended, an affection con- 
sciously warm and real. 

The ‘ Notes’ here referred to were at first mtended for 
the use of my audience alone. At the urgent request of a 
friend I slightly expanded them, and converted them into the 
little book here presented to the reader. 

The amount of atteution bestowed upon the volume in- 
duces me to give this brief history of its origin. 

A German critic, whom I have no reason to regard as 
specially favourable to me or it, makes the following remark 
on the style of the book: ‘ This passion [for the mountains | 
tempts him to reveal more of his Alpine wanderings than is 
necessary for his demonstrations. The reader, however, 
will not find this a disagreeable interruption of the course 
of thought; for the book thereby gains wonderfully in 
vividness.’ This, I would say, was the express aim of the 
breaks referred to. I desired to keep my companion fresh, 
as well as instructed, and these interruptions were so many 
breathing-places where the intellectual tension was pur- 
posely relaxed and the mind of the pupil braced to fresh 
action. 

Of other criticisms, flattering and otherwise, I forbear to 
speak, As regards some of them, indeed, it would be a 
reproach to that manliness which I have sought to encourage 
in my pupil to return blow for blow. If the reader be 
acquainted with them, this will let him know how I regard 


PREFACE TO THE FOURTH EDITION. xix - 


them; and if he be not acquainted with them, I would rec- 
ommend him to ignore them, and to form his own judg: 
ment of this book. No fair-minded person who reads it 
will dream that I, in writing it, had thought of acting other- 
wise than justly and generously toward my predecessors, 
the last of whom, to the grief of all who knew him, has re 


cently passed away. 
Joun TYNDALL 
April, 1874 


Sed ae 
} -, 2. Clouds, Rains, and Rivers 3 : : - - 
3. The Waves of Light : : : ; . - 
4. The Waves of Heat which produce the Vapour of our Atmosphere 
and melt our Glaciers . : - : : : 
5. Experiments to prove the foregoing statements. : . 
6. Oceanic Distillation : ; : 2 , : 

7. Tropical Rains 

8. Mountain Condensers : ; , ‘ E . 
9. Architecture of Sno+7 : : ‘ : ‘ 

10. Atomic Poles ‘ ; : : Se ee 
11. Architecture of Lake Ice . : ‘ : : . 
12. The Source of the Arveiron. Ice Pinnacles, Towers, and Chasms 
of the Glacier des Bois. Passage to the Montanvert . : 
13. The Mer de Glace and its Sources. Our First Climb to the Cleft 
Station . . : : ; : : ‘ 
14. Ice-cascade and Snows of.the Col du Géant 2 i : 
15. Questioning the Glaciers . ° : : : - 
lv. Branches and Medial Moraines of the Mer de Glace from the 
Cleft Station . : : : - : . 
17. The Taléfre and the Jardin. Work among the Crevasses ; 
18. First Questions regarding Glacier Motion. Drifting of Bodies 


CONTENTS. 


buried in a Crevasse . : : ‘ c - 


PAUB 
1,6 
8 


11 
4 
19 
23 
27 


AK CONTENTS 
| PAGE 
§ 19. The Motion of Glaciers. Measurements by Hugi —_ Agassiz. 
z Drifting of Huts on the Ice : ° : Pi 
20. Precise Measurements of Agassizand Forbes. Motion of a Glacier 
proved to resemble the Motion ofa River . : ah spe 
£1. The Theodolite and its Use. Our own Measurements. «> 
22. Motion of the Merde Glace . ° : : :° S68 
23. Unequal Motion of the two Sides of the Mer de Glace . 1 oe 
24. Suggestion of a new Likeness of Glacier Motion to River Mction. 
Conjeeture tested . : * : oe 
25. New Law of Glacier Motion : : : < -paee 
26. Motion of Axis of Mer de Glace See : : . 8 
27. Motion of Tributary Glaciers . : - ee a: feats 
28. Motion of Top and Bottom of Glacier . : : oe. 
29. Lateral Compression of a Glacier oes , . > 
30. Longitudinal Compression ofa Glacier.  —S.. ‘ Pee 
31. Sliding and Flowing. Hard Ice and Soft Ice . : - 86 
32. Winter on the Merde Glace. : : : ol gnee 
33. Winter Motion of the Mer de Glace. ; : eo ae 
34. Motion of the Grindelwald and Aletsch Glacier . 95 
35. Motion of Morteratsch Glacier . : : an « 98 
36. Birth of a Crevasse: Reflections ‘ F : - 98 
37. Icicles . : ; : : : 3 eee 
38. The Bergschrund soya: | : » aeZ 
39. Transverse Crevasses . : : : ~ 303 
$0. Marginal Crevasses : : : Me - 105 
41. Longitudinal Crevasses . : : : - 169 
42. Crevasses in relation to Curvature of Glacisr_ . ; “Sy ae 
43. Moraine-ridges, Glacier Tables, and Sand Cones ‘ o ee 
44. The Glacier Mills or Moulins . : : . 116 


45. The Changes of Volume of Water by Heat and Cold . ee 


Correction of Errors , 


. The Riffelberg and Gorner Glacier 
Ancient Glaciers of Switzerland 

. Erratic Blocks . : : 
. Ancient Glaciers of England, Ireland, Scotland, and Wales . 150 
. The Glacier Epoch 
. Glacial Theories - 
. Dilatation and Sliding Theories 
. Plastic Theory . 

. Viscous Theory. 

. Regelation Theory 
Cause of Regelation 
. Faraday’s View of Regelation . 
. The Blue Veins of Glaciers 


. Relation of Structure to Pressure 


67. Conclusion 


&: 


. Consequences Jowing from the foregoing Properties 


. The Molecular Mechanism of Water-Congelation 
. The Dirt Bands of the Mer de Glace 
. Sea-ice and Icebergs : 
. The ete the Margelin See and its Icebergs . 


. Slate Cleavage and Glacier Lamination 


XXlll 


PAGE 


oz: Water. 


- be ws & wt et ite Pus se eo Ds’  -_— - S77 
=. eee eee ee pe je eet So. ee a ‘Wetns 1 ad get fh ees Se. f Tweet Se. Fe es Silly r Se ear Se ee Te os a : Tas ee 
F 1 


CLCUD-BANNER OF THE AIGUILLE DU DRU (par. 84 and 227.) 


= 


Sex 
STS 


THE FORMS OF WATER 


IN 


ULOUDS AND RIVERS, ICE AND GLACIERS. 


§ 1. Clouds, Rains, and Rivers. 


1. Evexy occurrence in Nature is preceded by other 
occurrences which are its causes, and succeeded by 
others which are its effects. The human mind is not 
satisfied with observing and studying any natural oc- 
currence alone, but takes pleasure in connecting every 
natural fact with what has gone before it, and with 
what is to come after it. 

2. Thus, when we enter upon ,the study of rivers and 
glaciers, our interest will be greatly augmented br 
taking into account not only their actual appearances, 
but also their causes and effects. 

do. Let us trace a river to its source. Beginning 
where it empties itself into the sea, and following it 


2 THE FORMS OF WATER IN 


backwards, we find it from time to time joined by 
tributaries which swell its waters. The river of course 
becomes smaller as these tributaries are passed. It 
shrinks first to a brook, then to a stream; this again 
divides itself into a number of smaller streamlets, 
ending in mere threads of water. These constitute 
the source of the river, and are usually found among 
hills. ees 

4. Thus the Severn has its source in the Welsh 
Mountains; the Thames in the Cotswold Hills; the 
Danube in the hills of the Black Forest; the Rhine and 
the Rhone in the Alps; the Ganges in the Himalaya — 
Mountains; the Euphrates near Mount Ararat; the 
Garonne in the Pyrenees; the Elbe in the Giant Moun- 
tains of Bohemia; the AaaGics in the Rocky Mountz 
and the Amazon in the Andes of Peru. 

5. But itis quite plain that we have not yet reaghed 
the real beginning of the rivers. Whence do the © 
earliest streams derive their water? A brief residence 
among the mountains would prove to you that they are 
fed by rains. In dry weather you would find the 
streams feeble, sometimes indeed quite dried up. In 
wet weather you would see them foaming torrents. In 
general these streams lose themselves as little threads 
of water upon the hill sides; but sometimes you may © 
irace a river to a definite spring. The river Albula in 
Switzerland, for instance, rushes at its origin in con- 
siderable volume from a mountain side. But you very 


CLOUDS AND RIVERS, ICE AND GLACIERS. 3 


soon assure yourself that such springs are also fed by 
rain, which has percolated through the rocks or soil, 
and which, through some orifice that it has found or 
formed, comes to the light of day. 

6. But we cannot end here. Whence comes the rain 
which forms the mountain streams? Observation 
enables you to answer the question. Rain does not 
come from a clear sky. It comes from clouds. But 
what are clouds? Is there nothing you are acquainted 
with which they resemble? You discover at once a 
likeness between them and the condensed steam of a 
locomotive. At every puff of the engine a cloud is pro- 
jected into the air. Watch the cloud sharply: you 
notice that it first forms at a little distance from the 
top of the funnel. Give close attention and you will 
sometimes see a perfectly clear space between the 
funnel and the cloud. Through that clear space the 
thing which makes the cloud must pass. What, then, 
is this thing which at one moment is transparent and 
invisible, and at the next moment visible as a dense 
opaque cloud ? 

7. It is the steam or vapour of water from the boiler. 
Within the boiler this steam is transparent and in- 
visible; but to keep it in this invisible state a heat 
would be required as great as that within the boiler. 
When the vapour mingles with the cold air above the 
hot funnel it ceases to be vapour. Every bit of steam 
shirinks, when chilled, to a much more minute particle of 


d. THE FORMS OF WATER IN 


water. The hquid particles thus produced form a kind 
of water-dust of exceeding fineness, which floats in the 
air, and is called a cloud. 

8. Watch the cloud-banner from the funnel of a 
running locomotive; you see it growing gradually less 
dense. It finally melts away altogether, and if you 
continue your observations you will not fail to notice 
that the speed of its disappearance depends upon the 
character of the day. In humid weather the cloud 
hangs long and lazily in the air; in dry weather it is 
rapidly licked up. What has become of it? It has 
been reconverted into true invisible vapour. 

9. The drier the air, and the hotter the air, the © 
greater is the amount of cloud which can be thus dis- 
solved init. When the cloud first forms, its quantity 
is far greater than the air is able to maintain in an in- 
visible state. But as the cloud mixes gradually with a 
larger mass of air it is more and more dissolved, and 
- finally passes altogether from the condition of a finely- 
divided liquid into that of transparent vapour or gas. 

10. Make the lid of a kettle air-tight, and permit — 
the steam to issue from the pipe; a cloud is precipitated 
in all respects similar to that issuing from the funnel of 
the locomotive. 

11. Permit the steam as it issues from the pipe tc 
pass through the flame of a spirit-lamp, the cloud is in- 
stantly dissolved by the heat, and is not again precipi- 
tated. With a special boiler and a special nozzle the 


CLOUDS AND RIVERS, ICE AND GLACIERS. A 


experiment inay be made more striking, but not more 
instructive, than with the kettle. 

12. Look to your bedroom windows when the weather 
is very cold outside; they sometimes stream with water 
derived from the concensation of the aqueous vapour 
from your own lungs. The windows of railway carriages 
in winter show this condensation in a striking manner. 
Pour cold water into a dry drinking-glass on a summer’s 
day: the outside surface of the glass becomes instantly 
dimmed by the precipitation of moisture. On a warm 
day you notice no vapour in front of your mouth, but 
on a cold day you form there a little cloud derived 
from the condensation of the aqueous vapour from the 
lungs. 

13. You may notice in a ball-room that as long as the 


door and windows are kept closed, and the room remains 


hot, the air remains clear; but when the doors or windows 
are opened a dimness is visible, caused by the precipi- 
tation to fog of the aqueous vapour of the ball-room. 
If the weather be intensely cold the entrance of fresh 
air may even cause snow to fall. This has been ob- 
served in Russian ball-rooms; and also in the subterra- 
nean stables at Erzeroom, when the doors are opened 
and the cold morning air is permitted to enter. 

14. Even on the driest day this vapour is never 
absent from our atmosphere. The vapour diffused 
through the air of this room may be congealed‘to hoar 
frost in your presence. ‘This is done by filling a 


6 THR FORMS OF WATER IN 


vessel with a mixture of pounded ice and salt, which 
is colder than the ice itself, and which, therefore, con- 
denses and freezes the aqueous vapour. The surface 
of the vessel is finally coated with a frozen fur, so 
thick that it may be scraped away and formed into a 
snow-ball. | 
_ 15. To produce the cloud, in the case of the 16008 
motive and the kettle, heat is necessary. By heating 
the water we first convert it into steam, and then by 
clilline the steam we convert it into cloud. Is there 
any fire in nature which produces the clouds of our 
atmosphere? There is: the fire of the sun. _ 

16, Thus, by tracing backward, without any breaks in 
the chain of occurrences, our river from its end to its 
veal beginnings, we come at length to the sun. 


ey 
17. There are, however, rivers which have sources 
somewhat different from those just mentioned. They 
do not begin by driblets on a hill side, nor can they be 
traced toa spring. Go, for example, to the mouth of 
the river Rhone, and trace it backwards to Lyons, where 
it turns to the east. Bending round by Chambery, you 
come at length to the Lake of Geneva, from which the 
river rushes, and which you might be disposed to regard 
as the source of the Rhone. But go to the head of the 
lake, and you find that the Rhone there enters it, that 
the lake is in fact a kind of expansion of the river. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 7 


Follow this upwards; you find it joined by smaller 
rivers from the mountains right and left. Pass these, 
and push your journey higher still. You come at leneth 
to a huge mass of ice-—the end of a glacier—which fills 
the Rhone valley, and from the bottom of the glacier 
the river rushes. In the glacier of the Rhone you thus 
find the source of the river Rhone. 

18. But again we have not reached the real begin- 
ning of the river. You soon convince yourself that this 
earliest water of the Rhone is produced by the melting 
of the ice. You get upon the glacier and walk upwards 
along it. After a time the ice disappears and you come 
upon snow. If you are a competent mountaineer you 
may go to the very top of this great snow-field, and if 
you cross the top and descend at the other side you 
finally quit the snow, and get upon another olacier 
called the Trift, from the end of which rushes a rive” 
smaller than the Rhone. | 

19. You soon learn that the mountain snow feeds 
the glacier. By some means or other the snow is con- 
verted into ice. But whence comes the snow? Like 
the rain, it comes from the clouds, which, as before, 
can be traced to vapour raised by the sun. Without 
solar fire we could have no atmospheric vapour, without 
vapour no clouds, without clouds no snow, and without 
snow no glaciers. Curious then as the conclusion may 
be, the cold ice of the Alps has its origin in the heat of 
the sun. 


8 THE FORMS CF WATER IN. 


§ 3. The Waves of Light. 


20. But what is the sun? We know its size aml its 
weight. We also know that it is a globe of fire far 
hotter than any fire upon earth. But we now enter 
upon another enquiry. We have to learn definitely 
what is the meaning of solar light and solar heat; in 
what way they make themselves known to our senses; 
by what means they get from the sun to the earth, and — 
how, when there, they produce the clouds of our atmo- 
sphere, and thus originate our rivers and our glaciers. 

21. If in a dark room you close your eyes and press 
the eyelid with your finger-nail, a circle of light will be 
seen opposite to the point pressed, while a sharp blow 
upon the eye produces the impression of a flash of light. 
There is a nerve specially devoted to the purposes of 
vision which comes from the brain to the back of the 
eye, and there divides into fine filaments, which are 
woven together to a kind of screen called the retina. 
The retina can be excited in various ways so as to pro- 
duce the consciousness of light; it may, as we have 
seen, be excited by the rude mechanical action of a blow 
imparted to the eye. 

22. There is no spontaneous creation of light by 
the healthy eye. To excite vision the retina must be 
affecied by something coming from without. What is 
‘hat something? In some way or other luminous 


CLOUDS AND RIVERS, ICE AND GLACIERS. 9 


but 


bodies have the power of affecting the retina 
how ? 

23. It was long supposed that from such bodies 
issued, with inconceivable rapidity, an inconceivably fine 
matter, which flew throvgh space, passed through the 
pores supposed to exist in the humours of the eye, 
reached the retina behind, and by their shock against 
the retina, aroused the sensation of light. 

24. This theory, which was supported by the greatest 
men, among others by Sir Isaac Newton, was found 
competent to explain a great number of the phenomena | 
of light, but it was not found competent to explain all 
the phenomena. As the skill and knowledge of experi- 
menters increased, large classes of facts were revealed 
which could only be explained by assuming that light 
was produced, not by a fine matter flying through space 
and hitting the retina, but by the shock of minute waves 
against the retina. 

25. Dip your finger into a basin of water, and cause 
it to quiver rapidly to and fro. From the point of dis- 
turbance issue small ripples which are carried forward 
by the water, and which finally strike the basin. Here, 
in the vibrating finger, you have a source of agitation ; 
in the water you have a vehicle through which the 
finger’s motion is transmitted, and you have finally the 
side of the basin which receives the shock of the little 
waves. 

26. In like manner, according to the wave theory of 


LO ‘THE FORMS OF WATER IN 


lioht, you have a source of agitation in the vibrating 
atoms, or smallest particles, of the luminous body; you 
have a vehicle of transmission in a substance which is 
supposed to fill all space, and to be diffused through the 
humours of the eye; and finally, you have the retina, 
which receives the successive shocks of the waves. 
These shocks are supposed to produce the sensation of 
light. 

27. We are here dealing, for the most part, with 
suppositions and assumptions merely. We have never 
seen the atoms of a luminous body, nor their motions. 
We have never seen the medium which transmits their 
motions, nor the waves of that medium. How, then, do 
we come to assume their existence ? 

28. Before such an idea could have taken any real 
root in the human mind, it must have been well disci- 
plined and prepared by observations and calculations of 
ordinary wave-motion. It was necessary to know how 
both water-waves and sound-waves are formed and 
propagated. It was above all things necessary to know 
how waves, passing through the same medium, act upon 
each other. Thus disciplined, the mind was prepared 
to detect any resemblance presenting itself between the 
action of light and that of waves. Great classes of 
optical phenomena accordingly appeared which could 
be accounted for in the most complete. and satisfactory 
manner by assuming them to be produced by waves, and 
which could not be otherwise accounted for. It is 


CLOUDS AND RIVERS, ICE AND GLACIERS. 1] 


because of its competence to explain all the phenomena 
of light that the wave theory now receives universal 
acceptance un the part of scientific men. 

Let me use an illustration. We infer from the 
fiint implements recently found in such profusion all 
over England and in other countries, that they were 
produced by men, and also that the Pyramids of Egypt 
were built by men, because, as far as our experience 
goes, nothing but men could form such implements or 
build such Pyramids. In like manner, we infer from 
the phenomena of light the agency of waves, because, 
as far as our experience goes, no other agency could 
produce the phenomena. 


§ 4. The Waves of Heat which produce the Vapour of our 
Atmosphere and melt our Glaciers. 


29. Thus, in a general way, I have given you the 
conception and the grounds of the conception, which 
regards light as the product of wave-motion; but we 
must go farther than this, and follow the conception into 
some of its details. We have all seen the waves of 
water, and we know they are of different sizes—different 
in length and different in height. When, therefore, 
you are told that the atoms of the sun, and of almost 
all other luminous bodies, vibrate at different rates, and 
produce waves of different sizes, your experience of 
water-waves will enable you to form a tolerably clear 


notion of what is meant. 
As 


L2 | THE FORMS OF WATER IN 


30. As observed above, we have never seen the light: 
waves, but we judge of their presence, their position, 
and their magnitude, by their effects. Thei lengths 
have been thus determined, and found to vary from 
about 354,,th to <54,;th of an inch. 

dl. But besides those which produce light, the 
sun sends forth incessantly a multitude of waves which 
produce no light. The largest waves which the sun 
sends forth are of this non-luminous character, though 
they possess the highest heating power. 

32. A common sunbeam contains waves of all kinds, 
but it is possible to szft or filter the beam so as to inter- 
cept all its light, and to allow its obscure heat to pass 
unimpeded. For substances have been discovered 
which, while intensely opaque to the light-waves, are 
almost perfectly transparent to the others. On the other 
hand, it is possible, by the choice of proper substances, 
to intercept in a great degree the pure heat-waves, 
and to allow the pure light-waves free transmission. 
This last separation is, however, not so perfect as the 
first. 

33. We shall learn presently how to detach the one 
elass of waves from the other class, and to prove that 
waves competent to light a fire, fuse metal, or burn 
the hand lke a hot solid, may exist in a perfectly dark 
place. 


34. Supposing, then, that we withdraw, in the first 
instance the large heat-waves, and allow the light 


CLOUDS AND RIVERS, ICE AND GLACIERS. 13 


waves alone to pass. These may be concentrated by 
suitable lenses and sent into water without sensibly 
warming it. Let the light-waves now be withdrawn, 
and the larger heat-waves concentrated in the same 
manner; they may be caused to boil the water almost 
instantaneously. 

35. This is the point to which I wished to lead you, 
and which without due preparation could not be under- 
stood. You now perceive the important part played by 
these large darkness-waves, if I may use the term, in 
the work of evaporstion. When they plunge into seas, 
lakes, and rivers, they are intercepted close to the sur- 
face, and they heat the water at the surface, thus 
causing it to evaporate; the light-waves at the same 
time entering to great depths without sensibly heating 
the water through which they pass. Not only, there- 
fore, is it the sun’s fire which produces evaporation, 
but a particular constituent of that fire, the existence 
of which you probably were not aware of. 

36. Further, it is these selfsame lightless waves 
which, falling upon the glaciers of the Alps, melt the 
ice and produce all the rivers flowing from the glaciers; 
for I shall prove to you presently that the light-waves, 
even when concentrated to the uttermost, are unable 
to melt the most delicate hoar-frost ; much less would 
they be able to produce the copious liquefaction observed 
upon the glaciers. 

_ 37. These large lightless waves of the sun, as well as 


4, THE FORMS OF WATER IN 


the heat-waves issuing from non-luminous hot bodies, 
are frequently called obscure or invisible heat. 

We have here an example of the manner in which 
phenomena, apparently remote, are connected together 


in this wonderful system of things that we call Nature. 
You cannot study a snow-flake profoundly without being © 


led back by it step by step to the constitution of the sun. 
It is thus throughout Nature. All its parts are inter- 
dependent, and the study of any one part completely 
would really involve the study of all. 


§ 5. Hxpervments to prove the foregoing Statements. 


38. Heat issuing from any source not visibly red 
cannot be concentrated so. as to produce the intense 
effects just referred to. To produce these it is neces- 
sary to employ the obscure heat of a body raised to the 
highest possible state of incandesvence. The sun is 
such a body, and its dark heat is therefore suitable 
for experiments of this nature. 3 

39. But in the atmosphere of London, and for ex- 
periments such as ours, the heat-waves emitted by coke 
raised to intense whiteness by a current of electricity 
are much more manageable than the sun’s waves. 
The electric light has also the advantage that its dark 
radiation embraces a larger proportion of the total ra- 
diation than the dark heat of thesun. In fact, the force 
or energy, if I may use the term, of the dark waves of 
the electric light is fully seven times that of its hight: 


ett 


{ 
i et a eh ed ne ie ed Bh eel es eet, eee 


ae 
a * { 
‘Ts | fF = ee? 


Zé 
Ne Wa 


CLOUDS AND RIVERS, ICE AND GLACIERS. 15 


waves. The electric light, therefore, shall be employed 
in our experimental demonstrations. 

40. From this source a powerful beam is sent through 
the room, revealing its track by the motes floating in 
the air of the room; for were the motes entirely absent 
the beam would be unseen. It falls upon a concave 
mirror (a glass one silvered behind will answer) and 
is gathered up by the mirror into a cone of reflected 
rays ; the luminous apex of the cone, which is the focus 
of the mirror, being about fifteen inches distant from its 
reflecting surface. Let us mark the focus accurately by 
a pointer. : 

41. And now let us place in the path of the beam a 
substance perfectly opaque to light. This substance is 
iodine dissolved in a liquid called bisulphide of carbon. 
The light at the focus instantly vanishes when the dark 
solution is introduced. But the solution is intensely 
transparent to the dark waves, and a focus of such 
waves remains in the air of the room after the light 
has been abolished. You may feel the heat of these 
waves with your hand; you may let them fall upon a 
thermometer, and thus prove their presence; or, best 
of all, you may cause them to produce a current of 
electricity, which deflects a large magnetic needle. The 
magnitude of the deflection is a measure of the heat. 

42. Our object now is, by the use of a more powerful 
lamp, and a better mirror (one silvered in front 
and with a shorter focal distance), to intensify the 


16 THE FORMS OF WATER IN 


action here rendered so sensible. As before, the focus 
is rendered strikingly visible by the intense illumina- 
tion of the dust particles. We will first filter the 
beam so as to intercept its dark waves, and. then per- 
mit the purely luminous waves to exert their utmost 
power on a small bundle of gun-cotton placed at the 
focus. | 7 

43. No effect whatever is produced. The gun-cotton 
might remain there for a week without ignition. Let 
us now permit the unfiltered beam to act upon the 
cotton. It is instantly dissipated in an explosive flash. 
This experiment proves that the lhight-waves are incom- 
petent to explode the: cotton, while the waves of the 
full beam are competent to do so; hence we may con- 
clude that the dark waves are the real agents in the 
explosion. 

44, But this conclusion would be only probable; for 
it might be urged that the mixture of the dark waves 
and the light-waves is necessary to produce the result. 
Let us then, by means of our opaque solution, isolate 
our dark waves and converge them on the cotton. It 
explodes as before. 

45. Hence it is the dark waves, and they only, that 
are concerned in the ignition of the cotton. 

46. At the same dark focus sheets of platinum are 
raised to vivid redness; zinc is burnt up; paper in- 
stantly blazes; magnesium wire is ignited; charcoal 
within a receiver containing oxygen 1s set burning; a 


CLOUDS AND RIVERS, ICE AND GLACIERS. 17 


diamond similarly placed is caused to glow like a star, 
being afterwards gradually dissipated. And all this 
while the air at the focus remains as cool as in any 
other part of the room. 

47. To obtain the light-waves we employ a clear 
solution of alum in water; to obtain the dark waves 
we employ the solution of iodine above referred to. 
But as before stated (32), the alum is not so perfect a 
filter as the iodine; for it transmits a portion of the 
obscure heat. | 

48. Though the light-waves here prove their incom- 
petence to ignite gun-cotton, they are able to burn up 
black paper; or, indeed, to explode the cotton when it 
is blackened. The white cotton does not absorb the 
light, and without absorption we have no heating. The 
blackened cotton absorbs, is heated, and explodes. 

49. Instead of a solution of alum, we will employ for 
our next experiment a cell of pure water, through which 
the light passes without sensible absorption. At the 
focus is placed a test-tube also containing water, the full 
force of the light being concentrated upon it. The 
water is not sensibly warmed by the concentrated 
waves. We now remove the cell of water; no change 
is visible in the beam, but the water contained in the 
test-tube now boils. 

50. The light-waves being thus proved ineffectual, 
and the full beam effectual, we may infer that it is the 
dark waves that do the work of heating. But we clench 


13 THE FORMS OF WATER IN 


our inference by employing our opaque iodine filter 
Placing it on the path of the beam, the licht is entirely 
stopped, but the water boils exactly as it did when the 
fu]! beam fell upon it. 

51. The truth of the statement made in paragraph (34) 
is thus demonstrated. 

52. And now with regard to the melting of ice. On 
the surface of a flask containing a freezing mixture we 
obtain a thick fur of hoar-frost (Par.14). Sending the 
beam through a water-cell, its luminous waves are con- 
centrated upon the surface of the flask. Not aspicula 
of the frost is dissolved. We now remove the water-cell, 
and in a momenta patch of the frozen fur as large as 
half-a-crown is melted. Hence, inasmuch as the full 
beam produces this effect, and the luminous part of the 
beam does not produce it, we fix upon the dark porns 
the melting of the frost. | 

53. As before, we clench this inference by concentra- 
ting the dark waves alone upon the flask. The frost is 
dissipated exactly as it was by the full beam. 

54. These effects are rendered strikingly visible by 
darkening with ink the freezing mixture within: the 
flask. When the hoar frost is removed, the blackness 
of the surface from which it had been melted comes 
out in strong contrast with the adjacent snowy white- 
ness. When the flask itself, instead of the freezing 
mixture, is blackened, the purely luminous waves being 
absorbed by the glass, warm it; the glass reacts upon 


CLOUDS AND RIVERS, ICE AND GLACIERS. 19 


the frost, and melts it. Hence the wisdom of darkening, 
instead of the flask itself, the mixture within the flask. 

55. This experiment proves to demonstration the 
statement in paragraph (36): that it is the dark waves 
of the sun that melt the mountain snow and ice, and 
originate all the rivers derived from glaciers. 

There are writers who seem to regard science as an 
ageregate of facts, and hence doubt its efficacy as an 
exercise of the reasoning powers. But all that. 1 have 
here taught you is the result of reason, taking its sland, 
however, upon the sure basis of observation and experi- 
ment. And this is the spirit in which our further 
studies are to be pursued. 


§ 6. Oceanic Distillation. 


56. The sun, you know, is never exactly overhead in 
England. But at the equator, and within certain ]i- 
mits north and south of it, the sun at certain periods of 
the year is directly overhead at noon. These limits are 
called the Tropics of Cancer and of Capricorn. Upon 
the belt comprised between these two circles the sun’s 
rays fall with their mightiest power; for here they 
shoot directly downwards, and heat both earth and sea 
more than when they strike slantingly. 

o¢. When the vertical sunbeams strike the land they 
heat it, and the air in contact with the hot soil becomes 
heated in turn. But when heated the air expands, and 
when it expands it becomes lighter. This lighter air 


20 THE FORMS OF WATER IN 


rises, like wood plunged into water, through the heavier 
air overhead. | 

58. When the sunbeams fall upon the sea the water 
is wirmed, though not so much as the land. The 
warmed water expands, becomes thereby lighter, and 
therefore continues to float upon the top. This upper 
layer of water warms to some extent the air in contact 
with it, but it also sends up a quantity of aqueous 
vapour, which being far lighter than air, helps the 
latter to rise. Thus both from the land and from the 
sea we have ascending currents established by the 
action of the sun. 

59. When they reach a certain elevation in the 
atmosphere, these currents divide and flow, part 
towards the north and part towards the south; while 
from the north and the south a flow of heavier and 
colder air sets in to supply the place of the ascending 
warm alr. 

60. Incessant circulation is thus established in the 
atmosphere. The equatorial air and vapour flow above 
towards the north and south poles, while the polar air 
flows below towards the equator. The two currents of 
air thus established are called the upper and the lower 
trade winds. 

61. But before the air returns from the poles great 
changes have occurred. For the air as it quitted the 
equatorial regions was laden with aqueous vapour, 
which could not subsist in the cold polar regions. It is 


CLCUDS AND RIVERS, ICE AND GLACIERS. Zl 


there precipitated, falling sometimes as rain, or more 
commonly as snow. The land near the pole is covered 
with this snow, which gives birth to vast glaciers in a 
manner hereafter to be explained. 

62. It is necessary that you should have a perfectly 
clear view of this process, for great mistakes have been 
made regarding the manner in which glaciers are related 
to the heat of the sun. 

63. It was supposed that if the sun’s heat were 
diminished, greater glaciers than those now existing 
‘would be produced. But the lessening of the sun’s 
heat would infallibly diminish the quantity of aqueous 
vapour, and thus cut off the glaciers at their source. 
A brief illustration will complete your knowledge here. 

64. In the process of ordinary distillation, the hyuid 
to be distilled is heated and converted into vapour in 
one vessel, and chilled and reconverted into liquid in 
another. What has just been stated renders it plain 
that the earth and its atmosphere constitute a vast dis- 
tilling apparatus in which the equatorial ocean plays 
the part of the boiler, and the chill regions of the poies 
the part of the condenser. In this process of distilla- 
tion heat plays quite as necessary a part as cold, and 
before Bishop Heber cculd speak of ‘ Greenland’s icy 
mountains,’ the equatorial ocean had to be warmed by 
the sun. We shall have more to say upon this question 
afterwards. 


29 THE FORMS OF WATER IN 


]JLLUSTRATIVE J-XPERIMENTS. * 


65. I have said that when heated, air expands. H 
ycu wish to verify this for yourself, proceed thus. Take 
an empty flask, stop it by a cork; pass through the cork 
a narrow glass tube. By heating the tube in a spirit- 
lamp you can bend it downwards, so that when the 
flask is standing upright the open end of the narrow 
tube may dip into water. Now cause the flame of 
your spirit-lamp to play against the flask. The flame 
heats the glass, the glass heats the air; the air ex- 
pands, is driven through the narrow tube, and issues 
in a storm of bubbles from the water. 

66. Were the heated air unconfined, it would rise in 
the heavier cold air. Allow a sunbeam or any other 
intense light to fall upon a white wall or screen in a dark 
room. SBring a heated poker, a candle, or a gas flame 
underneath the beam. An ascending current rises from 
the heated body through the beam, and the action 
of the air upon the light is such as to render the 
wreathing and waving of the current strikingly visible 
upon the screen. When the air is hot enough, and there- 
fore light enough, if entrapped in a paper bag it carries 
the bag upwards, and you have the Fire-balloon. 

67. Fold two sheets of paper into two cones and 
suspend them with their closed points upwards from 
the end of a delicate balance. See that the cones 


ee 


CLOUDS AND RIVERS, ICE AND GLACIERS. 14°) 


balance each other. Then placc for a moment the 
flame of a spirit-lamp beneath the open base of one of 
them ; the hot air ascends from the lamp and instantly 
tosses upwards the cone above it. 

68. Into an inverted glass shade introduce a little 
amoke. Let the air come to rest, and then simply 
place your hand at the open mouth of the shade. 
Mimic hurricanes are produced by the air warmed by 
the hand, which are strikingly visible when the smoke 
is illuminated by a strong light. 

69. The heating of the tropical air by the sun is 
mdirect. ‘The solar beams have scarcely any power to 
heat the air through which they pass; but they heat 
the land and ocean, and these communicate their heat 
to the air in contact with them. The air and vapour 
start upwards charged with the heat thus communi- 
cated. 


§ 7. Tropical Rains. 


70. But long before the air and vapour from the 
equator reach the poles, precipitation occurs. Wherever 
a humid warm wind mixes with a cold dry one, rain 
falis. Indeed the heaviest rains occur at those places 
where the sun is vertically overhead. We must enquire 
a little more closely into their origin. 

71. Filla bladder about two-thirds full of air at the 
sea level, and take it tothe summit of Mont Blane. As 


you ascend, the bladder becomes more and more dis. 


24. THE FORMS OF WATER IN 


tended; at the top of the mountain it is fully distended, 
and has evidently to bear a pressure from within. 
Returning to the sea level you find that the tightness 
disappears, the bladder finally appearing as flaccid as 
at first. 

72. The reason is plain. At the sea level the air 
within the bladder has to bear the pressure of the 
whole atmosphere, being thereby squeezed into a com- 
paratively small volume. In ascending the mountain, 
you leave more and more of the atmosphere behind; — 
the pressure becomes less and less, and by its expansive 
force the air within the bladder swells as the outside 
pressure is diminished. At the top of the mountain 
the expansion is quite sufficient to render the bladder 
tight, the pressure within being then actually greater 
than the pressure without. By means of an air-pump 
we can show the expansion of a balloon partly filled 
with air, when the external pressure has been in part 
removed. | 

73. But why do I dwell upon this? Simply to make 
plain to you that the unconfined arr, heated at the earth’s 
surface, and ascending by its lightness, must expand 
more and more the higher it rises in the atmosphere. 

74. And now I have to introduce to you a new fact, 
towards the statement of which I have been working 
for some time. It is this:—The ascending air vs chilled 
by its expansion. Indeed this chilling is one source of 
the coldness of the higher atmospheric regions. And 


CLOUDS AND RIVEkS, ICE AND GLACIERS. 25 


now fix your eye upon those mixed currents of air and 
aqueous vapour which rise from the warm tropical ocean. 
They start with plenty of heat to preserve the vapour 
as vapour; but as they rise they come into regions 
already chilled, and they are still further chilled by 
their own expansion. The consequence might be fore- 
seen. The load of vapour is in great part precipitated, 
dense clouds are formed, their particles coalesce to 
rain-drops, which descend daily in gushes so profuse 
that the word ‘torrential’ is used to express the 
copiousness of the rain-fall. I could show you this 
cuilling by expansion, and also the consequent precipi- 
tation of clouds. 

75. Thus long before the air from the equator reaches 
the poles its vapour is in great part removed from it, 
having redescended to the earth as rain. Still a good 
quantity of the vapour is carried forward, which yields 
hail, rajn, and snow in northern and southern lands. 


ILLUSTRATIVE EXPERIMENTS. 


76. [ have said that the air is chilled during its ex- 
pansun. Prove this, if you like, thus. With a con- 
densii¢ syringe, you can force air into an iron box 
furnished with a stopcock, to which the syringe is 
screwed. Do so till the density of the air within the 
box is doubled or trebled. Immediately after this con- 
densation, both the box and the air within it are warm, 
and can be proved to be so by a proper thermometer. 


26 THE FORMS OF WATER IN 


Simply turn the cock and allow the compressed xir ta 
stream intothe atmosphere. The current, if allowed to 
strike a thermometer, visibly chills it; and with othe: 
instruments the chili may be made more evident still. 
Even the hand feels the chill of the expanding air. 

77. Throw astrong light, a concentrated sunbeam for 
example, across the issuing current; if the compressed 
air be ordinary humid air, you see the precipitation of a 
little cloud by the chill accompanying the expansion. 
This cloud-formation may, however, be better illustratea 
in the following way :— 

78. In a darkened room send a strong beam of light 
through a glass tube three feet long and three inches 
wide, stopped at its ends by glass plates. Connect the 
tube by means of a stopcock with a vessel of about one- 
fourth its capacity, from which the air has been re- 
moved by an air-pump. The exhausted cylinder of the 
pump itself will answer capitally. Fill the glass tube 
with humid air; then simply turn on the stopcock 
which connects it with the exhausted vessel. Having 
more room the air expands, cold accompanies the ex- 
pansion, and, as a consequence, a dense and brilliant 
cloud immediately fills the tube. If the experiment be 
made for yourself alone you may see the cloud in ordi- 
nary daylight; indeed, the brisk exhaustion of any 
receiver filled with humid air is known to produce this 
condensation. 

79. Other vapours than that of water may be thns 


CLOUDS AND RIVERS, ICE AND GLACIERS. QF 


precipitated, some of them yielding clouds of intense 
briliancy, and displaying iridescences, such as are some- 
times, but not frequently, seen in the clouds floating 
cver the Alps. 

80. In science what is true for the small is true for 
the large. Thus by combining the conditions observed 
on a large scale in nature we obtain ona small scale the 
phenomena of atmospheric clouds. 


§ 8. Mountain Condensers. 


81. To complete our view of the process of atmo- 
spheric precipitation we must take into account the 
action of mountains. Imagine a south-west wind 
blowing across the Atlantic towards Ireland. In its 
_ passage it charges itself with aqueous vapour. In the 
_ south of Ireland it encounters the mountains of Kerry: 
the highest of these is Magillicuddy’s Reeks, near 
Killarney. Now the lowest stratum of this Atlantic 
wind is that which is most fully charged with vapour. 
When it encounters the base of the Kerry mountains 
it is tilted up and flows bodily over them. Its load of 
vapour is therefore carried to a height, it expands on 
reaching the height, it is chilled in consequence of the 
expansion, and comes down in copious showers of rain. 
From this, in fact, arises the luxuriant vegetation of 
Killarney; to this, indeed, the lakes owe their water 
supply. The cold crests of the mountains also aid in 


the work of condensation. 
4. 


28 THE FORMS* OF WATER IN; 


82. Note the consequence. There is a town called 
Cahirciveen to the south-west of Magillicuddy’s Reeks, 
at which observations of the rainfall have been made, 
and-a good distance farther te the north-east, right in 
the course cf the south-west wind, there is another town, 
ealled Portarlington, at which observations of rainfall 
have also been made. But before the wind reaches the 
latter station it has passed over the mountains of Kerry 
and left a great. portion of its moisture behind it. 
What is the’ result? At Cahirciveen, as shown by 
Dr. Lloyd, the rainfall amounts to 59 inches in a year, 
while at Portarlington it is only 21 inches. : 

$3. Again, you may sometimes descend from the 
Alps when the fall of rain and snow is heavy and in- 
cessant, into Italy, and find the sky over.the plains of 
Lombardy blue and cloudless, the wind at the same 
time blowing over the plain towards the Alps. Below — 
the wind is hot enough to keep its vapour in a perfectly 
transparent state; but it meets the mountains, is tilted 
up, expanded, and chilled. The cold of the higher 
summits also helps the chill. The consequence is that 
the vapour is precipitated as rain or snow, thus producing 
bad weather upon the heights, while the plains below, 
flooded with the same air, enjoy the aspect of the un- 
clouded summer sun. Clouds blowing from the Alps are 
also sometimes dissolved over the plains of Lombardy 

84. In connection with the formation of clouds by 
mountains, one particularly instructive effect may he 


— °F 
| > 


CLOUDS AND RIVERS, ICE AND GLACIERS. 29 


here noticed. You frequently see a streamer of cloud 


many hundred yards in length drawn out from an 
Alpine peak. Its steadiness appears perfect, though a 
strong wind may be blowing at the same time over the 


mountain head. Why is the cloud not blown away? 


[t is blown away ; its permanence is only apparent. At 
one end it is incessantly dissolved, at the other end it 
is incessantly renewed: supply and consumption being 
thus equalized, the cloud appears as changeless as the 
mountain to which it seems to cling. When the red 
sun of the evening shines upon these cloud-streamers 
they resemble vast torches with their flames blown 
through the air. 


§ 9. Architecture of Snow. 


€5. We now resemble persons who have climbed a 
dificult peak, and thereby earned the enjoyment of a 
wide prospect. Having made ourselves masters of the 
conditions necessary to the production of mountain 
snow, we are able to take a comprehensive and intelli- 
gent view of the phenomena of glaciers. 

86. A few words are still necessary as to the forma- 
tion of snow. The molecules and atoms of all sub- 
stances, when allowed free play, build themselves into 
definite and, for the most part, beautiful forms called 
erystals. Iron, copper, gold, silver, lead, sulphur, when 
melted and permitted to cool gradually, all show this 
erystallizing power. The metal bismuth shows it in a 


30 THE FORMS OF WATER IN 


particularly striking manner, and when properly fused 
and solidified, self-built crystals of great size and beauty 
are formed of this metal. 

87. If you dissolve saltpetre in water, and allow the 
solution to evaporate slowly, you may obtain large 
crystals, for no portion of the salt is converted into 
vapour. The water of our atmosphere is fresh though it 
is derived from the salt sea. Sugar dissolved in water, 
and permitted to evaporate, yields crystals of sugar- 
eandy. Alum readily erystallizes in the same way. 
Flints dissolved, as they sometimes are in nature, and 
permitted to crystallize, yield the prisms and pyramids 
of rock crystal. Chalk dissolved and crystallized yields 
Iceland spar. The diamond is crystallized carbon. All 
our precious stones, the ruby, sapphire, beryl, topaz, 
emerald, are all examples of this crystallizing power. 

88. You have heard of the force of gravitation, and 
you know that it consists of an attraction of every 
particle of matter for every other particle. You know 
that planets and moons are held in their orbits by this 
attraction. But gravitation is a very simp!e affair com- 
pared to the force, or rather forces, of crystallization. 
For here the ultimate particles of matter, inconceivably 
small as they are, show themselves possessed of attrac- 
tive and repellent poles, by the mutual action of which 
the shape and structure of the crystal are determined. 
In the solid condition the attracting poles are rigidly 
leuecked together; but if sufficient heat be applied the 


CLOUDS AND RIVERS, ICE AND GLACIERS. 51 


bond of union is dissolved, and in the state of fusion the 
poles are pushed so far asunder as to be practically out of 
each other’s range. The natural tendency of the mole- 
cules to build themselves together is thus neutralized. 
89. This is the case with water, which as a liquid is 
to all appearance formless. When sufficiently cooled 
the molecules are brought within the play of the 
erystallizing force, and they then arrange themselves in 
forms of indescribable beauty. When snow is produced 
in calm air, the icy particles build themselves into 
beautiful stellar shapes, each star possessing six rays. 
There is no deviation from this type, though in other 
respects the appearances of the snow-stars are infinitely 
various. In the polar regions these exquisite forms 
were observed by Dr. Scoresby, who gave numerous 


: drawings of them. I have observed them in mid-winter 
_ filling the air, and loading the slopes of the Alps. But 


in England they are also to be seen, and no words of 
mine could convey so vivid an impression of their 
beauty as the annexed drawings of a few of them, 
executed at Greenwich by Mr. Glaisher. 

90. It is worth pausing to think what wonderfu: 
work is going on in the atmosphere during the forina- 
tion and descent of every snow-shower: what building 
power is brought into play! and how imperfect seem 
the productions of human minds and hands when com- 
pared with those formed by the blind forces of natu e! 

91. But who ventures to call the forces of nature 


$2 THE FORMS OF WATER IN CLOUDS, RIVERS, ETC. 


blind? In reality, when we speak thus we are describing 
our own condition. The blindness is ours; and what 
we really ought to say, and to confess, is that our powers 
are absolutely unable to comprehend either the origin 
or the end of the operations of nature. 

92. But while we thus acknowledge our limits, there 
is also reason for wonder at the extent to which science 
has mastered the system of nature. From age to age, 
and from generation to generation, fact has been added 
to fact, and law to law, the true method and order of 
the Universe being thereby more and more revealed. 
In doing this science has encountered and overthrown 
various furms of superstition and deceit, of credulity 
and imposture.- But the world continually produces 
weak persons and wicked persons; and as long as they 
continue to exist side by side, as they do in this our 
day, very debasing beliefs will also continue to infest 
the world. 


§ 10. Atomic Poles. 


93. ‘What did I mean when, a few moments ago 
(88), I spoke of attracting and repellent poles?’ Let 
me try to answer this question. You know that astro- 
nomers and geographers speak of the earth’s poles, and 
you have also heard of magnetic poles, the poles of a 
magnet being the points at which the attraction and 
repulsion of the magnet are as it were concentrated. 

94. Every magnet possesses two such poles; and if 


BA THE FORMS OF WATER IN 


iron filings be scattered over a magnet, each particle 
becomes also endowed with two poles. Suppose suck 
particles devoid of weight and floating in our atmosphere, 
what must occur when they come near each other ? 
Manifestly the repellent poles will retreat from each 
other, while the attractive poles will approach and 
finally lock themselves together. And supposing the 
particles, instead of a single pair, to possess several pairs 
of poles arranged at definite points over their surfaces ; 
you can then picture them, in obedience to their mutual 
attractions and repulsions, building themselves together 
to form masses of definite shape and structure. 

95. Imagine the molecules of water in calm cold air to 
be gifted with poles of this description, which compel the 
particles to lay themselves together in a definite order, 
and you have before your mind’s eye the unseen archi- 
tecture which finally produces the visible and beautiful 
crystals of the snow. Thus our first notions and con- 
ceptions of poles are obtained from the sight of our 
eyes in looking at the effects of magnetism; and we 
then transfer these notions and conceptions to particles. 
which no eye has ever seen. The power by which we 
thus picture to ourselves effects beyond the range of the 
senses is what philosophers call the Imagination, and 
in the effort of the mind to seize upon the unseen 
architecture of crystals, we have an example of the 
‘scientific use’ of this faculty. Without imagination 
we might have critical power, but not creatwe power in 


selence. 


CLOUDS AND RIVERS, ICE AND GLACTERS. 30D 


§ 11. Architecture of Lake Ice. 


96. We have thus made ourselves acquainted with 
tlie beautiful snow-fiowers self-constructed by the 
molecules of water in calm cold air. Do the mole- 
cules show this architectural power when ordinary 
water is frozen? What, for example, is the structure 
of the ice over which we skate in winter? Quite as 
wonderful as the flowers of the snow. The observation 
is rare, if not new, but I have seen in water slowly 
freezing six-rayed ice-stars formed, and floating free 
on the surface. A six-rayed star, moreover, is typical 
of the construction of all our lake ice. It is built up 
of such forms wonderfully interlaced. 

97. ‘Take a slab of lake ice and place it in the path 
ci a concentrated sunbeam. Watch the track of the 
beam through the ice. Part of the beam is stopped, 
part of it goes through; the former produces interna] 
liquefaction, the latter has no effect whatever upon the 
ice. But the liquefaction is not uniformly diffused. 
From separate spots of the ice little shining points are 
seen to sparkle forth. very one of those points is sur- 
rounded by a beautiful liquid flower with six petals. 

98. Ice and water are so ostically alike that unless 
the light fall properly upon these flowers you cannot 
see them. But what is the central spot? A vacuuin. 
Ice swims on water because, bulk for bulk, it is lighter 


36 THE FORMS OF WATER IN 


than water; so that when ice is melted it shrinks in 
size. Can the liquid flowers then occupy the whole 
space of the ice melted? Plainly no. A little empty 
space is formed with the flowers, and this space, or 
rather its surface, shines in the sun with the lustre of 
burnished silver. 

99. In all cases the flowers are formed parallel to 
the surface of freezing. They are formed when the 
sun shines upon the ice of every lake; sometimes in 
myriads, and so small as to require a magnifying glass 
to see them. ‘They are always attainable, but their 
beauty is often marred by internal defects of the ice. 
Even one portion of the same piece of ice may show 
them exquisitely, while a second portion shows them 
imperfectly. 

100. Annexed is a very imperfect sketch of these 
beautiful figures. | 

101. Here we have a reversal of the process of 
crystallization. The searching solar beam is delicate 
enough to take the molecules down without deranging 
the order of their architecture. Try the experiment for 
yourself with a pocket-lens on a sunny day. You will 
not find the flowers confused; they all le parallel to 
the surface of freezing. In this exquisite way every 
bit of the ice over which our skaters glide in winter is 
nut together. | 

102. I said in (97) that a portion of the sunbeam was 
stopped by the ice and liquefied 1%. What is this 


CLOUDS AND RIVERS, ICE AND GLACIERS. Oo” 


portion? The dark heat of the sun. The great body 
of the light waves and even a portion of the dark ones, 


LIQUID FLOWERS IN LAKE ICE, 


pass through the ice without losing any of their heating 
power. When properly concentrated on combustible 
bodies, even after having passed through the ice, their 
burning power becomes manifest. 

103. And the ice itself may be employed to con- 
centrate them. With an ice-lens in the polar regions 

Dr. Scoresby has often concentrated the sun’s rays so 
as to make them burn wood, fire gunpowder, and melt 
lead; thus proving that the heating power is retained 
by the rays, even after they have passed through so cold 
a substance. 

104. By rendering the rays of the electric lamp 
parallel, and then sending them through a lens of ice, 
we obtain all the effects which Dr. Scoresby obtained 
with the rays of the sun. | 


38 THE FORMS OF WATER IN 


§ 12. The Source of the Arveiron. Ice Pinnacles, Towers, 
and Chasms of the Glacier des Bois. Passage 
to the Montanvert. 


105. Our preparatory studies are for the present 
ended, and thus informed, let us approach the Alps. 
Through the village of Chamouni, in Savoy, a river 
rushes which is called the Arve. Let us trace this 
river backwards from Chamouni. At a little distance 
from the village the river forks ; one of its branches still 
continues to be called the Arve, the other is the Arvei- 
ron. Following this latter we come to what is called 
the ‘ source of the Arveiron ’"—a short hour’s walk from 
Chamouni. Here, as in the case of the Rhone already 
referred to, you are fronted by a huge mass of ice, the 
end of a glacier, and from an arch in the ice the Ar- 
veiron issues. Do not trust the arch in summer. Its 
roof falls at intervals with a startling crash, and would 
infallibly crush any person on whom it might fall. 

106. We must now be observant. Looking about us 
here, we find in front of the ice curious heaps and ridges 
of débris, which are more or less concentric. These are 
the terminal moraines of the glacier. We shall examine 
them subsequently. 

107. We now turn to the left, and ascend the slope 
beside the glacier. As we ascend we get a better view, 
and find that the ice here fills a narrow valley. We 


CLOUDS AND RIVERS, ICE AND GLACIERS. 39 


come upon another singular ridge, not of fresh débris, 
like those lower down, but covered in part with trees, 
and appearing to be literally as ‘ old as the hills.’ It 
tells a wonderful tale. We soon satisfy ourselves that 
the ridge is an ancient moraine, and at once conclude 
that the glacier, at some former period of its existence, 


SOURCE OF THE ARVEIRON. 


was vastly larger than it is now. This old moraine 
stretches right across the main valley, and abuts against 
the mountains at the opposite side. 

108. Having passed the terminal portion of the 
glacier, which is covered with stones and rubbish, we 


find ourselves beside a very wonderful exhibition of ice. 


AQ) THE FORMS OF WATER IN 


The glacier descends a steep gorge, and in doing so is 
riven and broken in the most extraordinary manner. 
Here are towers, and pinnacles, and fantastic shapes 
wrought out by the action of the weather, which put 
one in mind of rude sculpture. Annexed is a sketch 
of an ice-pinnacle. . From deep chasms in the glacier 


ICE-PINNACLE. 


issues a delicate shimmer of blue light. At times we 
hear a sound like thunder, which arises either from 
the falling of a tower of ice, or from the tumble of a 
huge stone intoa chasm. The olacier maintains this 
wild and chaotic character for some time; and the best 


CLOUDS AND RIVERS, ICE AND GLACIERS. Al 


iceman would find himself defeated in any attempt to 
get along it. 

109. We reach a place called the Chapeau, where, if 
we wish, we can have refreshment in a little mountain 
hut. We then pass the Mauvais Pas, a precipitous 
rock, on the face of which steps are hewn, and the un- 
practised traveller is assisted by a rope. We pursue 
our journey, partly along the mountain side, and partly 
along a ridge of singularly artificial aspect--a lateral 
moraine. We at length face a house perched upon an 
eminence at the opposite side of the glacier. This is 
the auberge of the Montanvert, well known to all 
visitors to this portion of the Alps. 

110. Here we cross the glacier. I should have told 
you that its lower part, including the broken portion 
we have passed, is called the Glacier des Bois; while 
the place that we are now about to cross is the be- 
ginnins Gf the Mer de Glace. You feel that this term 
is not quite appropriate, for the glacier here is much 
more like a river of ice than a sea. The valley which 
it fills is about half a mile wide. 7 

111. The ice may be riven where we enter upon it, 
but with the necessary care there is no difficulty in 
crossing this portion of the Mer de Glace. The clefts 
and chasms in the ice are called crevasses; we s)iall 
make their acquaintance on a grander scale by and by. 

112. Look up and down this side of the glacier. It 
is considerably riven, but as we advance the crevasses 


NOW ONLIMOHS SAOVID AC UAW AHL 


“aT PVALSIVA 


THE FORMS OF WATER IN CLOUDS, RIVERS, ETC. 43 


will diminish, and we shall find very few of them at 
the other side. Note this for future use. The ice is at 
first dirty ; but the dirt soon disappears, and you come 
upon the clean crisp surface of the glacier. You have 
already noticed that the clean ice is white, and that 
from a distance it resembles snow rather than ice. This 
is caused by the breaking up of the surface by the 
solar heat. When you pound transparent rock-salt 
into powder it is as white as table-salt, and it is the 
minute. fissuring of the surface of the glacier by the 
sun’s rays that causes it to appear white. Within the 
glacier the ice is transparent. After an exhilarating 
passage we get upon the opposite lateral moraine, and 
ascend the steep slope from it to the Moutanvert Inn. 


§ 15. The Mer de Glace and its Sources. Our First. 
Climb to the Cleft Station. 


113. Here the view before us is very grand. We 
look across the glacier at the beautiful pyramid of the 
Aiguille du Dru (shown in our frontispiece) ; and to the 
right at the Aiguille des Charmoz, with its sharp pin- 
nacles bent as if they were ductile. Looking straight, 
up the glacier the view is bounded by the great crests 
called La Grande Jorasse, nearly 14,000 feet high. 
Onur object now is to get into the very heart of the 
mountains, and to pursue to its-origin the wonderful 


frozen river which we have just crossed. 
5) 


4.4, THE FOKMS OF WATER IN 


114. Starting from the Montanvert with the glacier 
below us to our left, we soon reach some rocks resem- 
bling the Mauvais Pas; they are called les Ponts. We 
cross them and reach l’ Angle, where we quit the land for 
the ice. We walk up the glacier, but before reaching 


the promontory called Trélaporte, we take once more to 
the mountain side; for though the path here has been 
forsaken on account of its danger, for the sake of know- 
ledge we are prepared to incur danger to a reasonable 
extent. A little glacier reposes on the slope to our 
right. We may see a huge boulder or two poised on 
the end of the glacier, and, if fortunate, also see the 
boulder liberated and plunging violently down the slope. 
Presence of mind is all that is necessary to render our 
safety certain; but travellers do not always show pre- 
sence of mind, and hence the path which formerly led 
over this slope has been forsaken. ‘The whole slope is 
cumbered by masses of rock which this little glacier has 
sent down. These I wished you to see; by and by 
they shall be fully accounted for. | 

115. Above Trélaporte to the right you see a most 
singular cleft in the rocks, in the middle of which 
stands an isolated pillar, hewn out by the weather. 
Onr next object is to get to the tower of rock to the lett 
of that cleft, for from that position we shall gain a 
most commanding and instructive view of the Mer de 
Glace and its sources. 

116. The cleft referred to, with its pillar, may bh. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 45 


secu to the richt of the preceding engraving of the Mer 
de Glace. Below the cleft is also seen the little glacier 
just referred to. 

117. We may reach this cleft by a steep gully, visible 
from our present position, and leading directly up 
to the cleft. But these gullies, or couloirs, are very 
dangerous, being the pathways of stones falling from 
the heights. We will therefore take the rocks to the 
Jeft of the gully, by close inspection ascertain their as- 
sallable points, and there attack them. In the Alps 
as elsewhere wonderful things may be done by looking 
steadfastly at difficuities, and testing them wherever 
they appear assailable. We thus reach our station, 
where the glory of the prospect, and the insight that 
ve gain as to the formation of the Mer de Glace, far 
more than repay us for the labour of our ascent. 

118. For we see the glacier below us, stretching its 
frozen tongue downwards past the Montanvert. And 
we now find this single glacier branching out into three 
others, some of them wider than itself. Regard the 
branch to the right, the Glacier du Géant. It stretches 
smoothly up for a long distance, then becomes disturbed, 
and then changes to a great frozen cascade, down which 
the ice appears to tumble in wild confusion. Above 
the cascade you see an expanse of shining snow, oc- 
cupying an area of some square miles. 


16 THE FORMS OF WATER IN 


§ 14. Ice-cascade and Snows of the Col du Géant. 


119. Instead of climbing to the height where we now 
siund, we might have continued our walk upon the Mer 
de Glace, turned round the promontory of Trélaporte, 
and walked right up the Glacier du Géant. We should 
have found ice under our feet up to the bottom of the 
cascude. It is not so compact as the ice lower down, 
but you would not think of refusing to call it ice. 

120. As we approach the fall, the smooth and un- 
broken character of the glacier changes more and more. 
We encounter transverse ridges succeeding each other 
with augmenting steepness. The ice becomes more 
and more fissured and confused. We wind through 
tortuous ravines, climb huge ice-mounds, and creep 
cautiously along crumbling crests, with crevasses right 
and left. The confusion increases until further advance 
along the centre of the glacier is impossible. 

121. But with the aid of an axe to cut steps in the 
steeper ice-walls and slopes we might, by swerving to 
either side of the glacier, work our way to the top of 
the cascade. If we ascended to the right, we shonld 
have to take care of the ice avalanches which sometimes 
thunder down the slopes; if to the left, we should have 
to take care of the stones let loose from the Aiguille 
Noire. After we had cleared the cascade, we should 
have to beware for a time of the crevasses, which fur 


CLOUDS AND RIVERS, ICE AND GLACIERS. AG 


some distance above the fall yawn terribly. But by 
cauticn we could get round them, and sometimes cross 
them by bridges of snow. Here the skill and know- 
ledge to be acquired only by long practice come’ into 
play; and -here also the use of the Alpine rope sug- 
gests itself. For not only are the snow bridges often 
frail, but whole crevasses are sometimes covered, the 
unhappy traveller being first made aware of their exist- 
exce by the snow breaking under his feet. Many lives 
have thus been lost, and some quite recently. 

122. Once upon the plateau above the ice-fall we 
and the surface totally changed. Below the fall we 
walked upon ice; here we are upon snow. After a 
gentle but long ascent we reach a depression of the 
ridge which bounds the snow-field at the top, and now 
look over Italy. We stand upon the famous Ool du 
Géant. 

123. They were no idle scamperers on the mountains 
that made these wild recesses first known; 1t was not 
the desire for health which now brings some, or the 
desire for grandeur ana beauty which brings others, or 
the wish to be able to say that they have climbed a 
mountain or crossed a col, which I fear brings a good 
many more; it was a desire for knowledge that brought 
the first explorers here, and on this col the celebrated 
De Saussure lived for seventeen days, making scientific 
observations. 


4% THE FORMS OF WATER IN 


§ 15. Questioning the Glacters. 


124. I would now ask you to consider for a een 
the facts which such an excursion places in our posses- 
sion. The snow through which we have in idea trudged 
is the snow of last winter and spring. Had we placed ~ 
last August a proper mark upon the surface of the 
snow, we should find it this August at a certain depth 
beneath the surface. A good deal has been melied 
by the summer sun, but a good deal of it remains, and 
it will continue until the snows of the coming winter 
fall and cover it. ‘This again will be in part preserved 
till next August, a good deal of it remaining until it is 
covered by the snow of the subsequent winter. We thus 
arrive at the certain conclusion that on the plateau 
of the Col du Géant the quantity of snow that falls 
annually exceeds the quantity melied. 

125. Had we come in the month of April or May, we 
should have found the glacier below the ice-fall also 
covered with snow, which is now entirely cleared away 
by the heat of summer. Nay, more, the ice there is 
obviously melting, forming running brooks which cut 
channels in the ice, and expand here and there into 
small blue-green lakes. Hence you conclude with 
certainty that below the ice-fall the quantity of frozen 
material falling upon t the glacier is less than the quantity 
melted, 


126. And this forces upon us another conclusion: 


CLOUDS AND RIVERS, ICE AND GLACIERS, AY 


between the glacier below the ice-fall and the plateau 
above it there must exist a line where the quantity ot 
snow which falls zs exactly equal to the quantity annually 
melted. This is the snow-line. On some glaciers it is 
yuite distinct, and it would be distinct here were the 
ice less broken and confused than it actually is. 

127. The French term névé is applied to the glacial 
region above the snow-line, while the word glacier is 
restricted to the ice belowit. Thus the snows of the 
Col du Géant constitute the névé of the Glacier du 
Géant, and in part, the névé of the Mer de Glace. 

123. But if every year thus leaves a residue of snow 
upon the plateau of the Col du Géant, it necessarily fol- 
lows that the plateau must get annually higher, pro- 
vided the snow remain upon it. Equally certain is the 
conclusion that the whole length of the glacier below 
the cascade must sink gradually lower, if the waste of 
annual melting be not made good. Supposing two feet of 
snow a year to remain upon the Col, this would raise 
it to a height far surpassing that of Mont Blanc in 
five thousand years. Such accumulation must take place 
if the snow remain upon the Col; but the accumulation 
dues not take place, hence the snow does not remain 
on the Col. The question then is, whither does it go? 


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THE FORMS OF WATER IN 


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CLOUDS AND RIVERS ICE AND GLACIERS. ol] 


§ 16. Branches and Medial Moraines of the Mer de Ulace 
from the Cleft Station. 


129. We shall grapple with this question immediately. 
Meanwhile look at that ice-vailey in front of us, stretch- 
ing up between Mont Tacu! and the Aiguille de Léchaud, 
to the base of the great ridge called the Grande Jorasse. 
This is called the Glacier de Léchaud. It receives at 
its head the snows of the Jorasse and of Mont Mallet, 
and joins the Glacier du Géant at the promontory of 
the Tacul. ‘The glaciers seem welded together where 
they join, but they continue distinct. Between them 
you clearly trace a stripe of débris (c on the annexed 
sketch-plan); you trace a similar though smaller stripe 
(a on the sketch), from the junction of the Glacier 
du Géant with the Glacier des Périades at the foot of 
the Aiguille Noire, which you also follow along the Mer 
de Glace. 

130. We also see another glacier, or a portion of it, 
to the left, falling apparently in broken fragments 
through a narrow gorge (Cascade du Taléfre on the 
sketch) and joining the Léchaud, and from their point 
of junction also a stripe of débris (d) runs downwards 
along the Mer de Glace. . Beyond this again we notice 
another stripe (e), which seems to begin at the bottom 
of the ice-fall, rising as it were from the body of the 
glacier. Beyond all of these we can notice the lateral 
moraine of the Mer de Glace. 


52 THE FORMS OF WATER IN 


131. These stripes are the medial moraines of the 
Mer de Glace. We shall learn more about them im- 
mediately. | 

132. And now, having informed our minds by these 
observations, let our eyes wander over the whole glo- 
rious scene, the splintered peaks and the hacked and 
jagged crests, the far-stretching snow-fields, the smaller 


elaciers which nestle on the heights, the deep blue ~ 


heaven and the sailing clouds. Is it not worth some 
labour to gain command of such a scene? But the 
delight it imparts is heightened by the fact that we 
did not come expressly to see it; we came to instruct 
ourselves about the glacier, and this high enjcyment is 
an incident of our labour. You will find it thus 
through life; without honest labour there can be no 
deep joy. 


(§17. The Taléfre and the Jardin. Work among the 


Orevasses. 


133. And now let us descend to the Mer de Glace, 
fo~ | want to take you across the glacier to that broken 
ice-fall the origin of which we have not yet seen. We 
aim at the farther side of the glacier, and to reach it 
we must cross those dark stripes of débris which we 
observed from the heights. Looked at from above, these 
moraines seemed flat, but now we find them to be 
ridges of stones and rubbish, from twenty to thirty feet 
high, 


CLOUDS AND RIVERS, ICE AND GLACIERS. Od 


134. We quit the ice at a place called the Couverele, 
and wind round this promontory, ascending all tlie 
time. We squeeze ourselves through the Egralets, a 
kind of natural staircase in the rock, and soon afterwards _ 
obtain a full view of the ice-fall, the origin of which 
we wish to find. The ice upon the fallis much broken; 
we have pinnacles and towers, some erect, some lean- 
ing, and some, if we are fortunate, falling like those 
upon the Glacier des Bois; and we have chasms from 
which issues a delicate blue light. With the ice-fall to 
our right we continue to ascend, until at length we 
command a view of a huge glacier basin, almost level, 
and on the middle of which stands a solitary island, 
entirely surrounded by ice. We stand at the edge of 
the Glacier du Taléfre, and connect it with the ice-fall 
we have passed. The glacier is bounded by rocky 
ridges, hacked and torn at the top into teeth and edges, 
and buttressed by snow fluted by the descending stones. 

135. We cross the basin to the central island, and 
find grass and flowers at the place where we enter upon 
it. This is the celebrated Jardin, of which you have 
often heard. The upper part of the Jardin is bare rock. 
Close at hand is one of the noblest peaks in this portion 
of the Alps, the Aiguille Verte. It is between thirteen 
and fourteen thousand feet high, and down its sides, 
after freshly -fallen snow, avalanches incessantly thunder. 
From one of its projections a streak of moraine starts 
down the Taléfre ; from the Jardin also a similar streak 


D4, THE FORMS OF WATER IN 


of moraine issues. Both continue side by side to the 
top of the ice-fall, where they are engulphed in the 
chasms. But at the bottom of the fall they reappear, 
as if newly emerging from the body of the glacier, and 
afterwards they continue along the Mer de Glace. 

136. Walk. with me now alongside the moraine from 
the Jardin down towards the ice-fall. For a time our 


work is easy, such fissures as appear offering no impe- | 


diment to our march. But the crevasses become 
gradually wider and wilder, following each other at 


length so rapidly as to leave merely walls of ice between 


them. Here perfect steadiness of foot is necessary—a 
slip would be death. We look towards the fall, and 
observe the confusion of wails and blocks and chasms 
velow us increasing. At length prudence and reason 
cry ‘Halt!’ We may swerve to the right or to the 
left, and making our way along crests of ice, with 
chasms on both hands, reach either the right lateral 
moraine or the left lateral moraine of the glacier. 


§ 18. First Questions regarding Glacrer Motion. Drift- 
ing of Bodies buried in a Crevasse. | 


137. But what are these lateral moraines? As you 
and I go from day to day along the glaciers, their 
origin is gradually made plain. We sce at intervals 
the stones and rubbish descending from the mountain 
sides and arrested by the ice. All along the fringe of 
the glacier the stones and rubbish fall, and it soon 


CLOUIS AND RIVERS, ICE AND GLACIERS. 55 


becomes evident that we have here the source of the 
lateral moraines. 

138. But how are the medial moraines to be ac- 
counted for? How does the débris range itself upon the 
glacier in stripes some hundreds of yards from its edge, 
leaving the space between them and the edge clear of 
rubbish ? Some have supposed the stones to have rolled 
over the glacier from the sides, but the supposition will 
not bear examination. Call to mind now our reasoning 
regarding the excess of snow which falls above the 
snow-line, and our subsequent question, How ‘is the 
snow disposed of. Can it be that the entire mass is | 
moving slowly downwards? If so, the lateral moraines 
would be carried along by the ice on which they rest, 
and when two branch glaciers unite they would lay 
their adjacent lateral moraines together to form a medial 
moraine upon the trunk glacier. 

139. There is, in fact, no way that we can see of dis- 
posing of the excess of snow above the snow-line; there 
is no way of making good the constant waste of the 
ice below the snow-line; there is no way of accounting 
for the medial moraines of the glacier, but by supposing 
that from the highest snow-fields of the Col du Géant, 
the Léchaud, and the Taléfre, to the extreme end of the 
Glacier des Bois, the whole mass of frozen matter is 
moving downwards. 

140. If you were older, it would give me pleasure to 
take you up Mont Blanc. Starting from Chamouni, we 


56 THE FORMS OF WATER IN 


should first pass through woods and pastures, then up. 
the steep hill-face with the Glacier des Bossons to our 
right, to a rock known as the Prerre Pointue; thence 
to a higher rock called the Pierre l Echelle, because here 
a ladder is usually placed to assist in crossing the 
chasms of the glacier. At the Pierre l’Echelle we 
should strike the ice, and passing under the Aiguille du 
Midi, which towers to the left, and which sometimes 
sweeps a portion of the track with stone avalanches, we 
should cross the Glacier des Bossons; amid heaped-up 
mounds and broken towers of ice; up steep slopes ; over 
chasms so deep that their bottoms are hid in darkness. 

141. We reach the rocks of the Grands Mulets, which 
form a kind of barren islet in the icy sea; thence 
to the higher snow-fields, crossing the Pett Plateau, 
which we should find cumbered by blocks of ice. 
Looking to the right, we should see whence they came, 
for rising here with threatening aspect high above us 
are the broken ice-crags* of the Dome du Gouté. The 
guides wish to pass this place in silence, and it is just 
as well to humour them, however much you may doubt 
the competence of the human voice to bring the ice- 
crags down. From the Petit Plateau a steep snow-slope 
would carry us to the Grand Plateau, and at day-dawn 
I know nothing in the whole Alps more grand and 
solemn than this place. 


' #* Named seracs from their resemblance in shape and colour to an inferky 
kind of curdy cheese eailed vy this name at Chamouni. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 57 


142. One object of our ascent would be now attained ; 
for here at the head of the Grand Plateau, and at the 
foot of the final slope of Mont Blanc, I should show you 
a great crevasse, into which three guides were poured 
by an avalanche in the year 1820. 

143. Is this language correct? A crevasse hardly 


CREVASSE ON GRAND PLATEAU. 


to be distinguished from the present one undoubted!y 
existed here in 1820. But was it the identical crevasse 
now existing? Is the ice riven here to-day the same 
as that riven fifty-one yearsago? Bynomeans. How 
is this proved? By the fact that more than forty years 
after their interment, the remains of those three cuides 


58 THE FORMS OF WATER IN 


were found near the end of the Glacier des Bossons, many 
miles below the existing crevasse. 

144. The same observation proves to demonstratiou 
that it is the ice near the bottom of the higher névé 
that becomes the surface-ice of the glacier near its end. 
The waste of the surface below the snow-line brings 
the deeper portions of the ice more and more to the 
light of day. | 

145. There are numerous obvious indications of the 
existence of glacier motion, though it is too slow to 
catch the eye at once. The crevasses change within 
certain limits from year to year, and sometimes from 
month to month; and this could not be if the ice did 
not move. Rocks and stones also are observed, which 
have been plainly torn from the mountain sides. Blocks 
seen to fall from particular points are afterwards 
observed lower down. On the moraines rocks are 
found of a totally different mineralogical character from 
those composing the mountains right and left; and in 
all such cases strata of the same character are found 
bordering the glacier higher up. Hence the conclusion 
that the foreign boulders have been floated down by 
theice. Further, the ends or ‘ snouts’ of many glaciers 
act like ploughshares on the land in front of them, 
overturning with slow but merciless energy huts and 
chalets that stand in their way. Facts like these 
have been long known to the inhabitants of the High 


CLOUDS AND RIVERS, ICE AND GLACIERS. 09 


Aips, who were thus made acquainted in a vague and 
general way with the motion of the glaciers. 


§ 19. The Motion of Glaciers. Measurements by Hug: 
and Agassiz. Drifting of Huts on the ice. 


146. But the growth of knowledge is from vagueness 
towards precision, and exact determinations of the rate 
of glacier motion were soon desired. With refer- 
ence to such measurements one glacier in the Bernese 
Oberland will remain for ever memorable. From the 
little town of Meyringen in Switzerland you proceed 
up the valley of Hasli, past the celebrated waterfall of 
Handeck, where the river Aar plunges into a chasm 
more than 200 feet deep. You approach the Grimsel 
Pass, but instead of crossing it you turn to the right and 
follow the course of the Aar upwards. Like the Rhone 
and the Arveiron, you find the Aar issuing from a glacier. 

147. Get upon the ice, or rather upon the deep 
moraine shingle which covers the ice, and walk upwards. 
It is hard walking, but after some time you get clear 
of the rubbish, and on to a wide glacier with a great 
medial moraine running along its back. This moraine 
is formed by the junction of two branch glaciers, the 
Lauteraar and the Finsteraar, which unite at a pro- 
montory called the Abschwung to form the trunk 
glacier of the Unteraar. 

148. On this great medial moraine in 1827 an intrepid 


6 


60 THE FORMS OF WATER IN 


and enthusiastic Swiss professor, Hugi, of Solothurm 
(French Soleure), built a hut with a view to observa- 
tions upon the glacier. His hut moved, and he 
measured its motion. Ir the three years—from 1827 
to 1830—it had moved 330 feet downwards. In 18386 
it had moved 2,354 feet; and in 1841 M. Agassiz found 
it 4,712 feet below its first position. 

149. In 1840, M. Agassiz himself and some bold 
companions took shelter under a great overhanging 
slab of rock on the same moraine,'to which they added 
side walls and other means of protection. And because 
he and his comrades came from Neufchatel, the hut 
was called long afterwards the ‘ Hétel des Neuchatelois.’ 
Two years subsequent to its erection M. Agassiz found 
that the ‘hotel’ had moved 486 feet downwards. 


§ 20. Precise Measurements of Agassiz and Forbes. 
Motion of a Glacier proved to resemble the Motion 
of a Raver. 


150. We now approach an epoch in the scientific 
history of glaciers. Had the first observers been 
practically acquainted with the instruments of pre- 
cision used in surveying, accurate measurements of the 
motion of glaciers would probably have been earlier 
executed. We are now on the point of seeing such 
instruments introduced almost simultaneously by M. 
Agassiz on the glacier of the Unteraar, and by Professor 
Forbes on the Mer de Glace. Attempts had been made 


CLOUDS AND RIVERS, ICE AND GLACIERS. 61 


py M. Escher de la Linth to determine the motion of 
a series of wooden stakes driven into the Aletsch 
glacier, but the melting was so rapid that the stakes 
soon fell. To remedy this, M. Agassiz in 1841 under- 
took the great labour of carrying boring tools to his 
‘hotel,’ and piercing the Unteraar elacier at six different 
places to a depth of ten feet, in a straight line across 
the glacier. Into the holes six piles were so firmly 
driven that they remained in the glacier for a year, and 
in 1842 the displacements of all six were determined. 
They were found to be 160 feet, 225 feet, 269 feet, 24¢ 
feet, 210 feet, and 125 feet, respectively. 

151. A great step is here gained. You notice that 
the middle numbers are the largest. They correspond 
to the central portion of the glacier. Hence, these 
measurements conclusively establish, not only the fact 
of glacier motion, but that the centre of the glacier, like 
that of a river, moves more rapidly than the sides. 

152. With the aid of trained engineers M. Agassiz 
followed up these measurements in subsequent yeatfs. 
His researches are recorded in a work entitled ‘ Systéme 
glaciaire,’ which is accompanied by a very noble Atlas 
of the Glacier of the Unteraar, published in 1847. 

153. These determinations were made by means of a 
theodolite, of which I will give you some notion im- 
mediately. The same instrument was employed the 
same year by the late Principal Forbes upon the Mer de 
(zlace. He established independently the greater central] 


62 THE FORMS OF WATER IN 


motion. He showed, moreover, that it is not necessary 
to wait a year, or even a week to determine the motion 
of a glacier; with a correctly-adjusted theodolite he 
was able to determine the motion of various points of 
the Mer de Glace from day to day. He affirmed, and 
with truth, that the motion of the glacier might be 
determined from hour to hour. We shall prove this 
farther on (162). Professor Forbes also triangulated 
the Mer de Glace, and laid down an excellent map of 
it. His first observations and his survey are recorded 
in a celebrated book published in 1843, and entitled 
‘Travels in the Alps.’ 

154, These observations were also followed up in 
subseauent years, the results being recorded in a series 
of detached letters and essays of great interest. These 
were subsequently collected in a volume entitled ‘ Occa- 
sional Papers on the Theory of Glaciers,’ published in 
1859. The labours of Agassiz and Forbes are the two 
chief sources of our knowledge of glacier phenomena. 


§ 21. The Theodolite and rts Use- Our own 
Measurements. 


155. My object thus far is attained. I have given 
you proofs of glacier motion, and a historic account of 
its measurement. And now we must try to add a 
little to the knowledge of glaciers by our own labours 
on the ice. Resolution must not be wanting at the 
commencement of our work, nor steadfast patience 


CLOUDS AND RIVERS, ICE AND GLACIERS. 63 


during its prosecution. Look then at this theodolite; 
it consists mainly of a telescope and a graduated circle, © 
the telescope capable of motion up and down, and the 
circle, carrying the telescope along with it, capable of 
motion right and left. When desired to make the - 
motion exceedingly fine and minute, suitable screws, 
called tangent screws, are employed. The instrument 
is supported by three legs, movable, but firm when 
properly planted. 

_ 156. Two spirit-levels are fixed at right angles to 
each other on the circle just referred to. Practice 
enables one to take hold of the legs of the instrument, 
and so to fix them that the circle shall be nearly 
horizontal. By means of four levelling screws we 
render it accurdtely norizontal. Exactly under the 
centre of the instrument is a small hook from which a 
plummet is suspended; the point of the bob just 
touches a rock on which we make a mark; or if the 
earth be soft underneath, we drive a stake into it 
exactly under the plummet. By re-suspending the 
plummet at any future time we can find to a hairbreadth 
the position occupied by the instrument to-day. 

157. Look through the telescope; you see it crossed 
by two fibres of the finest spider’s thread. In actual 
work we first direct the telescope across the glacier, 
until the intersection of the two fibres accurately 
covers some well-defined point of rock or tree at the other 
side of the valley. This, our fixed standard, we sketch 


64 THE FORMS OF WATER IN 


with its surroundings in a note-book, so as to be able 
immediately to recognise it on our return to this place. 
Imagine a straight line drawn from the centre of the 
telescope to this point, and that this line is permitted 
to drop straight down upon the glacier, every point of 
it falling as a stone would fall; alone such a line we 
have now to fix a series of stakes. | 

158. A trained assistant is already upon the glacier. 
He erects his staff and stands behind it; the telescope 
is lowered without swerving to the right or to the 
left; in mathematical language it remains in the same 
vertical plane. ‘The crossed fibres of the telescope 
probably strike the ice a little away from the staff of 
the assistant ; by a wave of the arm he moves right or 
left; he may move too much, so we wave him back 
again. After a trial or two he knows whether he is 
near the proper point, and if so makes his motions 
small. He soon exactly strikes the point covered by 
the intersection of the fibres. A signal is made which 
tells him that he is right; he pierces the ice with an 
auger and drives in astake. He then goes forward, and 
in precisely the same manner takes up another point. 
After one or two stakes have been driven in, the 
assistant is able to take up the other points very 
rapidly. Any requisite number of stakes may thus be 
fixed in a straight line across the glacier. : 

159. Next morning we measure the motion of all the 
stakes. The theodolite is mounted in its former posi- 


CLOUDS AND RIVERS, ICE AND GLACIERS. 65 


tion and carefully levelled. The telescope is directed 
first upon the standard point at the opposite side of 
the valley, being moved by a tangent screw until the 
intersection of the spider’s threads accurately covers 
the point. The telescope is then lowered to the 
first stake, beside which our trained assistant 1s 
already standing. He is provided with a staff with 
feet and inches marked on it. A glance shows us 
that the stake has moved down. By our signals the 
assistant recovers the point from which we started 
yesterday, and then determines the distance from this 
point to the stake. It is, say, 6 inches; through 
this distance, therefore, the stake has moved. 

160. We are careful to note the hour and minute at 
which each stake is driven in, and the hour and the 
minute when its distance from its first position is 
measured; this enables us to calculate the accurate 
daily motion of the point in question. The distances 
through which all the other points have moved are 
determined in precisely the same way. 

161. Thus we shall proceed to work, first making 
clear to our minds what is to be done, and then making 
sure that it shall be accurately done. To give our work 
reality, I will here record the actual measurements 
executed, and the actual thoughts suggested, on the 
Mer de Glace in 1857. The only unreality that 1 
would ask you to allow, is that you and I are supposed 
to be making the observations together. The labour 


60 THE FORMS OF WATER IN 


of measuring was undertaken for the most part by 
Mr. Hirst. 


§ 22. Motion of the Mer de Glace. 


162. Ou July 14, then, we find ourselves at the end 
uf the Glacier des Bois, not far from the source of the 
Arveiron. We direct our telescope across the glacier, 
and fix the intersection of its spider’s threads accu- 
rately upon the edge of a pinnacle of ice. We leave the 
instrument untouched, looking through it from hour 
to hour. The edge of ice moves slowly, but plainly, 
past the fibres, and at the end of three hours we assure 
ourselves that the motion has amounted to several 
inches. While standing near the vault of the Arveiron, 
and talking about going into it, its roof gives way, and 
falls with the sound of thunder. It is not, therefore, 
without reason that I warned you against entering 
these vaults in summer. 

163. We ascend to the Montanvert Inn, fix on it as 
a residence, and then descend to the lateral moraine of 
the glacier a little below the inn. Here we erect our 
_theodolite, and mark its exact position by a plummet. 
We must first make sure that our line is perpendicular, 
or nearly so, to the axis or middle line of the glacier. 
Our instructed assistant lays down a long staff in the 
direction of the axis, assuring himself, by looking up and 
down, that it is the true direction. With another staff 
in his hand, pointed towards our theodolite, he shifts 
his position until the second staffis perpendicular to the 


CLOUDS AND RIVERS, ICE AND GiACIERS. O71 


first. Here he gives usa signal. We direct cur iele- 
scope upon him, and then gradually raising its end in a 
vertical plane we find, and note by sketching, a standard 
point at the other side ofthe glacier. This point known, 
and our plummet mark known, we can on any future 
day find our line. (‘To render the measurements more 
intelligible, [ append on the next page an outline dia- 
gram of the Mer de Glace, and of its tributaries.) 

164. Along the line just described ten stakes were set 
on July 17,1857. Their displacements were measured 
on the following day. Two of them had fallen, but 
here are the distances passed over by the eight re- 
maining ones in twenty-four hours. 


DAILY MOTION OF THE MER DE GLACK. 


First Line: AA! upon THE SKETCH. 


East West 
perietee ee ee ote Ae ES OIG 
fackon 2 -.-9. (12 17. 28.. 26°25 26° 27. 33 


165. You have already assured yourself by x tual 
contact that the body of the glacier is real ice, and you 
may have read that glaciers move; but the actual 
observation of the motion of a body apparently so rigid 
is strangely interesting. And not only does the ice . 
move bodily, but one part of it moves past another ; 
the rate of motion augmenting gradually from 12 
inches a day at the side to 383 inches a day at a 
distance from the side. This quicker movement of the 
central ice of glaciers had been already observed by 


Col du 
Geant. 


Grande Jorasse. ‘ 


¢ 


Talefre. 


Trélaporte. 


Angle. 


Les Ponts. 


Chapeau. 


OUTLINE PLAN, SHOWING THE MEASURED LINES OF THE MER DE GLACE AND 
ITS TRIBUTARIES, 


THE FORMS OF WATER IN CLOUDS, RIVERS, ETC. 69 


Agassiz and Forbes; we verify their results, and now 
proceed to something new. Crossing the Glacier du 
Géant, which occupies more than half the valley, we 
find that our line of stakes is not yet at an end. The 
{0th stake stands on the part of the ice which comes 
from the Taléfre. , 

166. Now the motion of the sides is slow, because of 
the friction of the ice against its boundaries; but then 
one would think that midway between the boundaries, 
where the friction of the sides is least, the motion 
ought to be greatest. This is clearly not the case; for 
though the 10th stake is nearer than the 9th to the 
eastern or Chapeau side of the valley, the 10th stake 
surpasses the 9th by 6 inches a day. 

167. Here we have something to think of; but before 
a natural philosopher can think with comfort he must 
be perfectly sure of his facts. The foregoing line ran 
across the glacier a little below the Montanvert. We 
will run another line across a little way above the hotel. 
On July 18 we set out this line, and to multiply our 
chances of discovery we place along it 31 stakes. On 
the subsequent day five of these were found unfit for 
use; Lut here are the distances passed over by the 
remaining six-and-twenty in 24 hours. 


Sreconp Line: BB’ upon THE SKETCH. 


West 
Stake 2 3 4 3 6 rf 8 Seiad © | mae 1p ad fig Bs 


Inches Mite ie lee tena, te | ES 20. 20, 21; 2 
Stake ta 16) Sh ole 19> 20 21 22 25) 2£.) 26-26 
laches fo. 20-20-21) ae 21 20-22 22 23 20°. 26 


70 THE FORMS OCF WATER IN 


168. Look at these numbers. The first broad fact 
they reveal is the advance in the rate cf motion from 
first to last. There are however small irregularities ; 
from 23 inches at the 17th stake we fall to 21 inches at 
the 18th; from 23 inches at the 19th we fall to 21 inches 
at the 20th; from 25 :nches at the 21st we fall to 22 
inches at the 22nd and 23rd; but notwithstanding these 
small ups and downs, the general advance of the rate — 
of motion is manifest. Now there may have been some 
slight displacement of the stakes by melting, sufficient 
to account for these small deviations from uniformity 
in the increase of the motion. But another solution is 
also possible. We shall afterwards learn that the gla- 
cier is retarded not only by its sides but by its bed; 
that the upper portions of the ice slide over the lower 
ones. Now if the bed of the Mer de Glace should have 
eminences here and there rising sufficiently near to the 
surface to retard the motion of the surface, they might 
produce the small irregularities noticed above. 

169. We note particularly, while upon the ice, that the 
26th stake, like the 10th stake in our last line, stands 
much nearer to the eastern than to the western side 
of the glacier; the measurements, therefore, offer a fur- 
ther proof that the centre of this portion of the glacier 
is not the place of swiftest motion. 


§ 23. Unequal Motion of the two Sides of the 
3 Mer de Glace. 


170. But in neither the first line nor the second were 


CLOUDS AND RIVERS, ICE AND GLACIFRS. it 


we able to push our measurements quite across the 
glacier. Why? In attempting to do one thing we are 
often taught another, and thus in science, if we are only 
steadfast in our work, our very defeats are converted 
into means of instruction. We at first planted our 
theodolite on the lateral moraine of the Mer de Glace, 
expecting to be able to command the glacier from side 
to side. But we are now undeceived; the centre of 
the glacier proves to be higher than its sides, and from 
our last two positions the view of the ice near the oppo- 
site side of the glacier was intercepted by the eleva- 
tion at the centre. The mountain slopes, in fact, are 
warm in summer, and they melt the ice nearest to them, 
thus causing a fall from the centre to the sides. 

171. But yonder on the heights at the other side of 
the glacier we see a likely place for our theodolite. 
We cross the glacier and plant our instrument in a 
position from which we sweep the glacier from side to 
side. Our first line was below the Montanvert, our 
second line above it; this third line is exactly opposite 
the Montanvert; in fact, the mark on which we have 
fixed the fibre-cross of the theodolite is a corner of one 
of the windows of the little inn. Along this line we 
fix twelve stakes on July 20. On the 21st one of them 
had fallen; but the velocities of the remaining eleven 
.2 24 hours were found to be as follows :— 


"2 THE FORMS OF WATER IN 


Tuirp Lins: CC’ upon THE SKETCH. 

East West 
Stake... 1 2 83 4 6 6. 7 8." O Stee 
Inches .20 23 29 30 384 28 25 25 25 18 9 


172. Both the first stake and the eleventh in this 
series stood near the sides of the glacier. On the 
eastern side the motion is 20 inches, while on the 
western side it is only 9. It rises on the eastern side 
from 20 to 34 inches at the 5th stake, which we, stand- 
ing upon the glacier, can see to be much nearer to the 
eastern than to the western side. The united evidence 
of these three lines places the fact beyond doubt, that 
opposite the Montanvert, and for some distance above it 
and below it, the whole eastern side of the glacier is moving 
more quickly than the western side. 


§ 24. Suggestion of a new Likeness of Glacier Motion 
to River Motion. Conjecture tested. 


173. Here we have cause for reflection, and facts are 
comparatively worthless if they do not provoke this 
exercise of the mind. It is because facts of nature are 
not isolated but connected, that science, to follow them, 
must also form a connected whole. The mind of the 
natural philosopher must, as it were, be a web of thought 
corresponding in all its fibres with the web of fact in 
nature. | 

174. Let us, then, ascend to a point which commands 
a vood view of this portion of the Mer de Glace. The 


CLOUDS AND RIVERS, ICE AND GLACIERS. 73 


1¢2-river we see is not straight but curved, and its cur- 
vature is from the Montanvert; that is to say, its con- 
vex side is east, and its concave side is west (look to 
the sketch)... You have already pondered the fact that 
a glacier, in some respects, moves like ariver. How would 
a river move through acurved channel? Thisis known. 
Were the ice of the Mer de Glace displaced by water, 
the point of swiftest motion at the Montanvert would 
not be the centre, but a point east of the centre. Can 
it be then that this ‘ water-rock,’ as ice is sometimes 
called, acts in this respect also like water ? 

175. This is a thought suggested on the spot; it may 
or it may not be true, but the means of testing it are at 
hand. Looking up the glacier, we see that at les Ponts 
it also bends, but that there its convex curvature is 
towards the western side of the valley (look again to 
the sketch). If our surmise be true, the point of 
swiftest motion opposite les Ponts ought to lie west of 
the axis of the glacier. 

176. Let us test this conjecture. On July 25 we fix 
in a line across this portion of the glacier seventeen 
stakes; every one of them has remained firm, and on 
the 26th we find the motion for 24 hours to be as 
follows: - 


FourtH Line: DD vpon tue SKETCH. 
East West 
oes 46.06) Ge 7) 8s 9 710" 1512+ 19° 240018 
eer te tae ian 1G 19, 202) Bt 2S. 23). 21°: 92.-17 168 


74 THE FORMS OF WATER IN 


177. Inspected by the naked eye alone, the stakes 10 
and 11, where the glacier reaches its greatest motion, 
are seen to be considerably to the west of the axis of 
the glacier. Thus far we have a perfect verification of 
the guess which prompted us to make these measure- 
ments. You will here observe that the ‘ guesses’ of 
science are not the work of chance, but of thoughtful 
pondering over antecedent facts. The guess is the ‘ in- 
duction’ from the facts, to be ratified or exploded by the 
test of subsequent experiment. 

178. And though even now we. have exceedingly 
strong reason for holding that the point of maximum 
velocity obeys the law of liquid motion, the strength of 
our conclusion will be doubled if we can show that the 
point shifts back to the eastern side of the axis at 
another place of flexure. Fortunately such a place 
exists opposite Trélaporte. Here the convex curvature 
of the valley turns again to the east. Across this por- 
tion of the glacier a line was set out on July 28, and 
from measurements on the 38lst, the rate of motion per 
24 hours was determined. 


Firto Linge: EE’ upon THE SKETCH. 
West ; East 
Shake 2S es 1 =e 8 9 10 HM “ease 
Inches. 11.514 18 15 18 16 17 #%¥9 20 19 20 S336 ee 


179. Here, again, the mere estimate of distances by 
the eye would show us that the three stakes which moved 
fastest, viz. the 9th, 10th,and 11th, were all to the east of 


CLOUDS AND RIVERS, ICE AND GLACIERS. 75. 


the middle line of the glacier. The demonstration that 
the point of swiftest motion wanders to and fro across 
the axis, as the flexure of the valley changes, is, there- 
fore,—shall I say complete ? 

180. Not yet. For if surer means are open to us we 
must not rest content with estimates by the eye. We 
have with us a surveying chain: let us shake it out and 
measure these lines, noting the distance of every stake 
from the side of the glacier. This is no easy work 
among the crevasses, but I confide it confidently to Mr. 
Hirst and you. We can afterwards compare a number 
of stakes on the eastern side with the same number of 
stakes taken at the same distances from the western 
side. For example, a pair of stakes, one ten yards from 
the eastern side and the other ten yards from the 
western side; another pair, one fifty yards from the 
eastern side and the other fifty yards from the western 
side, and so on, can be compared together. For the 
sake of easy reference, let us call the points thus com- 
pared in pairs, equivalent points. 

181. There were five pairs of such points upon our 
fourth line, D D’, and here are their velocities :— 


Eastern points; motion in inches . . 13 15 16 18 20 
Western points =a fx een 17 22 23 23 


In every case here the stake at the western side moved 
more rapidly than the equivalent stake at the eastern 
sicle. | 


182. Applyirg the same analysis te our ifth line, 
({ 


76 THE FORMS OF WATER IN 


EE’, we have the following series of velocities of three — 
pairs of equivalent points :— 


Eastern points; motion in inches . . 15 18 19 
Western points = % a as 15 17 


183. Here the three points on the eastern side move 
more rapidly than the equivalent points on the western 
side. 

184. It is thus proved :— 

1. That opposite the Montanvert the eastern half of the 
Mer de Glace moves more rapidly than the western half. — 

2. That opposite les Ponts the western half of the 
glacier moves more rapidly than the eastern half. 

8. That opposite Trélaporte the eastern half of the 
glacier again moves more rapidly than the western half. 

4. That these changes wn the place of greatest motion 
are determined by the flecwres of the valley through which 
the Mer de Glace moves. 


§ 25. New Law of Glacier Motion. 


185. Let us express these facts in another way. Sup- 
posing the points of swiftest motion for a very great 
number of lines crossing the Mer de Glace to be deter- 
mined; the line joining all those points together is 
what mathematicians would call the locus of the point 
of swiftest motion. 

186. At Trélaporte this line would lie east of the 
centre; at the Ponts it would lie west of the centre; 
hence in passing from Trélaporte to the Ponts it would 


CLOUDS AND RIVERS, ICE AND GLACIERS. 77 


eross the centre. But at the Montanvert it would again 
lie east of the centre; hence between the Ponts and the 
Montanvert the centre must be crossed a second time. 
If there were further sinuosities upon the Mer de Glace © 
there would be further crossings of the axis of the glacier. 

187. The points on the axis which mark the transition 
from eastern to western bending, and the reverse, may 
be called points of contrary flexure. 

188. Now what is true of the Mer de Glace is true of 
all other glaciers moving through sinuous valleys; so 
that the facts established in the Mer de Glace may be 
expanded into the following general law of glacier mo- 
tion :— 

When a glacier moves through a sinuous valley, the locus 
of the point of maxumum motion does not coincide with 
the centre of the glacier, but, on the contrary, always 
lies on the convex side of the central line. The locus is 
therefore a curved line more deeply sinuous than the valley 
itself, and crosses the axis of the glacier at each point of 
contrary flexure. | 

189. The dotted line on the Outline Plan (page 68) 
represents the locus of the point of maximum motion, 
the firm line marking the centre of the glacier. 

190. Substituting the word river for glacier, this law 
is also true. The motion of the water is ruled by pre- 
cisely the same conditions as the motion of the ice. 

191, Let us now apply our law to the explanation 
of a difficulty. Turning to the careful measurements 


78 THE FORMS OF WALIER IN 


executed by M. Agassiz on the glacier of the Unteraar, 
we notice in the discussion of these measurements a 
section of the ‘Systéme glaciaire’ devoted to the 
‘ Migrations of the Centre.’ It is here shown that the 
middle of the Unteraar glacier is not always the point 
of swiftest motion. This fact has hitherto remained 
without explanation; but a glance at the Unteraar 
valley, or at the map of the valley, shows the enigma 
to be an illustration of the law which we have just 
established on the Mer de Glace. 


§ 26. Motion of Axis of Mer de Glace. 


192. We have now measured the rate of motion of 
five different lines across the trunk of the Mer de Glace. 
Do they all move alike? No. Like a river, a glacier 
at different places moves at differentrates. Comparing 
together the points of maximum motion of all five lines, 
we have this result :— 


MOTION OF MER DE GLACE. 


At Trelaporte . : : - 20 inches a day. 
At les Ponts 5 : ‘ he ee oe 
Above the Montanvert ‘ os DO. Le 
At the Montanvert . ; i ee eee a 
Below the Montanvert ‘ ; 2; SO ee a: 


193. There is thus an increase of rapidity as we de- 
scend the glacier from Trélaporte to the Montanvert ;: 


* This is probably under the mark. I think it likely that the swiftest 
motion of this portion of the Mer de Glace in 1857 amounted to a yard in 
twenty-four hours. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 79 


the maximum motion at the Montanvert being fourteen 
inches a day greater than at Trélaporte. - 


§ 27. Motion of Tributary Glaciers. 

194. So much for the trunk glacier; let us now 
investigate the branches, permitting, as we have hitherto 
done, reflection on known facts to precede our attempts 
to discover unknown ones. 

195. As we stood upon our ‘cleft station,? whence 
we had so capital a view of the Mer de Glace, we were 
struck by the fact that some of the tributaries of the 
glacier were wider than the glacier itself. Supposing 
water to be substituted for the ice, how do you suppose 
it would behave? You would doubtless conclude that 
_ the motion down the broad and slightly-inclined valleys 
of the Géant and the Léchaud would be comparatively 
slow, but that the water would force itself with increased 
rapidity through the ‘narrows’ of Trélaporte. Let us 
test this notion as applied to the ice. 

196. Planting our theodolite in the shadow of Monit 
Taeul, and choosing a suitable point at the opposite side 
of the Glacier du Géant, we fix on July 29 a series of 
ten stakes across the glacier. The motion of this line 
n twenty-four hours was as follows :— 


MOTION OF GLACIER DU GEANT. 
Sixta Lixe: HH’ vron SKetcu. 
Po Se Set oie oe eet eee ee 2 oe | 
TT ee if ORS tS fees alee ee is ie ee | ee! ee 


BO THE FORMS OF WATER IN 


197. Our conjecture is fully verified. The maximum 
motion here is seven inches a day less than that of the 
Mer de Glace at Trélaporte (192). 

198. And now for the Léchaud branch. On August 
1 we fix ten stakes across this glacier above the point 
where it is joined by the Taléfre. Measured on August 
3, and reduced to twenty-four hours, the motion was 
found to be— 

MOTION OF GLACIER DE LECHAUD. 


SeEvENTH Line: K K’ upon SxketTcu. 


Stake«..°s 4.°2:. 8 4 S 16:.7/-8 oo 
Inches 2: 6.23. 10. 9-8-8 -62-9 ee 


199. Here our conjecture is still further verified, the 
rate of motion being even less than that of the Glacier 
du Géant. 


§ 28. Motion of Top and Bottom of Glacier. 


200. We have here the most ample and varied evi- 
dence that the sides of a glacier, like those of a river, 
are retarded by friction against its boundaries. But 
the likeness does not end here. The motion of a river 
is retarded by the friction against its bed. Two 
observers, viz. Prof. Forbes and M. Charles Martins, 
concur in showing the same to be the case with a 
glacier. The observations of both have been objected 
to; hence it is all the more incumbent on us to seck 
for decisive evidence. ? 

201. At the Tacul (near the point a upon the sketch 


ULOUDS AND RIVERS, ICE AND GLACIERS. 81 


pian, p. 83) a wall of ice about 150 feet high has already 
attracted our attention. Bending round to join the 
Léchaud the Glacier du Géant is here drawn away from 
the mountain side, and exposes a fine section. We try 
to measure it top, bottom, and middle, and are defeated 
twice over. We try it a third time and succeed. A 
stake is fixed at the summit of the ice-precipice, another 
at 4 feet from the bottom, and a third at 35 feet above 
the bottom. These lower stakes are fixed at some risk 
of boulders falling upon us from above; but by skill 
and caution we succeed in measuring the motions of all 
three. For 24 hours the motions are :— 


Top stake : : : . 6 inches. 
Middle stake . é : Mae ee 
Bottom stake . : - ae 


202. The retarding influence of the bed of the glacier 
is reduced to demonstration by these measurements. 
The bottom does not move with half the velocity of the 
surface. 


§ 29. Lateral Compression of a Glacier. 

203. Furnished with the knowledge which these 
labours and measurements have given us, let us once 
more climb to our station beside the Cleft under the 
Aiguille de Charmoz. At our first visit we saw the 
medial moraines of the glacier, but we knew nothing 
about their cause. We now know that they mark upon 
the trunk its tributary glaciers. Cast your eye, then, 


82 THE FORMS OF WATER 1N 


first upon the Glacier du Géant; realise its width in 


its own valley, and see how much it is narrowed at 
Trélaporte. The broad ice-stream of the Léchand is 
still more surprising, being squeezed upon the Mer de 
Glace to a narrow white band between its bounding 
moraines. The Taléfre undergoes similar compression. 
Let us now descend, shake out our chain, measure, 
and express in numbers the width of the tributaries, 
and the actual amount of compression suffered at Tré- 
laporte. 7 


204. We find the width of the Glacier du Géant to 


be 5,155 links, or 1,134 yards. is, 

205. The width of the Glacier de Léchaud we find 
to be 3,725 links, or 825 yards. 

206. The width of the Taléfre we find to be 2,900 
links, or 638 yards. 7 

207. The sum of the widths of the three branch 
glaciers is therefore 2,597 yards. 

208. At Trélaporte these three branches are forced 
through a gorge 893 yards wide, or one-third of their 
previous width, at the rate of twenty inches a day. 

209. If we limit our view to the Glacier de Léchaud, 
the facts are still more astonishing. Previous to its 
junction with the Taléfre, this glacier has a width of 
825 yards; in passing through the jaws of the granite 
vice at Trélaporte, its width is reduced to eighty-eight 
yards, or in round numbers to one-tenth of its previous 
width. (Look to the sketch on the next page.) 


=o 


q 
j 
4 
3 


CLOUDS AND RIVERS, ICE AND GLACIERS. 


SS 
UW 
ies 


\ 
\ 


ee 
LLL 


SKETCH-PLAN SHOWING THE MORAINES a, b, c, d, e, OF THE MER DE GLACE, 


MNe “we Wry, 


83 


34 THE FORMS OF WATER IN 


210. Are we to understand by this that the ice of 
the Léchaud is squeezed to one-tenth of its former 
volume? By no means. It is mainly a change of form, 
not of volume, that occurs at Trélaporte. Previous to 
its compression, the glacier resembles a plate of ice 
lying flat upon its bed. After its compression, it 
resembles a plate fixed upon its edge. The squeezing, 
doubtless, has deepened the ice. 3 


§ 30. Longitudinal Compression of a Glacier. 


211. The ice is forced through the gorge at Tréla- 
porte by a pressure from behind; in fact the Glacier 
du Géant, immediately above Trélaporte, represents a 
piston or a plug which drives the ice through the 
gorge. What effect must this pressure have upon the 
plug itself? Reasoning alone renders it probable that 
the pressure will shorten the plug ; that the lower part 
of the Glacier du Géant will to some extent yield to the 
pressure from behind. 

212. Let us test this notion. About three-quarters 
of a mile above the Tacul, and on the mountain slope to 
the left as we ascend, we observe a patch of verdure. 
Thither we chmb; there we plant our theodolite, and 
set out across the Glacier du Géant, a line, which we 
will call line No. 1 (F EF” upon sketch, p. 68). 

218. About a quarter of a mile ower down we find a 
practicable couloir on the mountain side; we ascend 


CLOUDS AND RIVERS, ICE AND GLACIERS. 85 


it, reach a suitable platform, plant our instrument, and 
set out a second line, No. 2 (G G’ upon sketch). We 
must hasten our work here, for along this couloir stones 
_ are discharged from a small glacier which rests upon 
the slope of Mont Tacul. 

214. Still lower down by another quarter of a mile, 
which brings us near the Tacul, we set out a third line, . 
No. 3 (H H’ upon sketch), across the glacier. 

215. The daily motion of the centres of these three 
lines is as follows :— 


Inches Distances asunder 
No.1 . Z ae . 6465 yards. 
Ne. 2 -. Seats ; 
Wend. aay hea es 


216. The first line here moves five inches a day more 
than the second ; and the second nearly three inches a 
day more than the third. The reasoning is therefore 
confirmed. The ice-plug, which is in round numbers 
one thousand yards long, is shortened by the pressure 
exerted on its front at the rate of about eight inches a 
day. 

217. A river descending the Valley du Géant would 
behave in substantially the same fashion. It would have 
its motion on approaching Trélaporte diminished, and 
it would pour through the defile with a velocity greater 
than that of the water behind. 


86 THE FORMS OF WATER IN 


§ 31. Sliding and Flowing. Hard Ice and Soft Ice. 


218. We have thus far confined ourselves to the 
measurement and discussion of glacier motion; but m 
our excursions we have noticed many things besides. 
Here and there, where the ice has retreated from the 
mountain side, we have seen the rocks fluted, scored, 
and polished; thus proving that the ice had slidden over 
them and ground them down. At the source of the 
Arveiron we noticed the water rushing from beneath 
the glacier charged with fine matter. All glacier 
rivers are similarly charged. The Rhone carries its 
load of matter into the Lake of Geneva; the rush of 
the river is here arrested, the matter subsides, and the 
Rhone quits the lake clear and blue. The Lake of 
Geneva, and many other Swiss lakes, are in part filled 
up with this matter, and will, in all probability, finally 
be obliterated by it. 

219. One portion of the motion of a glacier is due to 
this bodily sliding of the mass over its bed. 

220. We have seen in our journeys over the glacier 
streams formed by the melting of the ice, and escaping 
through cracks and crevasses to the bed of the glacier. 
The fine matter ground down is thus. washed away ; 
the bed is kept lubricated, and the sliding of the ice 
rendered more easy than it would otherwise be. 

221. As a skater also you know how much ice is 
weakened bya thaw. Before it actually melts it becomes 


. : FS Neal ry ¢ L ; haat nS . rth ee pee ee | 
ee ae ee ee ee ee eee ee aw s J 


CLOUDS AND RIVERS, ICE AND GLACIERS. 87 


rotten and unsafe. Test such ice with your penknife: 
you can dig the blade readily into it, or cut the ice with 
ease. Try good sound ice in the same way: you find 
it much more resistant. The one, indeed, resembles - 
soft chalk; the other hard stone. 

222. Now the Mer de Glace in summer is in this 
thawing condition. Its ice is rendered soft and yielding 
by the sun; its motion is thereby facilitated. We 
have seen that not only does the glacier slide over its 
bed, but that the upper layers slide over the under 
ones, and that the centre slides past the sides. The 
softer and more yielding the ice is, the more free will 
be this motion, and the more readily also will it be 
forced through a defile like Trélaporte. 

223. But in winter the thaw ceases; the quantity of 
water reaching the bed of the glacier is diminished or 
entirely cut off. The ice also, to a certain depth at 
least, is frozen hard. These considerations would justify 
the opinion that in winter the glacier, if it moves at 
all, must move more slowly than in summer. At all 
events, the summer measurements give no clue to the 
winter motion. 3 

224. This point merits examination. Iwill not, how- 
ever, ask you to visit the Alps in mid-winter; but, if 
you allow me, I will be your deputy to the mountains, 
and report to you faithfully the aspect of the region 
and the behaviour of the ite. 


88 THE FORMS OF WATER IN 


§ 32. Winter on the Mer di Glace. 


225. The winter chosen 1s an inclement one. There 
is snow in London, snow in Paris, snow in Geneva; 
snow near Chamouni so deep that the road fences are 
entirely effaced. On Christmas night—nearly at mid- 
night—1859, your deputy reaches Chamouni. 

226. The snow fell heavily on December 26; but on 
the 27th, during a lull in the storm, we turn out. 
There are with me four good gcuides and a porter. They 
tie planks to their feet to prevent them from sinking 
in the snow; I neglect this precaution and sink often 
to the waist. Four or five times during our ascent 
the slope cracks with an explosive sound, and the snow 
threatens to come down in avalanches.* 

The freshly-fallen snow was in that particular con- 
dition which causes its granules to adhere, and hence 
every flake falling on the trees had been retained there. 
The laden pines presented beautiful and often fantastic 
forms. | 

227. After five hours and a half of arduous work the 
Montanvert was attained. We unlocked the forsaken 
auberge, round which the snow was reared in buttresses. 
[have already spoken of the complex play of crystallising 


* Four years later, viz. in the spring of 1863, a mighty climber and 
noble guide and eompanion of mine, named Johann Joseph Bennen, was 
lost, through the cracking and subsequent slipping of snow on such sg 
slope. 


CLOUDS AND RIVERS, ICE AND GLACIERS, 89 


forces. The frost-figures on the window-panes of the 
auberge were wonderful: mimic shrubs and ferns 
wrought by the building power while hampered by 
the adhesion between the glass and the film in which it 
worked. The appearance of the glacier was very impres- 


ny 
Wy Y fy 


YY 


Yy 


My 


/ 


Ns 


SNOW-LADEN PINE-TREE, 


sive; all sounds were stilled. The cascades which in 
summer fill the air with their music were silent, hanging 
from the ledges of the rocks in fluted columns of ice. 
The surface of the glacier was obviously higher than it 
had been in summer; suggesting the thought that while 
the winter cold maintained the lower end of the glacier 


30 THE FORMS OF WATER IN 


jammed between its boundaries, the upper portions still 
moved downwards and thickened the ice. The peak of 
the Aiguille du Dru shook out a cloud-banner, the ori- 
gin and nature of which have been already explained (84). 
(See Frontisprece.) | 

228. On the morning of the 28th this banner was 
strikingly large and grand, and reddened by the light — 
of the rising sun, it glowed like a flame. Rwoses of 
cloud also clustered round the crests of the Grande 
Jorasse and hung upon the pinnacles of Charmoz. 
Four men, well roped together, descended to the glacier. 
I had trained one of them in 1857, and he was now to 
fix the stakes. The storm had so distributed the snow 
as to leave alternate lengths of the glacier bare and 
thickly covered. Where much snow lay great caution 
was required, for hidden crevasses were underneath. 
The men sounded with their staffs at every step. Once 
while looking at the party through my telescope the 
leader suddenly disappeared ; the roof of a crevasse had 
given way beneath him; but the other three men 
promptly gathered round and lifted him out of the 
fissure. The true line was soon picked up bv the theo- 
dolite ; one by one the stakes were fixed until a series 
of eleven of them stood across the glacier. 

229. To get higher up the valley was impracticable ; 
the snow was too deep, and the aspect of the weather 
too threatening; so the theodolite was planted amid the 
pines a little way below the Montanvert, whence through 


CLOUDS AND RIVERS, ICE AND GLACIERS. 9] 


a vista I could see across the glacier. The men were 
wrapped at intervals by whirling snow-wreaths which 
quite hid them, and we had to take advantage of the 
lulls in the wind. Fitfully it came up the valley, dark- 
ening the air, catching the snow upon the glacier, and 
tossing it throughout its entire length into high and 
violently agitated clouds, separated from each other by 
cloudless spaces corresponding to the naked portions of 
the ice. In the midst of this turmoil the men con- 
tinued to work. Bravely and steadfastly stake after 
stake was set, until at leneth a series of ten of them 
was fixed across the glacier. 

230. Many of the stakes were fixed in the snow. 
They were four feet in length, and were driven in to a 
depth of about three feet. But that night, while list- 
ening to the wild onset of the storm, I thought it pos- 
sible that the stakes and the snow which held them 
might be carried bodily away before the morning. 
The wind, however, lulled. We rose with the dawn, but 
the air was thick with descending snow. It was all 
composed of those exquisite six-petaled flowers, or six- 
rayed stars, which have been already figured and de- 
scribed ($ 9). The weather brightening, the theodo- 
lite was planted at the end of the first line. The men 
descended, and, trained by their previous experience, 
rapidly executed the measurements. The first line was 
completed before 11 a.m. Again the snow began to fall, 


filling all the air. Spangles innumerable were showered 
8 


92 THE FORMS OF WATER IN 


npon the heights. Contrary to expectation, the men 
could be seen and directed through the shower. 

_ 231. To reach the position occupied by the theodolite 
at the end of our second line, I had to wade breast-deep 
through snow which seemed as dry and soft as flour. 
The toil of the men upon the glacier in breaking through 
the snow was predigious. But they did not flinch, and 
after a time the leader stood behind the farthest stake, 
and cried, Nous avons fini. I was surprised to hear. 
him so distinctly, for falling snow nad been thought 
very deadening to sound. The work was finished, and 
I struck my theodolite with a feeling of a general who 
had won a small battle. 

232. We put the house in order, packed up, and shot 
by glissade down the steep slopes of La Fila to the 
vault of the Arveiron. We found the river feeble, but 
not dried up. Many weeks must have elapsed since any 
water had been sent down from the surface of the 
glacier. But at the setting in of winter the fissures 
were in a great measure charged with water; and the 
Arveiron of to-day was probably due to the gradual 
drainage of the glacier. There was now no danger of 
antering the vault, for the ice seemed as firm as marble. 
-n the cavern we were bathed by blue lght. The 
strange beauty of the place suggested magic, and put. 
me in mind of stories about fairy caves which I had read 
when a boy. At the source of the Arveiron our winter 
visit to the Mer de Glace ends; next morning yous 
deputy was on his way to London. 


CLOUDS AND RIVERS, {CE AND GLACIERS. 93 


$ 33. Winter Motion of the Mer de Glace. 


233. Here are the measurements executed in the 
winter of 1859 :— | 
Line No. I. 
Meme. Sb 2 = 4 + 6 7 8 So 10:°. 34 
eer or 1h 14 ta 14 «6214-16 16 12.12 -7 


Line No. IL 
See eee ee ee Be HRs GS - -TO 
ene pe «14° 8G 1G 1G 61S. 17 FS 74 


234. Thus the winter motion of the Mer de Glace 
near the Montanvert is, in round numbers, half the 
summer motion. 

235. As in summer, the eastern side of the glacier alt 
this place moved quicker than the western. 


§ 34. Motion of the Grindelwald and Aletsch Glaciers. 

236. As regards the question of motion, to no other 
glacier have we devoted ourselves with such thorough- 
ness as to the Mer de Glace; we are, however, able 
to add a few measurements of other celebrated glaciers. 
Near the village of Grindelwald in the Bernese Ober- 
land, there are two great ice-streams called respec- 
tively the Upper and the Lower Grindelwald glaciers, 
the second of which is frequently visited by travellers 
in the Alps. Across it on August 6, 1860, a series of 
twelve stakes was fixed by Mr. Vaughan Hawkins and 
myself. Measured on the 8th and reduced to its daily 
rate, the motion of these stakes was as follows :— 


94, THE FORMS OF WATER IN 


MOTION OF LOWER GRINDELWALD GLACIER. 


East West 
Stake 301 2.5383. 42°53 6 7 —§ 9.3 
Inches “:..18 19 °20° 2121 21 22 20 19> aR eee 


237. The theodolite was here planted a little below 
the footway leading to the higher glacier region, and at 
about a mile above the end of the glacier. The mea- 
surement was rendered difficult by crevasses. 

238. The largest glacier in Switzerland is the Great 
Aletsch, to which further reference shall subsequently 
be made. Across it on August 14, 1860, a series of 
thirty-four stakes was planted by Mr. Hawkins and me. 
Measured on the 16th and reduced to their daily rate, 
the velocities were found to be as follows :— 


MOTION OF GREAT ALETSCH GLACIER. 
East 

Stake. 4 1.2 8-4 62° 6 -J- 33 2 9) 203 eee 
Inches: << 2-3 °4 6 °8 - 11 13° 14 16> ail 
Stake. 2298 14°15 16 17 18 919 20 52032 
Inches .. 419 18 18. 17 19° 19: 19 19-3075 
Stake .- > 24°25 26 27 28 29 -30 SO) °S2 eee 
Inches. 16°17 “37 17-17 21747 4 eee 

West 


* 


239. The maximum motion here is nineteen inches a 
day. Frobably the eastern side of the glacier is shallow, 
the retardation of the bed making the motion of the 
eastern stakes inconsiderable. The width of the glacier 
here is 9,030 links, or about a mile and a furlong. © 
The theodolite was planted high among the rocks on 
the western flank of the mountain, about half a mile 
above the Mareelin See. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 95 


§ 35. Motion of Morteratsch Glacier. 


240. Far to the east of the Oberland and in that 
interesting part of Switzerland known as the Ober En. 
gadin, stands a noble group of mountains, less in height 
than those of the Oberland, but still of commanding 
elevation. The group derives its name from its most 
dominant peak, the Piz Bernina. To reach the place 
we travel by railway from Basel to Zurich, and from 
Ziirich to Chur (French Coire), whence we pass by dili- 
gence over either the Albula pass or the Julier pass to 
the village of Pontresina. Here we are in the imme- 
diate neighbourhood of the Bernina mountains. 

241. From Pontresina we may walk or drive along a 
good coach road over the Bernina pass into Italy. At 
about an hour above the village you would look from 
the road into the heart of the mountains, the line of 
vision passing through a valley, in which is couched a 
glucier of considerable size. Along its back you would 
trace a medial moraine, and you could hardly fail to 
notice how the moraine, from a mere narrow streak 
at first, widens gradually as it descends, until finally it 
quite covers the lower end of the glacier. Nor is this 
an effect. of perspective ; for were you to stand upon the 
mountain slopes which nourish the glacier, you would 
see thence also the widening of the streak of rubbish, 
though the perspective here would tend to narrow 
’ the moraine as it retreats downwards. 


96 THE FORMS OF WATER IN 


242. The ice-stream here referred to is the Morter- 
atsch glacier, the end of which is a short hour’s walk 
from the village of Pontresina. We have now to de- 
termine its rate of motion and to account for the widen- 
ine of its medial moraine. 

243. In the summer of 1864 Mr. Hirst and myself 
set out three lines of stakes across the glacier. The 
first line crossed the ice high up; the second a good 
distance lower down, and the third lower still. Even 
the third line, however, was at a considerable distance 
above the actual snout of the glacier. ‘The daily 
motion of these three lines was as follows :— 


First Line. 


Stake 6-262 68 4 Be 6 8 ae 
Inches .-. 8 12° Y@ 13:..14 -16 12) 127-308 


Seconp LINE. 


Stake . 2.1 2 8 4 S&S 6° 7 8 “33333 
Inches. 22 4 6 8-10 -11 11 1) Sie 


Turrp LIne, 


Stake «¢ . 2°92 583° 4:95 -6 7.3 S330 
Inches. .°1 22. 4° 8: :.6 ~6 -7." 7 ~Sse2aoeee 


244, Compare these lines together. You notice the 
velocity of the first is greater than that of the second, 
and the velocity of the second greater than that of the 


third. 
945. The lines were permitted to move downwards fon - 


CLOUDS AND RIVERS, ICE AND GLACIERS. 07 


{00 hours, at the end of which time the spaces passed 
over by the points of swiftest motion of the three lines 
were as follows :— | 


Maximum Moriun 1x 100 Hours. 


First line. . - . 56 inches. 
Second line . - ‘ ne Ores > ya 
Third ine , ‘ : SOS oe | ieee 


246. Here then is a demonstration that the upper 
portions of the Morteratsch glacier are advancing on 
the lower ones. Jn 1871 the motion of a point on the 
middle of the glacier near its snout was found to be less 
than two wmches a day ! 

247. What, then, is the consequence of this swifter 
march of the upper glacier? Obviously to squeeze this 
medial moraine longitudinally, and to cause it to spread 
out laterally. We have here distinctly revealed the cause 
of the widening of the medial moraine. 

248. It has been a question much discussed, whether a 
glacier is competent to scoop out or deepen the valley 
through which it moves, and this very Morteratsch 


glacier has been cited to prove that such is not the case. 


Observers went to the snout of the glacier, and finding 
it sensibly quiescent, they concluded that no scooping 
occurred. But those who contended for the power of 
olaciers to excavate valleys never stated, or meant to 
state, that it was the snout of the glacier which did 
the work. In the Morteratsch glacier the work of 
*xcavation, which certainly goes on to a greater ar 


98 THE FORMS OF WATER IN 


less extent, must be far more effectual high up the 
valley than at the end of the glacier. 


§ 36. Birth of a Crevasse: Reflections. 


249. Preserving the notion that we are working to- 
gether, we will now enter upon a new field of enquiry. 
We have wrapped up our chain, and are turning home- 
wards after a hard day’s work upon the Glacier du 
Géant, when under our feet, as if coming from the 
body cf the glacier, an explosion is heard. Somewhat 
startled, we look enquiringly over the ice. The sound 
is repeated, several shots being fired in quick succession. 
They seem sometimes to our right, sometimes to our 
left, giving the impression that the glacier is breaking 
all round us. Still nothing is to be seen. | 

250. We closely scan the ice, and after an hour’s 
strict search we discover the cause of the reports. They 
announce the birth of a crevasse. Through a pool upon 
the glacier we notice air bubbles ascending, and find the 
bottom of the pool crossed by a narrow crack, from 
which the bubbles issue. Right and left from this pool 
we trace the young fissure through long distances. It 
is sometimes almost too feeble to be seen, and at no 
place is it wide enough to admit a knife-blade. 

251. It is difficult to believe that the formidable 
fissures among which you and I have so often trodden 
with awe, could commence in this small way. Such, 
however, is the case. The creat and gaping chasms oii 


CLOUDS AND RIVERS, ICE AND GLACIERS. 99 


and above the ice-falls of the Géant and the Taleéfre 
begin as narrow cracks, which open gradually to 
crevasses. We are thus taught in an instructive and 
impressive way that appearances suggestive of very | 
violent action may really be produced by processes so 
slow as to require refined observations to detect them. 
In the production of natural phenomena two things 
always come into play, the intensity of the acting force, 
and the time during which its acts. Make the in- 
tensity great, and the time small, and you have sudden 
- corvuision; but precisely the same apparent effect may 
be produced by making the intensity small, and the 
time great. This truth is strikingly illustrated by the 
Alpine ice-falls and crevasses; and many geological 
phenomena, which at first sight suggest violent con- 
vulsion, may be really produced in the selfsame 
almost imperceptible way. 


§ 37. Icicles. 


252. The crevasses are grandest on the higher névés, 
where they sometimes appear as long yawning fissures, 
and sometimes as chasms of irregular outline. 
delicate blue light shimmers from them, but this is 
gradually lost in the darkness of their profounder 
portions. Over the edges of the chasms, and mostly 
over the southern edges, hangs a coping of snow, and 
from this depend like stalactites rows of transparent 
icicles, 10, 20, 80 feet long. These pendent spears 


100 THE FORMS OF WATER IN 


constitute one of the most beautiful features of the 
higher crevasses. | 

253. How are they produced? Evidently by the 
thawing of the snow. But why, when once thawed, 
should the water freeze again to solid spears? Yon 
have seen icicles pendent from a house-eave, which 
have been manifestly produced by the thawing of the 
snow upon the roof. If we understand these, we shall 
also understand the vaster stalactites of the Alpine 
crevasses. 

254. Gathering up such knowledge as we possess, 
and reflecting upon it patiently, let us found on it, if 
we can, a theory of icicles. 

255. First, then, you are to know that the asr of our 
atmosphere is hardly heated at all by the rays of the 
sun, whether visible or invisible. The air is highly 
transparent to all kinds of rays, and it is only the 
scanty fraction to which it is not transparent that ex- 
pend their force in warming it. 

256. Not so, however, with the snow on which the 
sunbeams fall. It absorbs the solar heat, and on a 
sunny day you may see the summits of the high Alps 
glistening with the water of liquefaction. The air above 
and around the mountains may at the same time be 
many degrees below the freezing point in temperature. 

257. You have only to pass from sunshine into shade 
to prove this. A single step suffices to carry you from 
a place where the thermometer stands high to one 


CLOUDS AND RIVERS, ICE AND GLACIERS. 101 


where it stands low; the change being due, not to any 
difference in the temperature of the air, but simply to 
the withdrawal of the thermometer from the direct 
action of the solar rays. Nay, without shifting the 
thermometer at all, by interposing a suitable screen, 
which cuts off the sun’s rays, the coldness of the air 
may be demonstrated. 

258. Look now to the snow upon your house roof. 
The sun plays upon it, and melts it; the water trickles 
to the eave and then drops down. If the eave face the 
sun the water remains water; but if the eave do not 
face the sun, the drop, before its quits its parent snow, 
is already in shadow. Now the shaded space, as we 
have learnt, may be below the freezing temperature. If 
so, the drop, instead of falling, congeals, and the 
rudiment of an icicle is formed. Other drops and 
driblets succeed, which trickle over the rudiment, con- 
geal upon it in part and thicken it at the root. Buta 
portion of the water reaches the free end of the icicle, 
hangs from it, and is there congealed before it escapes. 
The icicle is thus lengthened. In the Alps, where the 
liquefaction is copious and the cold of the shaded 
crevasse intense, the icicles, though produced in the 
same way, naturally grow to a greater size. The drain- 
ave of the snow after the sun’s power is withdrawn 
also produces icicles. 

259. It is interesting and important that you should 
be able to explain the formation of an icicle; but it ig 


102 THE FORMS OF WATER IN 


far more important that you should realise the way in 
which the various threads of what we call Nature are 
woven together. You cannot fully understand an icicle 
without first knowing that solar beams powerful enough 
to fuse the snows and blister the human skin, nay, it 
might be added, powerful enough, when concentrated, 
to burn up the human body itself, may pass through 
the air, and still leave it at an icy temperature. 


§ 38. The Bergschrund. 


260. Having cleared away this difficulty, let us turn 
once more to the crevasses, taking them in the order 
of their formation. First then above the névé we have 
the final Alpine peaks and crests, against which the 
snow is often reared as a steep buttress. We have 
already learned that both névés and glaciers are moving 
slowly downwards; but it usually happens that the | 
attachment of the highest portion of the buttress to the 
rocks is great enough to enable it to hold on while 
the lower portion breaks away. A very characteristic 
crevasse is thus formed, called in the German-speaking 
portion of the Alps a Bergschrund. It often surrounds 
a peak like a fosse, as if to defend it against the as- 
saults of climbers. 

261. Look more closely into its formation. Imagine — 
the snow as yet unbreken. Its higher portions cling 
to the rocks,.and move downwards with extreme slow- 
ness. But its lower portions, whether from then 


CLOUDS AND RIVERS, ICE AND GLACIERS. 108 


greater depth and weighi, or their less perfect attach- 
ment, are compelled to move more quickly. A pull is 
therefore exertel, tending to separate the lower from > 
the upper snow. Fora time this pullis resisted by the 
cohesion of the névé; but this at length gives way, 
and a crack is formed exactly across the line in which 
the pull is exerted. In other words, a crevasses formed 
at right angles to the line of tension. 


§ 39. Transverse Crevasses. 


262. Both on the névé and on the glacier the origin 
of the crevasses is the same. Through some cause or 
other the ice is thrown into a state of strain, and as it 
cannot stretch it breaks across the line of tension. Take, 
for example, the ice-fall of the Géant, or of the Taléfre, 
above which you know the crevasses yawn terribly. 
Imagine the névé and the glacier entirely peeled away, 
so as to expose the surface over which they move. 
From the Col du Géant we should see this surface 
falling gently to the place now occupied by the brow of 
the cascade. Here the surface would fall steeply down 
to the bed of the present Glacier du Géant, where the 
slope would become gentle once more. 

263. Think of the névé moving over such a surface. 
It descends from the Col till it reaches the brow just 
referred to. It crosses the brow, and must bend down 
to keep upon its bed. Realise clearly what must occur. 
The surface of the névé is evidently thrown into a 


104 THE FORMS OF WATER IN 


state of strain; it breaks and forms a crevasse. Hach 
fresh portion of the névé as it passes the brow is 
similarly broken, aud thus a succession of crevasses is 
sent down the fall. Between every two chasms is a 
great transverse ridge. ‘Through local strains upon the 
fall those ridges are also frequently broken across, 
towers of ice—séracs—being the result. Down the fall 
both ridges and séracs are borne, the dislocation being 
augmented during the descent. 

264. What must occur at the foot of the fall? Here 
the slope suddenly lessens in steepness. It is plain that 
the crevasses must not only cease to open here, but that 
they must in whole or in part close up. At the summit 
of the fall, the bending was such as to make the surface 
convex ; at the bottom of the fall the bending renders 
the surface concave. In the one case we have strain, in 
the other pressure. In the one case, therefore, we have 
the opening, and in the other the closing of crevasses. 
This reasoning corresponds exactly with the facts of 
observation. 

265. Lay bare your arm and stretch it straight. 
Make two ink dots half an inch or an inch apart, 
exactly opposite the elbow. Bend your arm, the dots 
approach each other, and are finally brought together. 
Let the two dots represent the two sides of a crevasse 
at the bottoin of an ice-fall; the bending of the arm 
resembles the bending of the ice, and the closing up of 
the dots resembles the closing >f the fissures. 


a” a 
a 
4 
- 
| = 


CLOUDS AND RIVERS, ICE AND GLAUIERS. 105 


266. The same remarks apply to various portions of 
the Mer de Glace. At certain places the inclination 
changes from a gentler to a steeper slope, and on cross- 
ing the brow between both the glacier breaks its back. 
Transverse crevasses are thus formed. There is sucha 
change of inclination opposite to the Angle, and a still 
greater but similar change at the head of the Glacier 
des Bois. The consequence is that the Mer de Glace at 
the former point is impassable, and at the latter the 
rending and dislocation are such as we have seen and 
described. Below the Angle, and at the bottom of the 
Glacier des Bois, the steepness relaxes, the crevasses 
heal up, and the glacier becomes once more continuous 
and compact. 


§ 40. Marginal Crevasses. 


267. Supposing, then, that we had no changes of 
inclination, should we have no crevasses? We should 
certainly have less of them, but they would not wholly 
disappear. For other circumstances exist to throw the 
ice into a state of strain, and to determine its fracture. 
The principal of these is the more rapid movement of 
the centre of the glacier. 

268. Helped by the labours of an eminent man, now 
dead, the late Mr. Wm. Hopkins, of Cambridge, let us 
master the explanation of this point together. But the 


pleasure of mastering it would be enhanced if we could 


see beforehand the perplexing and delusive appearances 


106 THE FORMS OF WATER IN 


accounted for by the explanation. Could my wishes be 
followed out, I would at this point of our researches carry 
you off with me to Basel, thence to Thun, thence te 
Interlaken, thence to Grindelwald, where you would 


find yourself in the actual presence of the Wetterhorn 


and the Higer, with all the greatest peaks of the Bernese 
Oberland, the Finsteraarhorn, the Schreckhorn, the 
Monch, the J unefrau, at hand. At Grindelwald, as we 
have already learnt, there are two well-known glaciers 
—the Ober Grindelwald and the Unter Grindelwald 
v'laciers—on the latter of which our observations should 
commence. oo 

269. Dropping down from the village to the bottom 
of the valley, we should breast the opposite mountain, 
and with the great limestone precipices of the Wetter- 
horn to our left, we should get upon a path which com- 
mands a view of the glacier. Here we snould see 
beautiful examples of the opening of crevasses at the 
summit of a brow, and their closing at the bottom. 
But the chief point of interest would be the crevasses 
formed at the side of this glacier—the marginal crevasses, 
as they may be called. 

270. We should find the side copiously fissured, even 
at those places where the centre is compact; and we 
should particularly notice that the fissures would 


neither run in the direction of the glacier, nor straight 


across it, but that they would be oblique to it, enclosing 
an angle of about 45 degrees with the sides. Starting 


ee 


CLOUDS AND RIVERS, ICE AND GLACIERS. 107 


from the side of the glacier the crevasses would be seen 
to point upwards ; that is to say, the ends of the fissures 
abutting against the bounding mountain would appear 
to be dragged down. Were you less instructed than 
you now are, I might lay a wager that the aspect of 
these fissures would cause you to conclude that the 
centre of the glacier is left behind by the quicker moticn 
cf the sides. 

271. This indeed was the conclusion drawn by M. 
Agassiz from this very appearance, before he had 
measured the motion cf the sides and centre of the 


" glacier of the Unteraar. Intimately versed with the 


treatment of mechanical problems, Mr. Hopkins imme- 
diately deduced the obliquity of the lateral crevasses 
from the quicker flow of the centre. Standing beside 
the glacier with pencil and note-book in hand, I 
would at once make the matter clear to you thus. 

272. Let ac, in the annexed figure, be one side of 
the glacier, and B D the other; and let the direction of 


A. § Ss C 


B T T D 
motion be that indicated by the arrow. Let stv be a 


transverse slice of the glacier, taken straight across it, 
9 


108 THE FORMS OF WATER IN 


say to-day. <A few days or weeks hence this slice will 
have been carried down, and because the centre moves 
more quickly than the sides it will not remain straight, 
but will bend into the form s’ 1. | 

273. Supposing vt 2 to be a small square of the 

original slice near the side of the glacier. In its new 
position the square will be distorted to the lozenge- 
shaped figure 1’ 7’. Fix your attention upon the diagonal 
tT 2 of the square; in the lower position this diagonal, 
if the ice could stretch, would be lengthened to 1 Y. 
But the ice does not stretch; it breaks, and we have 
a crevasse formed at right angles to Y 7. The mere ° 
inspection of the diagram will assure you that the 
crevasse will point obliquely upwards. 
_ 274, Along the whole side of the glacier the quicker 
movement of the centre produces a similar state of 
strain; and the consequence is that the sides are 
copiously cut by those oblique crevasses, even at places 
where the centre is free from them. 

275. It 1s curious to see at other places the transverse 
fissures of the centre uniting with those at the sides, 
so as to form great curved crevasses which stretch 
across the glacier from side to side. The convexity of 
the curve is turned wpwards, as mechanical principles 
declare it ought to be. (See sketch on opposite page.) 
Butif you were ignorant of those principles, you would 
never infer from the aspect of these curves the quicker 
motion of the centre. In landslips, and in the motion 


= 


CLOUDS AND RIVERS, ICE AND GLACIERS. 109 


of partially indurated mud, you may sometimes notice 
appearances similar to those exhibited by the ice. 


7 


TGA ew —S TTA pa ML 

pS Ti LA NSS GM y if Wi Wf, 

NN \ vil if \i NSS Hi Mi py y iz} Wl 
ft ) SS SSRN SS Bb, H 


SKETCH OF CURVED CREVASSES : THE GLACIER MOVES FROM LEFT TO RIGHT. 


§ 41. Longitudinal Crevasses. 


276. We have thus unravelled the origin of both 
transverse and marginal crevasses. But where a glacier 
issues from a steep and narrow defile upon a com- 
paratively level plain which allows it room to expand 
laterally, its motion is in part arrested, and the level 
portion has to bear the thrust of the steeper portions 
behind. Here the line of thrust is in the direction of 
the glacier, while the direction at right angles to this 


110 THE FORMS OF WATER IN 


is one of tension. Across this latter the ple breaks, 
and longitudinal crevasses are formed. 


277. Examples of this kind of crevasse are furnished 


by the lower part of the Glacier of the Rhone, when 
looked down upon from the Grimsel Pass, or from any 
commanding point on the flanking mountains. 


§ 42. Crevasses in relation to Curvature of Glacier. 


278. One point in addition remains to be discussed, 
and your present knowledge will enable you to master 
it ina moment. You remember at an early period of 
our researches that we crossed the Mer de Glace from 
the Chapeau side to the Montanvert side. I then 
desired you to notice that the Chapeau side of the 
olacier was more fissured than either the centre or the 
Montanvert side (75). Why should this beso? Know- 
ing as we now do that the Chapeau side of the glacier 
moves more quickly than the other; that the point of 
maximum motion does not he on the centre but far east 
of it, we are prepared to answer this question in a per- 
fectly satisfactory manner. | 

279. Let 4B and cD, in the diagram opposite, re- 
present the two curved sides of the Mer de Glace at the 
Montanvert, and let mn bea straight line across the 
glacier. Leto be the point of maximum motion. The 
mechanical state of the two sides of the glacier may 
be thus made plain. Supposing the line mn to be a 
straight elastic string with its ends fixed; let it be 


CLOUDS AND RIVERS, ICE AND GLACIERS. 111 


grasped firmly at the point o by the finger and thumb, 
and drawn to o’, keeping the distance between o’ and 


Montanvert 


the side c p constant. Here the length, 7 0 of the string 
would have stretched to 7 o’, and the length mo to mo’, 
and you see plainly that the stretching of the short line, 
in comparison with its length, is greater than that of 
the long line in comparison with its length. In other 
words, the strain upon no’ is greater than that upon 
mo’; so that if one of them were to break under the 
strain, it would be the short one. 

280. These two lines represent the conditions of strain 
upon the two sides of the glacier. The sides are held 
back, and the centre tries to move on, a strain being 
thus set up between ‘the centre and sides. But the 
displacement of the point of maximum motion through 
the curvature of the valley makes the strain upon the 
eastern ice greater than that upon the western. The 
eastern side of the glacier is therefore more crevassed 
than the western. 

281. Here indeed resides the difficulty of getting 
along the eastern side of the Mer de Glace: a difficulty 


112 THE FORMS OF WATER IN 


which was one reason for our crossing the glacier 
opposite to the Montanvert. There are two convex 
sweeps on the eastern side to one on the western side, 
hence on the whole the eastern side of the Mer de Glace 
1s most riven. | , 


§ 43. Moraine-ridges, Glacier Tables, and Sand Cones. 


282. When you and I first crossed the Mer de Glace 
from Trélaporte to the Couvercle, we found that the 
stripes of rocks and rubbish which constituted the 
medial moraines were ridges raised above the general 
level of the glacier to a height at some places of twenty 
or thirty feet. On examining these ridges we found the 
rubbish to be superficial, and that it rested upon a great 
spine of ice which ran along the back of the glacier. 
By what means has this ridge of ice been raised ? 

283. Most boys have read the story of Dr. Franklin’s 
placing bits of cloth of various colours upon snow on a 
sunny day. The bits of cloth sank in the snow, the 
dark ones most. 

284. Consider this experiment. The sun’s rays first 
of all fall upon the upper surface of the cloth and warm 
it. The heat is then conducted through the cloth to 
the under surface, and the under surface passes it on to 
the snow, which is finally liquefied by the heat. It is . 
quite manifest that the quantity of snow melted will 
altogether depend upon the amount of heat sent from 
the upper to the under surface of the cloth. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 113 


285. Now clcth is what is called a bad conductor. 
It does not permit heat to travel freely through it. 
But where it has merely to pass through the thickness 
of a single bit of cloth, a good quantity of the heat 
gets through. ‘But if you double or treble or quintuple 
the thickness of the cloth; or, what is easier, if you put 
several pieces one upon the other, you come at length 
- toa poirit where no sensible amount of heat could get 
through from the upper to the under surface. 

286. What must occur if such a thick piece, or such 
a series of pieces of cloth, were placed upon snow on 
which a strong sun is fallimg? The snow round the 
cloth is melted, but that underneath the cloth is pro- 
tected. If the action continue long enough the in- 
evitable result will be, that the level of the snow all 
round the cloth will sink, and the cloth will be left 
behind perched upon an eminence of snow. 

287. If youunderstand this, you have already mastered 
the cause of the moraine-ridges. They are not produced 
by any swelling of the ice upwards. But the ice under- 
neath the rocks and rubbish being protected from 
the sun, the glacier right and left melts away and leaves 
a ridge behind. 

288. Various other appearances upon the glacier are 
accounted for in the same way. Here upon the Mer de 
Glace we have flat slabs of rock sometimes lifted up on 
pillars of ice. These are the so-called Glacier Tables. 
They are prodused, not hy the growth of a stalk of ice 


11-4. THE FORMS OF WATER IN 


out of the glacier, but by the melting of the glacier all 
round the ice protected by the stone. Here is asketch 
of one of the Tables of the Mer de Glace. 


) 
| 


289. Notice moreover that a glacier table is hardly ever 
set square upon its pillar. It generally leans to one 
side, and repeated observation teaches you that it so 
leans as to enable you always to draw the north and 
south line upon the glacier. For the sun being south 
of the zenith at noon pours its rays against the south- 
ern end of the table, while the northern end remains in 
shadow. The southern end, therefore, being most 
warmed does not protect the ice underneath it so effec- 
tually as the northern end. The table becomes inclined, 
and ends by sliding bodily off its pedestal. 

290. In the figure opposite we have what may be called 


CLOUDS AND RIVERS, ICE AND GLACIERS. 115 


an ideal Table. The oblique lines represent the direction 
of the sunbeams, and the consequent tilting of the table 
here shown resembles that observed upon the glaciers. 

291. A pebble will not rise thus: like Franklin’s 
single bit of cloth, a dark-coloured pebble sinks in the 
ice. A spot of black mould will not rest upon the sur- 
face, but will sink ; and various parts of the Glacier du 
Géant are honeycombed by the sinking of such spots of 
dirt into the ice. 

292. But when the dirt is of a thickness sufficient to 
protect the ice the case is different. Sand is often 


wasned away by a stream from the mountains, or from 
the moraines, and strewn over certain spaces of the 
glacier. A most curious action follows: the sanded 


116 THE FORMS OF WATER IN 


surface rises, the part on which the sand lies thickest 
rising highest. Little peaks and eminences jut forth, 
and when the distribution of the sand is favourable, 
and the action sufficiently prolonged, you have little 
mountains formed, sometimes singly, and sometimes 
erouped so asto mimic the Alps themseives. The Sand 
Cones of the Mer de Glace are not striking; but on 
the Gorner, the Aletsch, the Morteratsch, and other 
glaciers, they form singly and in groups, reaching 
scmetimes a height of ten or twenty feet. 


§ 44. The Glacier Mills or Moulins. 


293. You and I have learned by long experience the 
character of the Mer de Glace. We have marched over 


it daily, with a definite object in view, but we have 


not closed our eyes to other objects. It is from side 
glimpses of things which are not at the moment occu- 
-pying our attention that fresh subjects of enquiry arise 
in scientific investigation. 

294. Thus in marching over the ice near Trélaporte 
we were often struck by a sound resembling low rumbling 
thunder. We subsequently sought out the origin of 
this sound, and found it. | 

295. A large area of this portion of the glacier is 
unbroken. Driblets of water have room to form rills; 
rills to unite and form streams; streams to combine to 
torm rushing brooks, which sometimes cut deep chan 
nels in the ice. Sooner or later these streams reach a 


CLOUDS AND RIVERS, ICE AND GLACIERS. L117 


strained portion of the glacier, where a crack is forined 
across the stream. A way is thus opened for the water 
to the bottom of the glacier. By leng action the stream 
hollows out a shaft, the crack thus becoming the 
starting-point of a funnel of unseen depth, into which 
the water leaps with the sound of thunder. 

296. This funnel and its cataract form a glacier Mill 
or Moulin. 

297. Let me grasp your hand firmly while you stand 
upon the edge of this shaft and look into it. The hole, 
with its pure blue shimmer, is beautiful, but it is terrible. 
Incautious persons have fallen into these shafts, a 
second or two of bewilderment being followed by sudden 
death. But caution upon the glaciers and mountains 
ought, by habit, to be made a second nature to explorers 
like you and me. 

298. The crack into which the stream first descended 
to form the moulin, moves down with the glacier. A 
succeeding portion of the ice reaches the place where 
the breaking strain is exerted. A new crack is then 
formed above the moulin, which is thenceforth for- 
saken by the stream, and moves downward as an empty 
shaft. Here upon the Mer de Glace, in advance of the 
Grand Moulin, we see no less than six of these forsaken 
noles. Some of them we sound to a depth of 90 feet. 

299, But youand I both wish to determine, if possible, 
the entire depth of the Mer de Glace. The Grand 
Moulin offers a chance of doing this which we must not 


Jis THE FORMS OF WATER IN 


reclect. Our first effort to sound the moulin fails 
‘hrough the breaking of our cord by the impetuous 
plunge of the water. A lump of grease in the hollow 
of a weight enables a mariner to judge of a sea bottom. 
We employ such a weight, but cannot reach the bed of 
the glacier. A depth of 163 feet is the utmost reached 
by our plummet. 

300. From July 28 to August 8 we have watched the 
progress of the Grand Moulin. On the former date 
the position of the Moulin was fixed. On the 81st it 
had moved down 50 inches; a little more than a day 
afterwards it had moved 74 inches. On August 8 it 
had moved 198 inches, which gives an average of about 
18 inches in twenty-four hours. No doubt next summer 
upon the Mer de Glace a Grand Moulin will be found 
thundering near Trélaporte; but like the crevasse, of 


the Grand Plateau, already referred to (§ 16), it will 


not be our Moulin. This, or rather the ice which it 
penetrated, is now probably more than a mile lower 
down than it was in 1857. 7 


§ 45. The Changes of Volume of Water by Heat and Cold. 


801. We have noticed upon the glacier shafts and — 


pits filled with water of the most delicate blue. 
In some cases these have been the shafts of extinct 
moulins closed at the bottom. A theory has been 
advanced to account for them, which, though it may 
be untenable, opens out considerations regarding the 


CLOUDS AND RIVERS, ICE AND GLACIERS. 119 


properties of water that ought to be familiar to enquirers 
like you and me. 

302. In our dissection of lake ice by a beam of heat 
‘§ 11) we noticed little vacuous spots at the centres of 
the liquid flowers formed by the beam. ‘These spots we 
referred to the fact that when ice is melted the water 
produced is less in volume than the ice, and that hence 
the water of the flower was not able to occupy the whole 
space covered by the flower. 

303. Let us more fully illustrate this subject. Stop 
a small flask water-tight with a cork, and through the 
cork introduce a narrow glass tube also water-tight. 
It is easy to fill the flask with water so that the liquid 


shall stand at a certain height in the glass tube. 


304. Let us now warm the flask with the flame of a 
spirit-lamp. On first applying the flame you notice 
a momentary sinking of the liquid in the glass tube. 
This is due to the momentary expansion of the flask 
by heat; it becomes suddenly larger when the flame 
is first applied. 

305. But the expansion of the water soon overtakes 
that of the flask and surpasses it. We immediately see 
the rise of the liquid column in the glass tube, exactly 
as mercury rises in the tube of a warmed thermometer. 

306. Our glass tube is ten inches long, and at starting 
the water stood in it at a height of five inches. We 
will apply the spirit-lamp flame until the water rises 
quite to the top of the tube and trickles over. This 


120 THE FORMS OF WATER IN 


experiment suffices to show the expansion of the water 
by heat. 

307. We now take a common finger-glass and put 
into it a little pounded ice and salt. On this we place 
the flask, and then build round it the freezing mixture. 
The liquid column retreats down the tube, proving the 
contraction of the liquid bycold. We allow the shrinking 
to continue for some minutes, noticing that the down- 
ward retreat of the liquid becomes gradually slower, 
and that it finally ceases altogether. 

308. Keep your eye upon the liquid column; it 
remains quiescent for a fraction of a minute, and then 
moves once more. But its motion is now wpwards 
instead of downwards. The freezing mixture now acts 
exuctly like the flame. 

309. It would not be difficult to pass a thermometer 
through the cork into the flask, and it would tell us the 
exact temperature at which the liquid ceased to contract 
and began to expand. At that moment we should find 
the temperature of the liquid a shade over 39° Fahr. 

310. At this temperature, then, water attains its maai- 
mum density. 

311. Seven degrees below this temperature, or at 32° 
Fahr., the liquid begins to turn into solid crystals of ice, 
_ which you know swims upon water because it is bulkier 
fora given weight. In fact, this halt of the approaching 
molecules at the temperature of 39°, is but the prepara- 
tion for the subsequent act of crystallisation, in which 


CLOUDS AND RIVERS, ICE AND GLACIERS. 12) 


the expansion by cold culminates. Up to the point of 
solidification the increase of volume is slow and gradual ; 
while in the act of solidification it is sudden, and of 
overwhelming strength. 

312. By this force of expansion the Florentine Acade- 
micians long ago burst a sphere of copper nearly three 
quarters of an inch in thickness. By the same force 
the celebrated astronomer Huyghens burst in 1667 iron 
cannons a finger breadth thick. Such experiments 
have been frequently made since. Major Williams 
during a severe Quebec winter filled a mortar with 
water, and closed it by driving into its muzzle a plug 
of wood. Exposed to a temperature 50° Fahr. below 
the freezing point of water, the metal resisted the 
strain, but the plug gave way, being projected to a 
distance of 400 feet. At Warsaw howitzer shells 
have been thus exploded; and you and I have shi- 
vered thick bomb-shells to fragments, by placing them 
for half an honr in a freezing mixture. 

313. The theory of the shafts and pits referred to 
at the beginning of this section is this:—The water 
at the surface of the shaft is warmed by the sun, say to 
a temperature of 39° Fahr. The water at the bottom, 
in contact with the ice, must be at 32° or nearit. The 
heavier water is therefore at the top; it will descend 
to the bottom, melt the ice there, and thus deepen the 
shaft. 

314. The circulation here referred to undoubtedly 


[22 THE FORMS OF WATER IN 


goes on, and some curious effects are due to it; bit 
not, I think, the one here ascribed to it. The deepening 
of a shaft implies a quicker melting of its bottom than 
of the surface of the glacier. Ii is not easy to see how 
the fact of the solar heat being first absorbed by water, 
and then conveyed by it to the bottom of the shaft, 
should make the melting of the bottom more rapid than 
that of the ice which receives the direct impact of 
the solar rays. The surface of the glacicr must sink 
at least as rapidly as the bottom of the pit, so that 
the circulation, though actually existing, cannot produce 
the effect ascribed to it. 


§ 46. Consequences flowing from the foregoing Properties 
of Water. Correction of Errors. 


315. 1 was not much above your age when the 
property of water ceasing to contract by cold at a 
temperature of 39° Fahr. was made known to me, and I 
still remember the impression it made upon me. For 
I was asked to consider what would occur in case this 
solitary exception to an otherwise universal law ceased 
to exist. | 

316. [ was asked to reflect upon the condition of a 
lake stored with fish and offering its surface to very 
cold air. It was made clear to me that the water on 
being first chilled would shrink in volume and become 
heavier, that it would therefore sink and have its place 


CLOUDS AND RIVERS, ICE AND GLACIERS. 123 


supplied by the warmer and lighter water from the 
deeper portions of the lake. 

317. It was pointed out to me that without the law 
referred to this process of circuiation would go on until 
the whole water of the lake had been lowered to the 
freezing temperature. Congelation would then begin, 
and would continue as long as any water remained to be 
solidified. One consequence of this would be to destroy 
every living thing contained in the lake. Other calamities 
were added, all of which were said to be prevented by 
the perfectly exceptional arrangement, that after a cer- 
tain time the colder water becomes the lighter, floats 
on the surface of the lake, is there congealed, thus 
throwing a protecting roof over the life below. 

318. Count Rumford, one of the most solid of scientific 
men, writes in the following strain about this question : 
—‘ It does not appear to me that there is anything 
which human sagacity can fathom, within the wide- 
extended bounds of the visible creation, which affords a 
more striking or more palpable proof of the wisdom of 
the Creator, and of the special care He has taken in the 
general arrangement of the universe, to preserve animal 
life, than this wonderful contrivance. 

319. *‘ Let me beg the attention of my readers while 1 
endeavour to investigate this most interesting subject; 
and let me at the same time bespeak his candour and 
indulgence. I feel the danger to which a mortal ex- 
poses himself who has the temerity to explain the designs 

10 


124 THE FORMS OF WATER IN 


of Infinite Wisdom. The enterprise is adventurous, 
but it surely cannot be improper. 

3820. *‘ Had not Providence interfered on this occasion 
in a manner which may well be considered as miracu- 
lous, all the fresh water within the polar circle must — 
inevitably have been frozen to a very great depth in 
winter, and every plant and tree destroyed.’ 

321. Through many pages of his book Count Rumforé 
continues in this strain to expound the ways and in- 
tentions of the Almighty, and he does not hesitate to 
apply very harsh words to those who cannot share his 
notions. He calls them hardened and degraded. We 
are here warned of the fact, which is too often for- — 
gotten, that the pleasure or comfort of a belief, or the 
warmth or exaltation of feeling which it produces, is no 
guarantee of its truth. For the whole of Count Rum- 
ford’s delight and enthusiasm in connexion with this 
subject, and the whole of his ire against those who did 
not share his opinions, were founded upon an erroneous 
notion. 

322. Water is noé a solitary exception to an otherwise 
general law. There are other molecules than those of 
this liquid which require more room in the solid crys- 
talline condition than in the adjacent molten condition. 
Tron is a case in point. Solid iron floats upon molten 
iron exactly as ice floats upon water. Bismuth is a still 
more impressive case, and we could shiver a bomb as 
gertainly by the solidification of bismuth as by that 


CLOUDS AND RIVERS, ICE AND GLACIERS. £25 


of water. There is no fish to be taken care of here, 
still the ‘ contrivance’ is the same. 

323. I am reluctant to mention them in the same 
breath with Count Rumford, but I am told that in our 
own day there are people who profess to find the comforts 
of a religion in a superstition lower than any that has 
hitherto degraded the civilized human mind. So that 
the happmess of a faith and the truth of a faith are two 
totally different things. 

324. Life and the conditions of life are in necessary 
harmony. This is a truism, for without the suitable 
conditions life could not exist. But both life and its 
conditions set forth the operations of inscrutable Power. 
We know not its origin; we know not itsend. And 
the presumption, if not the degradation, rests with 
those who place upon the throne of the universe a 
magnified image of themselves, and make its doings 
a mere colossal imitation of their own. 


§ 47. The Molecular Mechanism of Water-congelation. 


325. But let us return to our science. How are we 
to picture this act of expansion on the part of freezing 
water? By what operation do the molecules demand 
with such irresistible emphasis more room in the solid 
than in the adjacent liquid condition? In all cases of 
this kind we must derive our conceptions from the 
world of the senses, and transfer them afterwards to a 
world transcending the range of the senses. 


126 THE FORMS OF WATER IN 


326. You have not forgotten our conversation re- 
garding ‘atomic poles’ (§ 10), and how the notion 
of polar force came to be applied to crystals. With 
this fresh in your memory, you will have no great difii- 
culty in understanding how expansion of volume may 
accompany the act of crystallisation. 

327. I place anumber of magnets before you. They, 
as matter, are affected by gravity, and, if perfectly free, 
they would move towards each other in ohetens: to 
the attraction of gravity. 

328. But they are not only matter, but . mag hae 
matter. They not only act upon each other by the 
simple force of gravity, but by the polar force of 
magnetism. Imagine them placed at a distance from 
each other, and perfectly free to move. Gravity first 
makes itself felt and draws them together. For a time 
the magnetic force issuing from the poles is insensible ; 
but when a certain nearness is attained, the polar force 
comes into play. The mutually attracting points close 
up, the mutually repellent points retreat, and it is easy 
to see that this action may produce an arrangement of 
the magnets which requires more room. Suppose them 
surrocnded by a box which exactly encloses them at 
the moment the polar force first comes into play. It 
is easy to see that in arranging themselves subsequently 
the repelled corners and ends of the magnets may be 
caused to press against the sides of the box, and even 
to burst it, if the forces be sufficiently strong. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 127 


329. Here then we have a conception wuich may 
be applied to the molecules of water. They, like the 
magnets, are acted upon by two distinct forces. Fora 
time while the liquid is being cooled they approach 
each other, in obedience to their general attraction for 
each other. But at a certain point new forces, some 
attractive, some repulsive, emanating from special points 
of the molecules, come into play. The attracted points 
close up, the repelled points retreat. Thus the mole- 
cules turn and rearrange themselves, demanding, as 
they do so, more space, and overcoming all ordinary 
resistance by the energy of their demand. This, in 
general terms, is an explanation of the expansion of 
water in solidifying: it would be easy to construct an 
apparatuc, for its illustration. 


§ 48. The Dirt Bands of the Mer de Glace. 


330. Pass from bright sunshine into a moderately 
lighted room 3; for a time all appears so dark that the 
objects in the room are not to be clearly distinguished. 
Hit violently by the waves of light ($ 3) the optic nerve 
is numbed, and requires time to recover its sensitiveness. 

331. It is for this reason that I choose the present 
hour for a special observation on the Mer de Glace. 
The sun has sunk behind the ridge of Charmoz, and the 
surface of the glacier is in sober shade. The main 
portion of our day’s work is finished, but we have still 
‘sufficient energy to climb the slopes adjacent te the 


128 THE FORMS OF WATER IN 


Montanvert to a height of a thousand feet or thereabouts 


above the ice. 
332. We now look fairly down upon the glacier, and 


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see it less foreshortened than from the Montanvert. We 
notice the dirt overspreading its eastern side, due to 


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CLOUDS AND RIVERS, ICE AND GLACIERS. 129 


the crowding together of its medial moraines. We see 
the comparatively clean surface of the Glacier du 
Géant; but we notice upon this surfacé an ap- 
pearance which we have not hitherto seen. It is 


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crossed by a series of grey bent bands, which follow 
each other in succession, from Trélaporte downwards. 
We count eighteen of these from our present position. 
(See sketch, page 128.) 


«Pa 


130 . THE FORMS OF WATER IN 


333. These are the Dirt Bands of the Mer de Glace; 
they were first observed by Professor Forbes in 1842. 

334. They extend down the glacier further than we 
can see; and if we cross the valley of Chamouni, and 


climb the mountains at the opposite side, to a point 
near the little auberge, called La Flégére, we shall 


‘ 
7 
~ 
m4 


CLOUDS AND RIVERS, ICE AND GLACIERS. 13] 


command a view of the end of the glacier and observe the 
completion of the series of bands. We notice that they 
are confined throughout to the portion of the glacier 
derived from the Col du Géant.. (See sketch, page 129.) 

335. We must trace them to their source. You 
know how noble and complete a view is obtained of the 
glacier and Col du Géant from the Cleft Station above 
Trélaporte. Thither we must once more climb; and 
thence we can see the succession of bands stretching 
downwards to the Montanvert, and upwards to the base 
of the ice-cascade upon the Glacier du Géant. The 
cascade is evidently concerned in their formation. (See 
sketch opposite.) 

336. And how? Simply enough. The glacier, as 
we know, is broken transversely at the summit of the 
ice-fall, and descends the declivity in a series of great 
transverse ridges. At the base of the fall, the chasms 
are closed, but the ridges in part remain torming 
protuberances, which run like vast wrinkles across 
the glacier. These protuberances are more and more 
bent because of the quicker motion of the centre, and 
the depressions between them form receptacles for the 
fine mud and débris washed by the little rills from the 
adjacent slopes. _ 

357. The protuberances sink gradually through the 
wasting action of the sun, so that long before Trélaporte 
is reached they have wholly disappeared. Not so the 
dirt of which they were the collectors: it continues to 


132 THE FORMS OF WATER IN 


occupy, in transverse bands, the flat surface of the gle. 
cier. At Trélaporte, moreover, where the valley becomes 
narrow, the bands are much sharpened, obtaining there 
the character which they afterwards preserve through- 
out the Mer de Glace. Other glaciers with cascades 
also exhibit similar bands. : 


§ 49. Sea Ice and Icebergs. 


338. We are now equipped intellectually for a cam- 
paign into another territory. Water becomes heavier 
and more difficult to freeze when salt is dissolved in it. 
Sea water is therefore heavier than fresh, and the 
Greenland Ocean requires to freeze it a temperature 
34 degrees lower than fresh water. When concentrated 
till its specific gravity reaches 1:1045, sea water re- 
quires for its congelation a temperature 183 degrees 
lower than the ordinary freezing-point.* 

339. But even when the water is saturated with salt, 
the crystallising force studiously rejects the salt, and 
devotes itself to the congelation of the water alone. 
Hence the ice of sea water, when melted, produces 
fresh water. The only saline particies existing in such 
ice are those entangled mechanically in its pores. They 
have no part or lot in the structure of the crystal. 

340. This exclusiveness, if 1 may use the term, of the 
water molecules; this entire rejection of all foreign 


* Scoresby. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 133 


elenients from the edifices which they build, is enforced 
to a surprising degree. Sulphuric acid has so strong 
an affinity for water that it is one of the most powerful 
agents known to the chemist for the removal of humidity 
from air. Still, as shown by Faraday, when a mixture 
of sulphuric acid and water is frozen, the crystal formed 
is perfectly sweet and free from acidity. The water 
alone has lent itself to the crystallising force. 

341. Every winter in the Arctic regions the sea 
freezes, roofing itself with ice of enormous thickness 
and vast extent. By the summer heat, and the tossing 
of the waves, this is broken up; the fragments are 
drifted by winds and borne by currents. They clash, 
_ they crush each other, they pile themselves into heaps, 
thus constituting the chief danger encountered by 
mariners in the polar seas. 

342. But among the drifting masses of flat sea-ice, 
vaster masses sail, which spring from a totally different 
source. These are the Icebergs of the Arcticseas. They 
rise sometimes to an elevation of hundreds of feet above 
the water, while the weight of ice submerged is about 
seven times that seen above. 

- 343. The first observers of striking natural pheno- 
mena generally allow wonder and imagination more 
than their due place. But to exclude all error arising 
from this cause, I wiil refer to the journal of a cool and 
intrepid Arctic navigator, Sir Leopold McClintock. He 
describes an iceberg 250 feet high, which was aground 


134. THE FORMS OF WATER IN 


in 500 feet of water. This would make the entire 
height of the berg 750 feet, not an unusual altitude for 
the greater icebergs. 

344. From Baffin’s Bay these mighty masses come 
salling down through Davis’ Straits into the broad 
Atlantic. A vast amount of heat is demanded for the 
siinple liquefaction of ice (§ 48); and the melting of 
icebergs is on this account so slow, that when large 
they sometimes maintain themselves till they have been 
drifted 2000 miles from their place of birth. 

845. What is their origin? The Arctic glaciers. 
From the mountains in the interior the indurated snows 
slide into the valleys and fill them with ice. The 
glaciers thus formed move like the Swiss ones, inces- 
santly downward. But the Arctic glaciers reach the 
sea, enter it, often ploughing up its bottom into sub- 
marine moraines. Undermined by the lapping of the 
waves, and unable to resist the strain imposed by their 
own weight, they break across, and discharge vast 
masses into the ocean. Some of these run aground on 
the adjacent shores, and often maintain themselves for 
years. Others escape southward, to be finally dissolved 
in the warm waters of the Atlantic. The first engra- 
ving on the opposite page is copied from a photograph 
taken by Mr. Bradford during a recent expedition to the 
Northern seas. The second represents a mass of ice 
upon the Glacier des Bossons. Their likeness suggests 
their common origin. 


135 


ICE AND GLACIERS. 


Ss, 


R: 


CLOUDS AND RIVE 


\ 


L36 THE FORMS OF WATER JIN 


§ 50. The Aiggischhorn, the Margelin See and its 
Icebergs. 


346. Iam, bcwever, unwilling that you should gui! 
Switzerland without seeing such icebergs as it can show, 
and indeed there are other still nobler glaciers than the 
Mer de Glace with which you ought to be acquainted. 
In tracing the Rhone to its source, you have already 
ascended the valley of the Rhone. Let us visit it again 
together; halt at the little town of Viesch, and go from 
it straight up to the excellent hostelry on the slope of 
the Aigeischhorn. This we shall make our head-quarters 
while we explore that monarch of European ice-streams, 
—the great Aletsch glacier. 

347. Including the longest of its branches, this noble 
ice-river 1s about twenty miles long, while at the middle 
of its trunk it measures nearly a mile and a quarter from 
side to side. The grandest mountains of the Bernese 
Oberland, the Jungfrau, the Monch, the Trugberg, the ~ 
Aletsehhorn, the Breithorn, the Gletscherhorn, and 
many another noble peak and ridge, are the collectors 
of its névés. From three great valleys formed in the 
heart of the mountains these névés are poured, uniting 
together to form the trunk of the Aletsch at a place 
named by a witty mountaineer, the ‘ Place de la Concorde 
of Nature.’ If tke phrase be meant to convey the ideas 
of tranquil grandetr, beauty of form, and purity of hue, 
it is well bestowed. 


CLOUDS AND RIVERS, ICE AND GLACIERS. a7 


348. Our hotel is not upon the peak of the Hggisch- 
horn, but a brisk morning walk soon places us upon the 
top. Thence we see the glacier like a broad river 
stretching upwards to the roots of the Jungfrau, and 
downwards past the Bel Alp towards its end. Pro- 
longing the vision downwards, we strike the noblest 
mountain group in all the Alps,—the Dom and its 
’ attendant peaks, the Matterhorn and the Weisshorn. 
The scene indeed is one of impressive grandeur, a mul- 
titude of peaks and crests here unnamed contributing 
to its glory. 

349. But low down to our right, and surrounded by 
the sheltering mountains, is an object the beauty of 
which startles those who are unprepared for it. Yonder 
we see the naked side of the glacier, exposing glistening 
ice-cliffs sixty or seventy feet high. It would seem as 
if the Aletsch here were engaged in the vain attempt 
to thrust an arm through a lateral valley. It once did 
so; but the arm is now incessantly broken off close to 
the body of the glacier, a great space formerly covered 
by the ice being occupied by its water of liquefaction. 
A lake of the loveliest blue is thus formed, which 
reaches quite to the base of the ice-cliffs, saps them, 
as the Arctic waves sap the Greenland glaciers, and 
receives from them the broken masses which it has 
undermined. As we look down upon the lake, small 
icebergs sail over the tranquil surface, each resembling 
A spowy swan accompanied by its shadow. 


138 THE FORMS OF WATER IN 


_ 350. This is the beautiful little lake of Margelin, or, 
as the Swiss here call it, the Margelin See. You see 
that splash, and immediately afterwards hear the sound 
of the plunging ice. The glacier has broken before our 
cyes, and dropped an iceberg into the lake. All over 
the lake the water 1s set in commotion, thus illustrating 
on a small scale the swamping waves produced by the 
descent of vast islands of ice from the Arctic glaciers. 
Look to the end of the lake. It is cumbered with the 
remnants of icebergs now aground, which have been in 
part wafted thither by the wind, but in part slowly borne 
by the water which moves gently in this direction. 

351. Imagine us below upon the margin of the lake, 
as I happened to be on one occasion. There is one 
large and lonely iceberg about the middle. Suddenly 
a sound like that of a cataractis heard; we look towards 
the iceberg and see water teeming from its sides. 
Whence comes the water? the berg has become top- 
heavy through the melting underneath; it is in the act 
of performing a somersault, and in rolling over carries 
with it a vast quantity of water, which rushes like a 
waterfall down its sides. And notice that the iceberg, 
which a moment ago was snowy-white, now exhibits the 
delicate blue colour characteristic of compact ice. It will 
soon, however, be rendered white again by the action 
of the sun. The vaster icebergs of the Northern seas 
sometimes roll over in the same fashion. A week may 
be spent with delight and profit at the Aiggischhorn. 


CLOUDS AND RIVERS, 1CE AND GLACIERS. 13S 


§ 51. The Bel Alp. 


352. From the Agegischhorn I might lead you along 
the mountain ridge by the Betten See, the fish of which 
we have already tasted, to the Rieder Alp, and thence 
across the Aletsch to the Bel Alp. This is a fine moun- 
tain ramble, but you and I prefer making the glacier 
our highway downwards. Hasy at some places, it is 
by no means child’s play at others to unravel its cre- 
vasses. But the steady constancy and close observation 
which we have hitherto found availing in difficult places 
do not forsake us here. We ciear the fissures; and, 
after four hours of exhilarating work, we find ourselves 
upon the slope leading up to the Bel A!p hotel. 

305. This is one of the finest halting-places in the 
Alps. Stretching before us up to the Aggischhorn 
and Margelin See is the long last reach of the Aletsch, 
with its great medial moraine running along its back. 
At hand is the wild gorge of the Massa, in which the 
snout of the glacier lies couched lke the head of a 


serpent. The beautifulsystem of the Oberaletsch glaciers 


is within easy reach. Above us is a peak called the 
Sparrenhorn, accessible to the most moderate climber, 
and on the summit of which little more than an hour's 
exertion will place you and me. Below us now is the 
Oberaletsch elacier, exhibiting the most perfect of medial 
moraines. Near us is the great mass of the Aletsch- 
horn, clasped by its névés, and culminating in brown 
dt 


140 THE FORMS OF WATER IN 


rock. Itis supported by other peaks almost as noble 
as itself. The Nesthorn is at hand; while sweeping 
round to the west we strike the glorious triad already 
referred to, the Weisshorn, the Matterhorn, and the 
Dom. Take one glance at the crevasses of the glacier 
inmediately below us. It tumbles at its end down a 
steep incline, and is greatly riven. But the crevasses 
open before the steep part is reached, and you notice 
the coalescence of marginal and transverse crevasses, 
producing a system of curved fissures with the convex- 
ities of the curves pointing upwards. The mechanical 
reason of this is now known to you. The glacier-tables 
are also numerous and fine. I should like to linger 
with youhere for a week, exploring the existing glaciers, 
and tracing out the evidences of others that have passed 
away. 


§ 52. The Riffelberg and Gorner Glacier. 


904, And though our measurements and observations 
on the Mer de Glace are more or less representative of 
all that can be made or solved elsewhere, I am unwilling 
to leave you unacquainted with the great system of 
glaciers which stream from the northern slopes of 
Monte Rosa and the adjacent mountains. From the 
Bel Alp we can descend to Brieg, and thence drive to 
Visp; but you and I prefer the breezy heights, so we 
sweep round the promontory of the Nessel, until we 
stand over the Rhone valley, in front of Visp. From 


CLOUDS AND RIVERS ICE AND GLACIERS. 141 


this village an hour’s walking carries us to Stalden, 
where the valley divides into two branches: the one 
leading through Saas over the Monte Moro, and the 
uther through St. Nicholas to Zermatt. The latter is 
our route. 

355. We reach Zermatt, but do not halt there. On 
the mountain ridge, 4,000 feet above the valley, we 
discern the Riffelberg hotel. This we reach. Right in 
front of us is the pinnacie of the Matterhorn, upon 
the top of which it must appear incredible to you 
that a human foot could ever tread. Constancy and 
skill, however, accomplished this, but in the first in- 
stance at a terrible price. In the little churchyard 
of Zermatt we have seen the graves of two of the 
ereatest mountaineers that Savoy and England have 
produced; and who, with two gallant young com- 
panions, fell from the Matterhorn in 1865. 

306. At the Riffelberg we are within an honr’s walk 
of the famous Gorner Grat, which commands so grand 
a view of the glaciers of Monte Rosa. But yonder huge 
knob of perfectly bare rock, which is called the Riffel- 
horn, must be our station. What the Cleft Station is 
to the Mer de Glace, the Riffelhorn is to the Gorner 
glacier and its tributaries. From its lower side the 
rock, easy as it may seem, is inaccessible. Here, indeed, 
in 1865, a fifth good man met his end, and he also lies 
beside his fellow countrymen in the churchyard of Zer- 
matt. Passing a little tarn, or lake, called the Riffel See, 


142 THE FORMS OF WATER IN 


we assail the Riffelhorn on its upper side. Jtis capital 
-ock-practice to reach the summit; and from it we 
command a most extraordinarv scene. 

357. The huge and manv-peaked mass of Monte 
Rosa faces us, and we scan its snows from bottom to 
top. To the rightis the mighty ridge of the Lyskamm, 
also Jaden with snow; and between both lies the 
Western Glacier of Monte Rosa. This glacier meets 
another from the vast snow-fields of the Cima di Jazzi; 
they join to form the Gorner glacier, and from their place 
of junction stretches the customary medial moraine. 
On this side of the Lyskamm rise two beautiful snowy 
eminences, the Twins Castor and Pollux; then come 
the brown crags of the Breithorn, then the Little Mat- 
terhorn, and then the broad snow-field of the Théodule, 
out of which springs the Great Matterhorn, and which 
you and [ will cross subsequently into Italy. — 

308. The valleys and depressions between these moun- 
tains are filled with glaciers. Down the flanks of the 
Twin Castor comes the Glacier des Jumeaux, from Pollux 
comes the Schwartze glacier, from the Breithorn the 
Trifti glacier, then come the Little Matterhorn glacier 
and the Théodule glacier, each, as it welds itself to the 
trank, carrying with it its medial moraine. We can 
count nine such moraines from our present positicn. 
And to a still more surprising degree than on the Mer | 
de Glace, we notice the power of the ice to yield to 
pressure ; the broad névés being squeezed on the trunis 


CLOUDS AND RIVERS, ICE AND GLACIERS. 143 


of the Gorner into white stripes, which become ever 
narrower between their bounding moraines, and finally 
disappear under their own shingle. 

399. On the two main tributaries we also notice 
moraines which seem in each case to rise from the 
body of the glacier, appearing in the middle of the 


THE GORNER GLACIER, WITH MONTE ROSA IN THE DISTANCE, AND THE 
RIFFELHORN TO THE LEFT. 


ice without any apparent origin higher up. These 
at their sources, are sub-glacial moraines, which have 
been rubbed away from rocky promontories entirely 
covered with ice. They lie hidden for a time in the 
body of the glacier, and appear at the surface where 
the ice above them has been melted away by the sun. 


144. THE FORMS OF WATER IN 


360. This is the place to mention a notion long 
entertained by the inhabitants of the high Alps, that 
glaciers possess the power of thrusting out all impu- 
rities from them. Qn the Mer de Glace you and I 
have noticed large patches of clay and black mud which 
evidently came from the body of the glacier, and we can 
therefore understand how natural was this notion of 
extrusion to people unaccustomed to close observation. 
But the power of the glacier in this respect is in reality 
the power of the sun, which fuses the ice above con- 
cealed impurities, and, like the bodies of the guides on 
the Glacier des Bossons (143), brings them to the light 
of day. 

361. On no other glacier will you find more objecta 
of interest than on the Gorner. Sand cones, glacier- 
tables, deep ice gorges cut by streams and bridged fan- 
tastically by boulders, moulins, sometimes arched ice- 
caverns of extraordinary size and beauty. On the lower 
part of the glacier we notice the partial disappearance of 
the medial moraine in the crevasses, and its reappear- 
ance at the foot of the incline. For many years this 
glacier was steadily advancing on the meadow in front 
of it, ploughing up the soil and overturning the chalets 
in its way. It now shares in the general retreat exhi- 
bited during the last fifteen years among the glaciers 
of the Alps. As usual, a river, the Visp, rushes from 
a vault at the extremity of the Gorner glacier. 


; 


CLOUDS AND RIVERS, ICE AND GLACIERS. 145 


§ 53. Ancient Glaciers of Switzerland. 


362. You have not lost the memory of the old 
Moraine, which interested us so much in our first ascent 
from the source of the Arveiron; for it opened our 
minds to the fact that at one period of its history the 
Mer de Glace attained far greater dimensions than it 
now exhibits. Our experience since that time has 
enabled us to pursue these evidences of ice action to an 
extent of which we had then no notion. 

363. Close to the existing glacier, for example, we 
have repeatedly seen the mountain side laid bare by the 
retreat of the ice. This is especially conspicuous just 
now, because for the last fifteen or sixteen years the 
glaciers of the Alps have been steadily shrinking; so 
that it is no uncommon thing to see the marginal rocks 
laid bare for a height of fifty, sixty, eighty, or even one 
hundred feet above the present glacier. On the rocks 
thus exposed we see the evident marks of the sliding; 
and our eyes and minds have been so educated in the 
observation of these appearances that we are now able 
to detect, with certainty, icemarks, or moraines, ancient 
or modern, wherever they appear. 

364. But the elevations at which we have found such 
uvidence might well shake belief in the conclusions to 
which they point. Beside the Massa Gorge, at 1,000 
feet above the present Aletsch, we found a great old 
moraine. Descending the meadows between the Bel Alp 


146 | THE FORMS OF WATER IN 


and Platten, we found another, now clothed with grass, 
and bearing a village on its back. But I wish to earry 
you to a region which exhibits these evidences on a 
still grander and more impressive scale. We have 
already taken a brief flight to the valley of Hasli and 
the Glacier of the Aar. Let us make that giacier our 
starting-point. Walking from it downwards towards 
the Grimsel, we pass everywhere over rocks singularlv 
rounded, and fluted, and scarred. ‘These appearances 
are manifestly the work of the glacier mn recent times. 
But we approach the Grimsel, and at the turniee of 
the valley stand before the precipitous granite flank of 
the mountain. The traces of the aneient ice are here 
as plain as they are amazing. The rocks are so hard 
that not only the fluting and polishing, but even the fine 
scratches which date back unnamable thousands of 
years are as evident as if they had been made yester- 
day. We may trace these evidences to a height of two 
thousand feet above the present valley bed. It is in- 
dubitable that an ice-river of this astounding depth 
once flowed through the vale of Hash. 

365. Yonder is the summit of the Siedelhorn; and 
if we gain it, the Unteraar glacier will he like a map 
below us. From this commanding point we plainly see 
marked upon the mountain sides the height to which 
the ancient ice extended. The ice-ground part of the 
mountains is clearly distinguished from the splintered 
grests which in those distant days rose above the surface 


CLOUDS AND RIVERS, ICE AND GLACIERS. 147 


of the glacier, and which must have then appeared as 
island peaks and crests in the midst of an ocean of ice. 
366. We now scamper down the Siedelhorn, get once 
more into the valley of Hasli, along which we follow 
for more than twenty miles the traces of the ice. Fluted 
precipices, polished slabs, and _ beautifully-rounded 
granite domes. Right and left upon the mountain 
flanks, at great elevations, the evidences appear. We 
follow the footsteps of the glacier to the Lake of 
Brientz; and if we prolonged our enquiries, we should 
learn that all the lake beds of this region, at the time 
now referred to, bore the burden of immense masses 
of ice. 
_ 367. Instead of the vale of Hasli, we might take the 

valley of the Rhone. The traces of a mighty glacier, 
which formerly filled it, may be followed all the way to 
Martigny, which is 60 miles distant from the present 
zze. At Martigny the Rhone glacier was reinforced by 
another from Mont Blanc, and the welded masses 
moved onward, planing the mountains right and left, to 
the Lake of Geneva, the basin of which they entirely 
filled. Other evidences prove that the glacier did not 
end here, but pushed across the low country until it 
encountered the limestone barrier of the Jura Moun- 
tains. 

§ 54. Erratic Blocks. 

368. What are these other evidences? We have 
seen mighty rocks poised on the moraines of the Mer 


{48 THE FORMS OF WATER IN 


de Glace, and we now know that, unless they are split 
and shattered by the frost, these rocks will, at some 
distant day, be landed bodily by the Glacier des Bois 
in the valley of Chamouni. You have already learned 
that these boulders often reveal the mineralogical nature 
of the mountains among which the glacier has passed; 
that specimens are thus brought down of a character 
totally different from the rocks among which they are 
finally landed; this is strikingly the case with the 
erratic blocks stranded along the Jura. 

369. For the Jura itself, as already stated, is lime- 
stone; there is no trace of native granite to be found 
amongst these hills. Still along the breast of the 
mountain above the town of Neufchatel, and at about 
800 feet above the lake of Neufchatel, we find stranded 
a belt of granite boulders from Mont Blanc. And when 
we clear the soil away from the adjacent mountain side, 
we find upon the limestone rocks the scarrings of the 
ancient glacier which brought the boulders here. 

370. The most famous of these rocks, called the 
Pierre 4 Bot, measures 50 feet in length, 40 in height, 
and 20 in width. Multiplying these three numbers 
together, we obtain 40,000 cubic feet as the volume of 
the boulder. | 

371. But this is small compared to some of the 
rocks which constitute the freight of even recent 
glaciers. Let us visit another of them. We have 
already been to Stalden, where the valley divides into 


CLOUDS AND RIVERS, ICE AND GLACIERS. 149 


two branches, the right branch running to St. Nicholas 
and Zermatt, and the left one to Saas and the Monte 
Moro. Three hours above Saas we come upon the end 
of the Allelein glacier, not filling the main valley, but 
thrown athwart it so as to stop its drainage like a dam. 
Above this ice-dam we have the Mattmark Lake, and 
at the head of the lake a small inn well known to 
travellers over the Monte Moro. 

372. Close to this inn is the greatest boulder that 
we have ever seen. It measures 240,000 cubic feet. 
Looking across the valley we notice a glacier with its 
present end half a mile from the boulder. The stone, 
I believe, is serpentine, and were you and I to ex- 
plore the Schwartzberg glacier to its upper fastnesses, 
we should find among them the birthplace of this 
gigantic stone. Four-and-forty years ago, when the 
olacier reached the place now occupied by the boulder, 
it landed there its mighty freight, and then retreated. 
There is a second ice-borne rock at hand which would be 
considered vast were it not dwarfed by the aspect of its 
huger neighbour. 

373. Evidence of this kind might be multiplied te any 
extent. In fact, at this moment, distinguished men, 
like Professor Favre of Geneva, are determining from 
the distribution of the erratic blocks the extent of the 
ancient glaciers of Switzerland. It was, however, an 
engineer named Venetz that first brought these evidences 
to light, and announced to an incredulous world the 


{50 TIIE FORMS OF WATER IN 


vast extension of the ancient ice. M. Agassiz after- 
wards developed and wonderfully expanded the dis- 
covery. Perhaps the most interesting observation 
regarding ancient glaciers is that of Dr. Hooker, 
who, during a recent visit to Palestine, found the 
celebrated Cedars of Lebanon growing upon ancient 
moraines. 


§ 55. Ancient Glaciers of England, Ireland, Scotland, 
and Wales. 


374. At the time the ice attained this extraordinary 
development in the Alps, many other portions of EKurope, 
where no glaciers now exist, were covered with them. 
In the Highlands of Scotland, among the mountains ot 
Kingland, Ireland, and Wales, the ancient glaciers have 
written their story as plainly as in the Alps themselves. 
T should like to wander with you through Borrodale in 
Cumberland, or through the valleys near Bethgellert in 
Wales. Under all the beauty of the present scenery we 
should discover the memorials of a time when the whole 
region was locked in the embrace of ice. Professor 
Ramsay is especially distinguished by his writings on 
the ancient glaciers of Wales. 

375. We have made the acquaintance of the Reeks 
of Magillicuddy as the great condensers of Atlantie 
vapour. At the time now referred to, this moisture 
did not fall as soft and fructifying rain, but as snow, 
which formed the nutriment of great glaciers. A chain 


: 


CLOUDS AND RIVERS, ICE AND GLACIERS. 15] 


of lakes now constitutes the chief attraction of Killarney, 
the Lower, the Middle, and the Upper Lake. Let us 
suppose ourselves rowing towards the head of the Upper 
Lake with the Purple Mountain to our left. Remem- 
bering our travels in the Alps, you would infallibly call 
my attention to the planing of the rocks, and declare 
She action to be unmistakably that of glaciers. With 
our attention thus sharpened, we land at the head of 
the lake, and walk up the Black Valley to the base of 
Magillicuddy’s Reeks. Your conclusion would be, that 
this valley tells a tale as wonderful as that of Hasli. 
376. We reach our boat and row homewards along the 
Upper Lake. Its islands now possess a new interest 
for us. Some of them are bare, others are covered 
wholly or in part with luxuriant vegetation ; but both the 
naked and clothed islands are glaciated. The weather- 
ine of ages has not altered their forms: there are the 
Cannon Rock, the Giant’s Coffin, the Man of War, ali 
sculptured as if the chisel had passed over them in our 
own lifetime. These lakes, now fringed with tender 
woodland beauty, were all occupied by the ancient ice. 
It has disappeared, and seeds from other regions have 
been wafted thither to sow the trees, the shrubs, the 
ferns, and the grasses which now beautify Killarney. 
Man himself, they say, has made his appearance in the 
world since that time of ice; but of the real period and 
manner of man’s introduction little is professed to be 
known since, to make them square with science. new 


Fa THE FORMS OF WATER IN 


meanings have becn found for the beautiful myths and 
stories of the Bible. | 

377. It is the nature and tendency of the human 
mind to look backward and forward; to endeavour to 
restore the past and predict the future. Thus endowed, 
from data patiently and painfully won, we recover in 
idea a state of things which existed thousands, it may 
be millions, of years before the history of the human 
race began. 


§ 56. The Glacial Epoch. 


378. This period of ice-extension has been named the 
Glacial Epoch. In accounting for it great minds have 
fallen into grave errors, aS we shall presently see. 

3879. The substance on which we have thus far been 
working exists in three different states: as a solid in 
ice; as a liquid in water; as a gas in vapour. To 
cause it to pass from one of these states to the next 
following one, heat is necessary. 

880. Dig a hole in the ice of the Mer de Glace in 
summer, and place a thermometer in the hole; it will 
stand at 32° Fahr. Dip your thermometer into one of 
the glacier streams; it will still mark 32°. The water is 
therefore as cold as ice. 

3881. Hence the whole of the heat poured by the sun 
upon the glacier, and which has been absorbed by the 
glacier, is expended in simply liquefying the ice, and 
not in rendering either ice or water a single degree 
warmer. | 


> = ~-:.” -_o = —=s—— 


———— 


: 
| 
j 
} 


CLOUDS AND RIVERS, ICE AND GLACIERS. 153 


882. Expose water to a fire; it becomes hotter for a 
time. It boils, and from that moment it ceases to get 
hotter. After it has begun to boil, all the heat com- 
municated by the fire is carried away by the steam, 
though the steam itself is not the least fraction of a degree 
hotter than the water. 

383. In fact, simply to liquefy ice a large quantity of 
heat is necessary, and to vaporize water a still larger 
quantity is necessary. And inasmuch as this heat does 
not render the water warmer than the ice, nor the 
steam warmer than the water, it was at one time sup- 
posed to be Aidden in the water and in the steam. 
And it was therefore called latent heat. 

384. Let us ask how much heat must the sun expend 
in order to convert a pound weight of the tropical ocean 
into vapour? ‘This problem has been accurately solved 
by experiment. It would require in round numbers 
1,000 times the amount of heat necessary to raise one 
pound ot water one degree in temperature. 

3085. But the quantity of heat which would raise the 
temperature of a pound of water one degree would raise 
the temperature of a pound of iron ten degrees. This 
has been also proved by experiment. Hence to convert — 
one pound of the tropical ocean into vapour the sun 
must expend 10,000 times as much heat as would raise 
one pound of iron one degree in temperature. 

386. This quantity of heat would raise the tempera- 
ture of 5 lbs. of iron 2,000 degrees, which is the fusing 
point of cast iron; at this temperature the metal would 


154 THE FORMS OF WATER IN 


not only be white hot, but would be passing into the 
molten condition. 

387. Consider the conclusions at which we have now 
arrived. For every pound of tropical vapour, or for 
every pound of Alpine ice produced by the congelation 
of that vapour, an amount of heat has been expended 
by the sun sufficient to raise 5 ibs. of cast iron to its 
melting-point. 

388. It would not we difficult to calculate approxi- 
mately the weight of the Mer de Glace and its tribu- 
taries—to say, for example, that they contained so many 
millions of millions of tons of ice and snow. Let the 
place of the ice be taken by a mass of white-hot iron of 
quintuple the weight; with such a picture before your 
mind you get some notion of the enormous amount of 
heat paid out by the sun to produce the present glacier. 

389. You must think over this, until it is as clear as 
sunshine. For you must never henceforth fall into the 
error already referred to, and which has entangled so 
many. So natural was the association of ice and cold, 
that even celebrated men assumed that all that is needed 
to produce a great extension of our glaciers is a dimi- 
nution of the sun’s temperature. Had they gone 
through the foregoing reflections and calculations, they 
would probably have demanded more heat instead of less 
for the production of a ‘glacial epoch.” What they 
really needed were condensers sufficiently powerful to 
congeal the vapour generated by the heat of the sun. 


CLOUDS AND RIVERS, ICE AND GLACIERS, 155 


§ 57. Glacier Theories. 


390. You have not forgotten, and hardly ever can 
furget, our climbs to the Cleft Station. Thoughts were 
then suggested which we have not yet discussed. We 
saw the branch glaciers coming down: from their névés, 
welding themselves together, pushing through Tréla- 
porte, and afterwards moving through the sinuous 
valley of the Mer de Glace. These appearances alone, 
without taking into account subsequent observations, 
were sufficient to suggest the idea that glacier ice, how- 
ever hard and brittle it may appear, is really a viscous 
substance, resembling treacle, or honey, or tar, or 
lava. 


§ 58. Dilatation and Sliding Theorves. 


391. Still this was not the notion expressed by the 
majority of writers upon glaciers. Scheuchzer of 
Zurich, a great naturalist, visited the glaciers in 1705, 

and propounded a theory of their motion. Water, he 
_ knew, expands in freezing, and the force of expansion is 
so great, that thick bombshells filled with water, and | 
permitted to freeze, are, as we know (812), shattered to 
pieces by the ice within. Scheuchzer supposed that the 
water in the fissures of the glaciers, freezing there and 
expanding with resistless force, was the power which 
urged the glacier downwards. He added to this theory 
other notions of a less scientific kind. 

12 


[56 THE FORMS OF WATER IN 


392. Many years subsequently, De Charpentier of Bex 
renewed and developed this theory with such ability 
and completeness, that 1t was long known as Charpen- 
tier’s Theory of Dilatation. M. Agassiz for a time 
espoused this theory, and it was also more or less dis- 
tinctly held by other writers. The glacier, in fact, was 
considered to be a magazine of cold, capable of freezing 
all water percolating through it. The theory was 
abandoned when this notion of glacier cold was ee 
by M. Agassiz to be untenable. 

393. In 1760, Altmann and Griiner propounded the 
view that glaciers moved by sliding over their beds. 
Nearly forty years subsequently, this notion was revived 
by De Saussure, and it has therefore been called ‘De 
Saussure’s Theory,’ or the ‘Sliding ‘Theory’ of glacier 
motion. 

394. There was, however, but little reason to connect 
the name of De Saussure with this or any other theory 
of glaciers. Incessantly occupied in observations of 
another kind, this celebrated man devoted very little 
time or thought to the question of glacier motion. 
What he has written upon the subject reads less like 
the elaboration of a theory than the expression of an 
opinion. | 

§ 59. Plastic Theory. 

395. By none of these writers is the property of vis- 
cosity or plasticity ascribed to glacier ice; the appear- 
ances of many glaciers are, however, so suggestive of 


CLOUDS AND. RIVERS, ICE AND GLACIERS. 457 


this idea that we may be sure it would have found more 
frequent expression, were 1t not in such apparent con- 
tradiction with our every-day experience of ice. 

396. Still the idea found its advocates. In a little 
book, published in 1773, and entitled ‘ Picturesque 
Journey to the Glaciers of Savoy,’ Bordier of Geneva 
wrote thus :—‘ It is now time to look at ail these objects 
with the eyes of reason; to study, in the first place, the 
position and the progression of glaciers, and to seek the 
solution of their principal phenomena. At the first as- 
pect of the ice-mountains an observation presents itself, 
which appears sufficient to explain all. It is that the 
entire mass of ice is connected together, and presses 
from above downwards after the manner of fluids. Let 
us then regard the ice, not as a mass entirely rigid 
and immobile, but as a heap of coagulated matter, or as 
softened wax, flexivie and ductile to a certain point.’ * 
Here probably for the first time the quality of plasticity 
is ascribed to the ice of glaciers. 

397. To us, familiar with the aspect of the glaciers, 
it must seem strange that this idea once expressed did 
not at once receive recognition and development. But 
in those early days explorers were few, and the ‘ Pic- 
turesque Journey’ probably but little known, so that 
the notion of plasticity lay dormant for more than half 

* Tam indebted to my distinguished friend Prof. Studer of Berne for 


- directing my attention to Bordier’s book, and to my friends at the British 
Museum for the great trouble they have taken to find it for me. 


158 THE FORMS OF WATER IN 


a century. But Bordier was at length succeeded by a 
man of far greater scientific grasp and insight than 
himself. This was Rendu, a Catholic priest and canon 
when he wrote, and afterwards Bishop of Annecy. In 
1841 Rendu laid before the Royal Academy of Sciences 
of Savoy his ‘ Theory of the Glaciers of Savoy,’ a con- 
tribution for ever memorable in relation to this subject.* 
- 398. Rendu seized the idea of glacier plasticity with 
- great power and clearness, and followed it resolutely te 
its consequences. It is not known that he had ever 
seen the work of Bordier; probably not, as he never 
mentions it. Let me quote for you some of Rendu’s 
expressions, which, however, fail to give an adequate 
idea of his insight and precision of thought :—‘ Between 
the Mer de Glace and a river there is a resemblance so 
complete that it is impossible to find in the glacier a 
circumstance which does not exist in the river. In 
currents of water the motion is not uniform either 
throughout their width or throughout their depth. 
The friction of the bottom and of the sides, with the 
action of local hindrances, causes the motion to vary, 
and only towards the middle of the surface do we 
obtain the full motion.’ 

399. This reads like a prediction of what has since 
been established by measurement. Looking at the 
clacier of Mont Dolent, which resembles a sheaf in 
form, wide at both ends and narrow in the middle, and 


* ‘Memoirs of the Academy,’ vol. x. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 159 


reflecting that the upper wide part had become narrow, 
and the narrow middle part again wide, Rendu observes, 
‘There is a multitude of facts which seem to necessitate 
the belief that glacier ice enjoys a kind of ductility 
which enables it to mouid itself to its locality, to thin 
out, to swell, and to contract as if it were a soft paste.’ 

400. To fully test his conclusions, Rendu required 
the accurate measurement of glacier motion. Had he 
added to his other endowments the practical skill of a 
land-surveyor, he would now be regarded as the prince 
of glacialists. As it was he was obliged to be content 
with imperfect measurements. In one of his excur- 
sions he examined the guides regarding the successive 
positions of a vast rock which he found upon the ice 
close to the side of the glacier. The mean of five years 
gave him a motion for this block of 40 feet a year. 

401. Another block, the transport of which he sub- 
sequently measured more accurately, gave him a velocity 
of 400 feet a year. Note his explanation of this dis- 
crepancy:—‘ The enormous difference of these two obser- 
vations arises from the fact that one block stood near 
the centre of the glacier, which moves most rapidly, 
while the other stood near the side, where the ice is 
held back by friction.” So clear and definite were 
Rendu’s ideas of the plastic motion of glaciers, that had 
the question of curvature occurred to him, I entertain 
no doubt that he would have enunciated beforehand the 


L60 ~ THE FORMS OF WATER IN 


shifting of the point of maximum motion from side to 
side across the axis of the glacier (§ 25). 

402. Itis right that you should know that scientific 
men do not always agree in their estimates of the cow- 
parative value of facts and ideas; and it is especially 
right that you should know that your present tutor 
attaches a very high value to ideas when they spring 
from the profound and persistent pondering of superior 
minds, and are not, as 1s too often the case, thrown out 
without the warrant of either deep thought or natural 
capacity. It is because I believe Ren lu’s labours fulfil 
this condition, that I ascribe to ther: so high a value. 
But when you become older and better informed, you 
may differ from me; and I write tl.ese words lest you 
should too readily accept my opinion of Rendu. Judge 
me, if you care to do so, when your knowledge is 
matured. I certainly shall not fear your verdict. 

403. But, much as I prize the prompting idea, and 
thoroughly as I believe that often in it the force of 
genius mainly lies, it would, in my opinion, be an error 
of omission of the gravest kind, and which, if habitual, 
would ensure the ultimate decay of natural knowledge, 
to neglect verifying our ideas, and giving them outward 
reality and substance when the means of doing so are 
at hand. In science thought, as far as possible, ought 
to be wedded to fact. This was attempted by Rendu, 
and in great part accomplished by Agassiz and Forbes. 


: 
: 
| 


CLOUDS AND RIVERS, ICE AND GLACIERS. 161 


§ 60. Viscous Theory. 


404. Here indeed the merits of the distinguished 
elacialist last named rise conspicuously to view. From 
the able and earnest advocacy of Professor Forbes, the 
public knowledge of this doctrine of glacial plasticity is 
almost wholly derived. He gave the doctrine a more 
distinctive form; he first appled the term viscous to 
glacier ice, and sought to found upon precise measure- 
ments a ‘ Viscous Theory’ of glacier motion. 

405. Iam here obliged to state facts in their historic 
sequence. Professor Forbes when he began his invest?- 
gations was acquainted with the labours of Rendu. Iu 
his earliest work upon the Alps he refers to those 
labours in terms of flattering recognition. But though 
as a matter of fact Rendu’s ideas were there to prompt 
him, it would be too much to say that he needed their 
inspiration. Had Rendu not preceded him, he might 
none the less have grasped the idea of viscosity, execut~ 
ing his measurements and applying his knowledge to 
maintain it. Be that as it may, the appearance of Pro- 
fessor Forbes on the Unteraar glacier in 1841, and on 
the Mer de Glace in 1842, and his labours then and 
subsequently, have given him a name not to be for- 
gotten in the scientific history of glaciers. i 

406. The theory advocated by Professor Forbes was 
enunciated by himself in these words :—‘ A glacier is an 
imperfect fluid, or viscous body, which is urged down 


162 THE. FORMS OF WATER IN 


slopes of certain inclination by the natural pressure 
of its parts.” In 1773 Bordier wrote thus:—‘ As the 
glaciers always advance upon the plain, and never dis- 
appear, it is absolutely essential that new ice shall per- 
petually take the place of that which is melted: it 
must therefore be pressed forward from above. One 
can hardly refuse then to accept the astonishing truth, 
that this vast extent of hard and solid ice moves as 
a single piece downwards.’ In the passage already 
quoted he speaks of the ice being pressed as a fluid 
from above. These constitute, I believe; Bordier’s con- 
tributions to this subject. The quotations show his 
sagacity at an early date; but, in point of completeness, 
his views are not to be compared with those of Rendu 
and Forbes. 

407. I must not omit to state here that though the 
idea of viscosity has not been espoused by M. Agassiz, 
his measurements, and maps of measurements, on the 
Unteraar glacier have been recently cited as the most 
clear and conclusive illustrations of a quality which, at 
all events, closely resembles vicosity. 

408. But why, with proofs before him more copious 
and characteristic than those of any other wbserver, does 
M. Agassiz hesitate to accept the idea of viscosity ax 
applied to ice? Doubtless because he believes the 
notion to be contradicted by our every-day experience 
of the substance. 

409. Take a mass of ice ten or even fifteen cubic feet 


CLOUDS AND RIVERS, ICE AND GLACIERS. 163 


in volume; draw a saw across it to a depth of half an 
ich or an inch; and strike a pointed pricker, not 
thicker than a very small round file, into the groove ; 
_ the substance will split from top to bottom with a clean 
erystalline fracture. How is this brittleness to be 
reconciled with the notion of viscosity ? 

410. We have, moreover, been upon the glacier and 
have witnessed the birth of crevasses. We have seen 
them beginning as narrow cracks suddenly formed, days 
being reguired to open them a single inch. _ In many 
glaciers fissures may be traced narrow and profound for 
hundreds of yards through the ice. What does this 
prove? Did the ice possess even a very small modicum 
of that power of stretching, which is characteristic of a 
viscous substance, such crevasses could not be formed. 

A411. Still it is undoubted that the glacier moves like 
a viscous body. The centre flows past the sides, the top 
fiows over the bottom, and the motion through a curved 
valley corresponds to fluid motion. Mr. Mathews, Mr. 
Froude, and above all Signor Bianconi, have, more- 
over, recently made experiments on ice which strikingly 
illustrate the flexibility of the substance. These experi- 
ments merit, and will doubtless receive, full attention 
at a future time. 3 


§ 61. Regelation Theory. 


412. I will now describe to you an attempt that has 
been made of late years to reconcile the brittleness of 


164 THE FORMS OF WATER IN 


ice with its motion in glaciers. It is founded on the 
observation, made by Mr. Faraday in 1850, that when 
two pieces of thawing ice are placed together they 
freeze together at the place of contact. 

413. This fact may not surprise you; still it surprised 
Mr. Faraday and others, and men of very great distinc- 
tion in science have differed in their interpretation of the 
fact. The difficulty is to explain where, or Low, in ice 
already thawing the cold is to be found requisite to freeze 
the film of water between the two touching surfaces. 

414. The word Regelation was proposed by Dr. Hooker 
tc express the freezing together of two pieces of thawing 
ice cbserved by Faraday; and the memoir in which the 
term was first used was published by Mr. Huxley and 
Mr. Tyndall in the Philosophical Transactions for 1857. 

415. The fact of regelation, and its application irre- 
spective of the cause of regelation, may be thus illus- 
trated :—Saw two slabs from a block of ice, and bring 
their flat surfaces into contact; they immediately freeze 
together. Two plates of ice, laid one upon the other, 
with flannel round them overnight, are sometimes so 
firmly frozen in the morning that they will rather break 
elsewhere than along their surface of junction. If you 
enter one of the dripping ice-caves of Switzerland, you 
have only to press for a moment a slab of ice against 
the roof of the cave to cause it to freeze there and 
stick to the roof. 

416. Place a number of fragments of ice in a basin of 


CLOUDS AND RIVERS, ICE AND GLACIERS. 165 


water, and cause them to touch each other; they freeze 
together where they touch. You can form a chain of 
such fragments; and then, by taking hold of one end 
of the chain, you can draw the whole series after it. 
Chains of icebergs are sometimes formed in this way 
in the Arctic seas. 

417. Consider what follows from these observations, 
Snow consists of small particles of ice. Now if by 
pressure we squeeze out the air entangled in thawing 
snow, and bring the little ice-granules into close contact, 
they may be expected to freeze together; and if the 
expulsion of the air be complete, the squeezed snow may 
be expected to assume the appearance of compact ice. 

418. We arrive at this conclusion by reasoning; !et 
us now test it by experiment, employing a suitable hy- 
draulic press, and a mould to hold the snow. In exact 
accordance with our expectation, we convert by pressure 
the snow into ice.* 

419. Place a compact mass of ice in a proper mould, 
and subject it to pressure. It breaks in pieces: squeeze 
the pieces forcibly together; they re-unite by regela- 
tion, and a compact piece of ice, totally different in 
shape from the first one, is taken from the press. To 
produce this effect the ice must be in a thawing con- 
dition. When its temperature is much below the 
melting point it is crushed by pressure, not into a 


* A similar experiment was made by the Messrs. Schlagintweit prior to 
the discovery which explains it, and which therefore remained unsolved. 


166 THE FORMS OF WATER IN 


pellucid mass of another shape, but into a white 
powder. 

420. By means of suitable moulds you may in this 
way change the shape of ice to any extent, turning out 
spheres, and cups, and rings, and twisted ropes of the 
substance; the change of form in these cases being 
effected through rude fracture and regelation. 

421. By applying the pressure carefully, rude fracture 
may be avoided, and the ice compelled slowly to = 
its form as if it were a plastic body. 

422. Now our first experiment illustrates the con- 
solidation of the snows of the higher Alpine regions. 
The deeper layers of the névé have to bear the weight 
of all above them, and are thereby converted into more 
or less perfect ice. And our last experiment illustrates 
the changes of form observed upon the glacier, where, 
by the slow and constant application of pressure, the ice 
gradually moulds itself to the valley, which it fills. 

423. In glaciers, however, we have also ample illus- 
trations of rude fracture and regelation. ‘The opening 
and closing of crevasses illustrate this. The glacier 
is broken on the cascades and mended at their bases. 
When two branch glaciers lay their sides together, the 
regelation is so firm that they begin immediately to ; 
flow in the trunk glacier as a single stream. The 
medial moraine gives no indication by its slowness of 


motion that it is derived from the sluggish ice of the = i 


sides of the branch glaciers. 


ULOUDS AND RIVERS, ICE AND GLACIERS. 167 


424. 'The gist of the Regelation Theory is that the ice 
of glaciers changes its form aid preserves its continuity 
under pressure which keeps its particles together. But 
when subjected to tension, sooner than stretch it breaks, 
and behaves no longer as a viscous body. 


§ 62. Cause of Regelation. 


425. Here the fact of regelation is applied to explain 
the plasticity of glacier ice, no attempt being made to 


- assign the cause of regelation itself. They are two en- 


tirely distinct questions. But a little time will be well 
spentin looking more closely into the cause of regelation. 
You may feel some surprise that eminent men should de- 
vote their attention to so small a point, but we must not 
forget that in nature nothing is small. Laws and prin- 
ciples interest the scientific student most, and these may 
be as well illustrated by small things as by large ones. 

426. The question of regelation immediately connects 
itself with that of ‘ latent heat,’ already referred to, (383) 
but which we must now subject to further examination. ” 
To melt ice, as already stated, a large amount of heat 
is necessary, and in the case of the glaciers this heat is 
furnished by the sun. Neither the ice so melted nor 
the water which results from its lquefaction can fall 
below 52° Fahrenheit. The freezing point of water and 
the melting point of ice touch each other, as it were, 
at this temperature. A hair’s-breadth lower water 
freezes; a hair’s-breadth higher ice melts. 


168 THE FORMS OF WATER IN 


427. Butif the ice could be caused to melt without this 
supply of solar heat, a temperature lower than that of 
ordinary thawing ice would result. When snow and 
salt, or pounded ice and salt, are mixed together, the 
salt causes the ice to melt, and in this way a cold 
of 20 or 30 degrees below the freezing point may be 
produced. Here, in fact, the ice consumes its own 
warmth in the work of liquefaction. Such a mixture 
of ice and salt is called ‘a freezing mixture.’ 

428. And if by any other means ice at the temperature 
of 32° Fahrenheit could be liquefied without access of 
heat from without, the water produced would be colder 
than the ice. Now Professor James Thomson has preved 
that ice may be liquefied by mere pressure, and his 
»rother, Sir William Thomson, has also shown that 
water under pressure requires a lower temperature to 
freeze it than when the presstre is removed. Professor 
Mousson subsequently liquefied large masses of ice by a 
hydraulic press ; and by a beautitul experiment Professor 
Helmholtz has proved that water in a vessel from which 
the air has been removed, and which is therefore relieved 
from the pressure of the atmosphere, freezes and forme 
ice-crystals when surrounded by melting ice. All these 
facts are summed up in the brief statement that the 
yreezing point of water is lowered by pressure.* 

429, For our own instrnetion we may produce the 


* Professor James Thomson and Professor Clausius proved this inde 
pendently and almost coutemporaneously. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 169 


agnefaction of ice by pressure in the following way: 
— You remember the beautiful flowers obtained when a 
sunbeam is sent through lake ice($ 11), and you have 
not forgotten that the flowers always form parallel to 
the surface of freezing. Let us cut a prism, or small 
column of ice with the planes of freezing running across 
it at right angles; we place that prism between two 
slabs of wood, and bring carefully to bear upon it the 
squeezing force of a small hydraulic press. 

430. It is well toconverge by means of a concave mirror 
a good light upon the ice, and to view it through a 
magnifying lens. You already see the result. Hazy 
surfaces are formed in the very body ot the ice, which 
gradually expand as the pressure is slowly augmented. 
Here and there you notice something resembling crys- 
tallisation ; fern-shaped figures run with considerable 
rapidity through the ice, and when you look carefully at 
their points and edges you find them in visible motion. 
These hazy surfaces are spaces of liquefaction, and the 
motion you see is that of the ice falling to water under 
the pressure. That water is colder than the ice was 
before the pressure was applied, and if the pressure be 
relieved, not only does the liquefaction cease, but the 
water re-freezes. ‘The cold produced by its liquefaction 
under pressure is sufficient to re-congeal it when the 
pressure is removed. 

431. If instead of diffusing the pressure over sut- 
faces of considerable extent, we concentrate it on a 


170 THE FORMS OF WATER IN 


small surface, the liquefaction will of course be more 
rapid, and this is what Mr. Bottomley has recently done 
in an experiment of singular beauty and interest. Let 
us support on blocks of wood the two ends of a bar of 
ice 10 inches long, 4 inches deep, and 3 wide, and let us 
loop over its middle a copper wire one-twentieth, or 
even one-tenth, of an inch in thickness. Connecting 
the two ends of the wire together, and suspending 
from it a weight of 12 or 14 pounds, the whole pressure 
of this weight is concentrated on the ice which sup- | 
ports the wire. What is the consequence? The ice 
underneath the wire liquefies; the water of liquefaction 
escapes round he wire, but the moment it is relieved 
from the press re it freezes, and round about tke wire, 
even before it has entered the ice, you have a frozen 
casing. The wire continues to sink in the ice; the 
water incessantly escapes, freezing as it does so behind 
the wire. In half an hour the weight falis; the wire 
has gone clean through the ice. You can plainly see 
where it has passed, but the two severed pieces of ice 
are so firmly frozen together that they will break else- 
where as soon as along the surface of regelation. 

432. Another beautiful experiment bearing upon this 
point has recently been made by M. Boussingault. oes: 
filled a hollow steel cylinder with water and chilled it. 
In passing to ice water, as you know, expands (§ 45); 
in fuct, room for expansion is a necessary condition of 
solidification. But in the present case the strong steel 


£ 


CLOUDS AND RIVERS, ICE AND GLACIERS. 171 


resisted the expansion, the water in consequence re- 
maining liquid at a temperature of more than 30° Fahr. 
below the ordinary freezing point. A bullet within the 
eylinder rattled about at this temperature, showing 
that the water was still liquid. On opening the tap the 
liquid, relieved of the pressure, was instantly converted 
into ice. 

433. It is only substances which expand on solidify- 
ine that behave in this manner. The metal bismuth, as 
we know, is an example similar to water; while lead, 
wax, or sulphur, all of which contract on solidifying, 
have their point of fusion heightened by pressure. 

454, And now you are prepared to understand Pro- 
fessor James Thomson’s theory of regelation. When 
two pieces of ice are pressed together liquefaction, he 


contends, results. The water spreads out around the 


points of pressure, and when released re-freezes, thus 
forming a kind of cement between the pieces of ice. 


§ 63. Faraday’s View of Regelation. 


435. Haraday’s view of regelation is not so easily 
expressed, still I will try to give you some notion of it, 
dealing in the first place with admitted facts. Water, 
even in open vessels, may be lowered many degrees below 
its freezing temperature, and still remain liquid; it may 
also be raised to a temperature far higher than its boiling 
point, and still resist boiling. Thisis due tothe mutual 
eohesion of the water particles, which resists the change 


15 


L72 THE FORMS OF WATER IN 


of the liquid either into the solid or the vaporous 
condition. | 

436. But if into the over-chilled water you throw a 
particle of ice, the cohesion is ruptured, and congelation 
immediately sets in. And if into the superheated 
water you introduce a bubble of air or of steam, cohe- 
sion is likewise ruptured, and ebullition immediately 
commences. 7 

437. Faraday concluded that i the interior of any 
body, whether solid or liquid, where every particle is 
grasped so to speak by the surrounding particles, and 
grasps them in turn, the bond of cohesion is so strong 
as to require a higher temperature to change the state 
of aggregation than is necessary at the surface. At the 
surface of a piece of ice, for example, the molecules are 
free on one side from the control of other molecules ; 
and they therefore yield to heat more readily than in 
the interior. The bubble of air or steam in overheated 
water also frees the molecules on one side; hence the 
ebullition consequent upon its introduction. Prac- 
tically speaking, then, the point of liquefaction of the 
interior ice is higher than that of the superficial ice. 
Faraday also refers to the special solidifying. power 
which bodies exert upon their own molecules. Cam- 
phor in a glass bottle fills the bottle with an atmos- . 
phere of camphor. In such an atmosphere large crystals 
of the substance may grow by the incessant deposition 
of camphor molecules upon camphor, at a temperature 


CLOUDS AND RIVERS, ICE AND GLACIERS. 173 


too high to permit of the slightest deposit wpon the 
adjacent glass. A similar remark applies to sulphur, 
phosphorus, and the metals in a state of fusion. They 
are deposited upon solid portions of their own substance 
at temperatures not low enough to cause them to soli- 
dify against other substances. 

438. Water furnishes an eminent -.example of this 
special solidifying power. It may be cooled ten 
degrees and more below its freezing point without 
freezing. But this is not possible if the smallest frag- 
ment of ice be floating in the water. It then freezes 
accurately at 32° Fahr., depositing itself, however, not 
upon the sides of the containing vessel, but wpon the vce. 
Faraday observed in a freezing apparatus thin crystals 
of ice growing in ice-cold water to a length of six, 
eight, or ten inches, at a temperature incompetent to 
produce their deposition upon the sides of the contain- 
ing vessel. 

439. And now we are prepared for Faraday’s view of 
regelation. When the surfaces of two pieces of ice, 
covered with a film of the water of liquefaction, are 
brought together, the covering ‘film is transferred from 
the surface to the centre of the ice, where the point 
of liquefaction, as before shown, is higher than at the 
surface. The special solidifying power of ice upon water 
is now brought into play on both sides of the film. Under 
these circumstances, Faraday held that the film would 
eongeal, and freeze the two surfaces together. 


L74 THE FORMS OF WATER IN 


440. The lowering of the freezing point by pressure 
amounts to no more than one-seventieth of a degree 
Fahrenheit for a whole atmosphere. Considering the 
infinitesimal fraction of this pressure which is brought 
into play in some cases of regelation, Faraday thought its 
effect insensible. He suspended pieces of ice,and brought 
them into contact without sensible pressure, still they 
froze together. Professor James Thomson, however, 
considered that even the capillary attraction exerted 
between two such masses would be sufficient to produce 
regelation. You may make the following experiments, 
in further illustration of this subject :— 

441. Place a small piece of ice on water, and press it 
underneath the surface by a second piece. The sub- 
merged piece may be so small as to render the pressure 
infinitesimal; still it will freeze to the under surface of 
the saperior piece. 

442. Place two pieces of ice in a basin of warm water, 
and allow them to come together; they freeze together 
when they touch. ‘The parts surrounding the place ot 
contact melt away, but the pieces continue for a time 
united by a narrow bridge of ice. The bridge finally 
melts, and the pieces for a moment are separated. But 
capillary attraction immediately draws them together, — 
and regelation sets in once more. A new bridge is 
formed, which in its turn is dissolved, the separated 
pieces again closing up. A kind of pulsation is thus 
established between the two pieces of ice. They touch, 


CLOUDS AND RIVERS, ICE AND GLACIERS. 175 


they freeze, a bridge is formed and melted; and thus 
the rhythmic action continues until the ice disappears. 

443. According to Professor James Thomson’s 
theory, pressure is necessary to liquefy the ice. The 
leat necessary for liquefaction must be drawn from the 
ice itself, and the cold water must escape from the 
pressure to be re-frozen. Now in the foregoing experi- 
ments the cold water, instead of being allowed to freeze, 
issues into the warm water, still the floating fragments 
regelate in a moment. The touching surfaces may, 
moreover, be convex; they may be reduced practically 
to points, clasped all round by the warm water, which 
indeed rapidly dissolves them as they approach each 
other ; still they freeze immediately when they touch. 

444, You may learn from this discussion that in 
scientific matters, as in all others, there is room for 
differences of opinion. The frame of mind to be culti- 
vated here is a suspension of judgment as long as the 
meaning remains in doubt. It may be that Faraday’s 
action and Thomson’s action come both into play. I 
cannot do better than finish these remarks by quoting 
Faraday’s own concluding words, which show how in 
his mind scientific conviction dwelt apart from dogma- 
tism :—‘ No doubt,’ he says, ‘nice experiments will 
enable us hereafter to criticise such results as these, 
and separating the true from the uatrue will establish 
the correct theory of regelation.’ 


L176 THE FORMS OF WATER IN 


§ 64. The Blue Veins of Glaciers. 


445, We uow approach the end, one important 
question only remaining to be discussed. Hitherto we 
have kept it back, for a wide acquaintance with the 
glaciers was necessary to its solution. We had also 
to make ourselves familiar by actual experiment with 
the power of ice, softened by thaw, to yield to pressure, 
and to liquefy under such pressure. 

446. Snow is white. But if you examine its in- 
dividual particles you would call them transparent, not 
white. ‘The whiteness arises from the mixture of the 
ice particles with small spaces of air. In the case of 
all transparent bodies whiteness results from such a 
mixture. The clearest glass or crystal when crushed 
becomes a white powder. The foam of champagne is 
white through the intimate admixture of a transparent 
liquid with transparent carbonic acid gas. The whitest 
paper, moreover, is composed of fibres which are in- 
dividually transparent. 

447, It is not, however, the air or the gas, but the 
optical severance of the particles, giving rise to a mul- 
titude of reflexions of the white solar light at their 
surfaces, that produces the whiteness. 

A448. The whiteness of the surface of a clean glacier 
(112), and of the icebergs of the Miargelin See (357), 
has been already referred to a similar cause. The 
surface is broken into innumerable fissures by the solar 


CLOUDS AND RIVERS, ICE AND GLACIERS. 177 


neat, the reflexion of solar light from the sides of the 
little fissures producing the observed appearance. 

449. In like manner if you freeze water in a test- 
tube by plunging it into a freezing mixture, the ice 
produced is white. For the most part also the ice 
formed in freezing machines is white. Examine such 
ice, and you will find it filled with small air-bubbles. 
When the freezing is extremely slow the crystallising 
force pushes the air effectually aside, and the result- 
ing ice is transparent; when the freezing is rapid, the 
air is entangled before it can escape, and the ice is 
translucent. But even in the case of quick freezing 
Mr. Faraday obtained transparent ice by skilfully re- 
moving the air-bubbles as fast as they appeared with 
a feather. 

450. In the case of lake ice the freezing is not uni- 
form, but intermittent. It is sometimes slow, sometimes 
rapid. When slow the air dissolved in the water is 
effectually squeezed out and forms a layer of bubbles on 
the under-surface of the ice. An act of sudden freezing 
entangles this air, and hence we find lake ice usually 
composed of layers alternately clear, and filled with 
bubbles. Such layers render it easy to detect the planes 
of freezing in lake ice. 

451. And now for the bearing of these facts. Under 
the fall of the Géant, at the base of the Taléfre cascade, 
anc lower down the Mer de Glace; in the higher re- 
gions of the Grindelwald, the Aar, the Aletsch and the 


[73 THE FORMS OF WATER IN 


Gorner glaciers, the ice does not possess the trans- 
parency which it exhibits near the ends of the glaciers. 
It is white, or whitish, Why? Examination shows 
it to be filled with small air-bubbles; and these, as we 
now learn, are the cause of its whiteness. 

452. They are the residue of the air origin en- 
tangled in the snow, and connected, as before stated, 
with the whiteness of the snow. During the descent of 
the glacier, the bubbles are gradually expelled. by the 
enormous pressures brought to bear upon the ice. Not 
only is the expulsion caused by the mechanical yielding 
of the soft thawing ice, but the liquefaction of the sub- 
stance at places of violent pressure, opening, as it does, 
fissures for the escape of the air, must play an import- 
ant part in the consolidation of the glacier. 


453. The expulsion of the bubbles 1s, however, not 


uniform; for neither ice nor any other substance offers 
an absolutely uniform resistanee to pressure. At the 
base of every cascade that we have visited, and on the 
walls of the crevasses there formed, we have noticed in- 
numerable blue streaks drawn through the white trans- 
lucent ice, and giving the whole mass the appearance 
of lamination. These blue veins turned out upon ex- 
amination to be spaces from which the air-bubbles had 
been almost wholly expelled, translucency being thus 
converted into transparency. 

454, ‘This is the veined or ribboned structwre of gla- 


giers, regarding the origin of which diverse opinions are — 


now entertained. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 4179 


455. It is now our duty to take up the problem, and 
to solve it if we can. On the névés of the Col du 
Géant, and other glaciers, we have found great cracks, 
and faults, and Bergschrunds, exposing deep sections of 
the névé; and on these sections we have found marked 
the edges of half-consolidated strata evidently produced 
by successive falls of snow. The névé is stratified be- 
cause its supply of material from the atmosphere is 
intermittent, and when we first observed the blue veins 
we were disposed to regard them as due to this stratifi- 


~ eation. 


456. But observation and reflexion soon dispelled 
this notion. Indeed it could hardly stand in the pre- 
sence of the single fact that at the bases of the ice-falls 
the veins are always vertical, or nearly so. We saw no 
way of explaining how the horizontal strata of the néve 
eould be so tilted up at the base of the fall as to be set 
onedge. Nor isthe aspect of the veins that of stratifi- 
cation. 

457. On the central portions of the cascades, more- 
over, there are no signs of the veins. At the bases 
they first appear, reaching in each case their maximum 
development a little below the base. As you and I 
stood upon the heights above the Zasenberge and scru- 
tinised the cascade of the Strahleck branch of the 
Grindelwald glacier, we could not doubt that the base 
of the fall was the birthplace of the veins. We called 
this portion of the glacier a ‘Structure Mill,’ intimating 


180 THE FORMS OF WATER IN 


that here, and not on the névé, the veined structure 
was manufactured. 


SECTION OF ICEFALL, AND GLACIER BELOW IT, SHOWING ORIGIN OF VEINED 
STRUCTURE. 


458. This, however, is, at bottom, the laneuage of 
strong opinion merely, not that of demonstration; and in 
sclence opinion ought to content us only so long as 
positive proof is unattainable. The love of repose must 
not prevent us from seeking this proof. There is no 
sterner conscience than the scientific conscience, and — 
it demands, in every possible case, the svbstitution for 
private conviction of demonstration which shall be con- 
clusive to all. 

459. Let us, for example, be shown a case in which 
the stratification of the névé is prolonged into the 
glacier ; let us see the planes of bedding and the planes 
of lamination existing side by side, and still indubitably 


CLOUDS AND RIVERS, ICE AND GLACIERS. 181 


distinct. Such an observation would effectually exclude 
stratification from the problem of the veined structure, 
and through the removal of this tempting source of 
error, we should be rendered more free to pursue the 
truth. 

460. We sought for this conclusive test upon the 
Mer de Glace, but did not find it. Wesought it on the 
Grindelwald, and the Aar glaciers,* with an equal want 
of success. On the Aletsch glacier, for the first time, 
we observed the apparent coexistence of bedding and 
structure, the one cutting the other upon the walls of 
the same crevasse. Still the case was not sufficiently pro- 
nounced to produce entire conviction, and we visited the 
Gorner glacier with the view of vate up our quest. 


SS = == ee 
——— SSS es ——= 


ji 


: ——— 


Hig eH 
pe — 


if j 


STRUCTURE AND BEDDING ON ALETSCH GLACIER. 


461. Here day after day added to the conviction that 
the bedding and the structure were two different things. 


* M. Agassiz, however, reports a case of the kind upon the glacier of the 
Aar. | 


; 


182 THE FORMS OF WATER IN 


Still day after day passed without revealing to us the 
final proof. Surely we have not let our own ease stand 
in the way of its attainment, and if we retire baffled 
we shall do so with the consciousness of having done 
our best. Yonder, however, at the base of the Mat- 
terhorn, is the Furgge glacier that we have not yet 
explored. Upon it our final attempt must be made. 

462. We get upon the glacier near its end, and 
ascend it. We are soon fronted by a barrier composed 
of three successive walls of névé, the one rising above 
the other, and each retreating behind the other. The 
bottom of each wall is separated from the top of the 
succeeding one by a ledge, on which threatening masses 
of broken névé now rest. We stand amid blocks and 
rubbish which have been evidently discharged from 
these ledges, on which other masses, ready apparently to 
tumble, are now poised. | 

463. On the vertical walls of this barrier we see, 
marked with the utmost plainness, the horizontal lines 
of stratification, while something exceedingly like the 
veined structure appears to cross the lines of bedding 
at nearly a right angle. The vertical surface is, how- 
ever weathered, and the lines of structure, if they be 
such, are indistinct. ‘The problem now is to remove the 
surface, and expose the ice underneath. It is one of 
the many cases that have come before us, where the 
value of an observation is to be balanced against the 
danger which it involves. 


CLOUDS AND RIVERS, ICE AND GLACIERS. 183 


464. We do nothing rashly; but, scanning the ledges 
and selecting a point of attack, we conclude that the 
danger is not too great to be incurred. We advance 
to the wall, remove the surface, and are rewarded by 
the discovery underneath it of the true blue veins. 
They, moreover, are vertical, while the bedding is hori- 
zontal. Bruce, as you know, was defeated in many a 
battle, but he persisted and won at last. Here, upon 
the Furgge glacier, you also have fought and won 
your little Bannockburn. 


STRUCTURE AND BEDDING ON FURGGE GLACIER. 


465. But let us not use the language of victor, too 
soon. ‘The stratification theory has been removed out 
of the field of explanation, but nothing has as yet been 
cffered in its place. 


§ 65. Relation of Structure to Pressure. 


466. This veined structure was first described by the 
distinguished Swiss naturalist, Guyot, nowa resident in 


184 THE FORMS OF WATER IN 


the United States. From the Grimsel Pass I have 
already pointed out to you the Gries glacier over- 
spreading the mountains at the opposite side of the 
valley of the Rhone. It was on this glacier that 
M. Guyot made his observation. 

467. ‘I saw,’ he said, ‘under my feet the surface of 
the entire glacier covered with regular furrows, from 
one to two inches wide, hollowed out in a half-snowy 
mass, and separated by protruding plates of harder and 
more transparent ice. It was evident that the glacier 
here was composed of two kinds of ice, one that of the 
furrows, snowy and more easily melted; the other of 
the plates, more perfect, crystalline, glassy, and resis- 
tant; and that the unequal resistance which the two 
kinds of ice presented to the atmosphere was the cause 
of the ridges. 

468. ‘ Atter having followed them for several hun- 
dred yards, I reached a crevasse twenty or thirty feet 
wide, which, as it cut the plates and furrows at right 
angles, exposed the interior of the glacier to a depth of 
thirty or forty feet, and gave a beautiful transverse 
section of the structure. As far as my eyes could reach, 
I saw the mass of the glacier composed of layers of 
snowy ice, each two of which were separated by one of 
the hard plates of which I have spoken, the whole 
forming a regularly laminated mass, which resembled 
sertain calcareous slates.’ 

469. I have not failed to point out to you upon all 


CLOUDS AND RIVERS, ICE AND GLACIERS. 185 


the glaciers that we have visited the little superficial 
furrows here described; and you have, moreover, 
noticed that in the furrows mainly is lodged the finer 
dirt which is scattered over the glacier. They sug- 
gest the passage of a rake over the ice. And when- 
ever these furrows were interrupted by a crevasse, the 
veined structure invariably revealed itself upon the 
walls of the fissure. The surface grooving is indeed 
an infallible indication of the interior lamination of 
the ice. 

470. We have tracked the structure through the 
various parts of the glaciers at which its appearance 
was most distinct; and we have paid particular atten- 
tion to the condition of the ice at these places. The 
very fact of its cutting the crevasses at right angles is 
significant. We know the mechanical origin of the 
crevasses; that they are cracks formed at right angles 
to lines of tension. But since the crevasses are also 
perpendicular to the planes of structure, these planes 
must be parallel to the lines of tension. 

471. On the glaciers, however, tension rarely occurs 
alone. At the sides of the glacier, for example, where 
marginal crevasses are formed, the tension is always 
accompanied by pressure; the one force acting at right 
angles to the other. Here, therefore, the veined 
structure, which is parallel to the lines of tension, is 
perpendicular to the lines of pressure. 7 
472. That this is so will be evident to you in a 


186 THE FORMS OF WATER IN 


moment. Let the adjacent figure represent the channel 
of the glacier moving in the direction of the arrow. 
Suppose three circles to be marked upon the ice, one at 
the centre and the two others at the sides. Ina glacier 


SSS 
SS SS 


SS 


O 
: te 

10 ta 

CMM MM Seco ZZ 


SS 
NS 


7 


of uniform inclination all these circles would move 
downward, the central one only remaining a circle. By 
the retardation of the sides the marginal circles would 
be drawn out to ovals. The two circles would be elon- 
gated in one direction, and compressed in another. 
Across the long diameter, which is the direction of 
strain, we have the marginal crevasses ; across the short 
diameter mn, which is the direction of pressure, we have 
the marginal vemed structure. 

473. This association of pressure and structure is 
invariable. At the bases of the cascades, where the 
inclination of the bed of the glacier suddenly changes, 
the pressure in many cases suffices not only to close the 
crevasses but to violently squeeze the ice. At such 
places the structure always appears, sweeping quite 
across the glacier. When two branch glaciers unite, 
their mutual thrust intensifies the pre-existing marginal 
structure of the branches, and developes new planes of 
lamination. Under the medial moraines, therefore, we 


CLOUDS AND RIVERS, ICE AND GLACIERS. 187 


have usually a good development of the structure. It 
is finely displayed, for example, under the great medial 
moraine of the glacier of the Aar. 

A474. Upon this glacier, indeed, the blue veins were 
observed independently three years after M. Guyot had 
first described them. I say independently, because M. 
Guyot’s description, though written in 1838, remained 
unprinted, and was unknown in 1841 to the observers on 
the Aar. These were M. Agassizand Professor Forbes. 
To the question of structure Professor Forbes subse- 
quently devoted much attention, and it was mainly 
his observations and reasonings that gave it the im- 
portant position now assigned to it in the phenomena 
of glaciers. 

475. Thus without quitting the glaciers themselves, we 
establish the connexion between pressure and structure. 
Is there anything in our previous scientific experience 
with which these facts may be connected? The new 
knowledge of nature must always strike its roots into 
the old, and spring from it as an organic growth. 


§ 66. Slate Cleavage and Glacier Lamination. 


476. M. Guyot threw out an exceedingly sagacious 
nint, when he compared the veined structure to the 
cleavage of slate rocks. We must learn something of 
this cleavage, for it really furnishes the key to the 
problem which now occupies us. Let us go then to the 

14 


188 THE FORMS OF WATER IN 


quarries of Bangor or Cumberland, and observe the 
quarrymen in their sheds splitting the rocks. Witha 
sharp point struck skilfully into the edge of the slate, 
they cause it to divide into thin plates, fit for roofing 
or ciphering, as the case may be. The surfaces along 
which the rock cleaves are called its planes of cleavage. 

477. All through the quarry you notice the direction 
of these planes to be perfectly constant. How is this 
laminated structure to be accounted for ? 

478. You might be disposed to consider that cleavage 
is a case of stratification or bedding; for it is true that 
in varions parts of England there are rocks which can 
be cloven into thin flags along the planes of bedding. 
But when we examine these slate rocks we verify the 
observation, first I believe made by the eminent and 
venerable Professor Sedgwick, that the planes of bed- 
ding usually run across the planes of cleavage. 

479. We have here, as you observe, a case exactly 
similar to that of glacier lamination, which we were 
at first disposed to regard as due to stratification. We 
afterwards, however, found planes of lamination crossing 
the layers of the névé, exactly as the planes of cleavage 
cross the beds of slate rocks. 

480. But the analogy extends further. Slate cleavage 
continued to be a puzzle to geologists till the late Mr. 
Daniel Sharpe made the discovery that shells and other 
fossils and bodies found in slate rocks are invariably 
Battened out in the planes of cleavage. 


CLOUDS AND RIVERS. ICE AND GLACIERS. 18? 


481. Turn into any well-arranged museum—for 

example, into the School of Mines in Jermyn Street, and 
observe the evidence there collected. Look particularly 
to the fossil trilobites taken from the slate rock. ‘They 
are in some cases squeezed to one third of their primi- 
tive thickness. Numerous other specimens show 1 
the most striking manner the flattening out of shells. 
_ 482. To the evidence adduced by Mr. Sharpe, Mr. 
Sorby added other powerful evidence, founded upon the 
microscopic examination of slate rock. Taking both 
into account, the conclusion is irresistible that such 
rocks have suffered enormous pressure at right angles 
to the planes of cleavage, exactly as the glacier has 
demonstrably suffered great pressure at right angles to 
its planes of lamination. 

483. The association of pressure and cleavage is thus 
demonstrated ; but the question arises, do they stand to 
each other in the relation of cause and effect? The 
only way of replying to this question is to combine 
artificially the conditions of nature, and see whether 
we cannot produce her results. 

484. The substance of slate rocks was ouce a piwstic 
mud, in which fossils were embedded. Let us imitate 
the action of pressure upon such mud by employing, 
insteau of it, softened white wax. Placing a ball of the 
wax between two glass plates, wetted to prevent it from 
sticking, we apply pressure and flatten out the wax. 

A485. The flattened mass is at first too soft to cleave 


190 THE FORMS OF WATER IN 


sharply; but you can see, by tearing, that it is lami- 
nated. Let us chill it withice. We find afterwards 
that no slate rock ever exhibited so fine a cleavage. 
The laminee, it need hardly be said, are perpendicular 
to the pressure. 3 

486. One cause of this lamination is that the wax is 
an aggregate of granules the surfaces of which are places 
of weak cohesion; and that by the pressure these 
eranules are squeezed flat, thus producing planes of 
weakness at right angles to the pressure. 

487. But the main cause of the cleavage I take to be 
the lateral sliding of the particles of wax over each 
other. Old attachments are thereby severed, which 
the new ones fail to make good. Thus the tangential 
sliding produces lamination, as the rails near a station 
are caused to exfoliate by the gliding of the wheel. 

488. Instead of wax we may take the slate itself, 
erind it to fine powder, add water, and thus reproduce 
the pristine mud. By the proper compression of such 
mud, in one direction, the cleavage is restored. | 

489. Call now to mind the evidences we have had 
of the power of thawing ice to yield to pressure. — 
Recollect the shortening of the Glacier du Géant, and 
the squeezing of the Glacier de Léchand, at Trélaporte. 
Such a substance, slowly acted upon by pressure, will © 
yield laterally. Its particles will slide over each other, 
the severed attachments being immediately made good 
by regelation. It will not yield uniformly, but along 


CLOUDS AND RIVERS, ICE AND GLACIERS. 1¥1 


special planes. It will also liquefy, not uniformly, but 
along special surfaces. Both the sliding and the lique- 
faction will take place principally at right angles to the 
pressure, and glacier lamination is the result. 

490. As long as it is sound the laminated glacier ice 
resists cleavage. Regelation, as I have said, makes the 
severed attachments good. But when such ice is exposed 
_to the weather the structure is revealed, and the ice 
ean then be cloven into tablets a square foot, or even a 
square yard in area. 


§ 67. Conciusion. 


491. Here, my friend, our labours close. It has 
been a true pleasure to me to have you at my side so 
long. In the sweat of our brows we have often reached 
the heights where our work lay, but you have been 
steadfast and industrious throughout, using in all pos- 
sible cases your own muscles instead of relying upon 
mine. Here and there I have stretched an arm and 
helped you to a ledge, but the work of climbing has 
been almost exclusively your own. It is thus that I 
should like to teach you all things; showing you the 
way to profitable exertion, but leaving the exertion to 
you—more anxious to bring out your manliness in the © 
presence of difficulty than to make your way smooth by 
toning difficulties down. 

492. Steadfast, prudent, without terror, though not 


192 THE FORMS OF WATER IN CLOUDS, ETC. 


at all times without awe, I have found you on rock and 
ice, and you have shown the still rarer quality of 
steadfastness in intellectual effort. As here set forth, 
our task seems plain enough, but you and I know how 
often we have had to wrangle resolutely with the facts 
to bring out their meaning. The work, however, is now 
done, and you are master of a fragment of that sure 
and certain knowledge which is founded on the faithful 
study of nature. Is it not worth the price paid for 
it? Or rather, was not the paying of the price—the 
healthful, if sometimes hard, exercise of mind and 
body, upon alp and glacier—a portion of our delight ? 

493. Here then we part. And should we not meet 
again, the memory of these days will still unite us. 
Give me your hand. Good bye. 


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INDEX. 


A 


Accurate measurements of the motions 
of glaciers, by Agassiz and Forbes, 
60-62. 

Aizgischhorn, view from the, 137%. 

Agassiz’s measurements, 60; conclu- 
sions, 107; discovery by, 150; obser- 
vations made by, 187. 

Aiguille du Dru, pyramid of, 43; cloud- 
banner of, 90. 

— des Charmoz, 43; clouds about, 99. 

— Noire, 51. 

— Verte, height of, 53. 

— du Midi, stone avalanches of, 56. | 

Air, its expansion, 24; a chilling pro- 
cess, 25; experiments illustrating, | 


25, 26. 

Aletsch glacier, 186; length of, 186; arm 
of, 137. 

Alpine ice, origin in the sun’s heat, 7. 

Ancient glaciers of England, Ireland, 
Scotland, and Wales. 150, 151. 

Architecture of snow, 29-34, 91; of lake- 
ice, 35, 169. 

Arveiron, vault of, 66; description and 
cause of, 92. 


B 


Bel Alp, description of the, 139, 149. 

eee rand, formation of the, 102, 103, 

Blue veins of glaciers, 176; whiteness of 
snow, 176; whiteness of ice, 177; 
freezing of lake-ice, 177; explanation 
of cause of whiteness of glaciers, 178; 
translucency converted irto trans- 
parency, 178; vertical veins, 179; 
structure and bedding on glaciers, 
181, 182; stratification theory, 183; 
observations, 187. 

Bodies of guides found on Glacier des 
Bossons, 57, 144, 

Bowlders, size of, 148, 149. 


Cc 


Changes of volume resulting from heat 
and cold, 118-122; illustrations of, 
119, 120; consequences from, 122; 
opiniozs of Count Rumford, 128, 124. 

Chapeau, refreshment at, 41. 

Cleavage and glacier lamination, 187; 
analogy between, 188, 189; planes 
of, 188; observation of Prof. Sedg- 
wick,188; discovery by Daniel Sharp, 
188; additional evidence of Mr. Sor- 
by, 189; association of pressure and 
cleavage established, 189; relation 
of cause and effect, 189; artificial 
conditions of Nature combined, 189, 
190. 

Clouds, their formation, 3-6; in tropical 
regions, 25; illustration of the forma- 
tion of, 26. 

Col du Géant, snows and ice-cascade of 
the, 46, 47; snow-fall on the plateau 
of, 48, 49: cracks on, 179. 


Conclusion, 191, 192. 
Condensers needed, 154. 
Conditions necessary for the production 


of natural phenomena, 99. 


Conscience, scientific, 180. 


Crevasses, 41; work among the, 52; wid- 
ening of, 54; drifting of bodies buried 
in, 57; birth of, 98; features of, 100; 
characteristic, 102; transverse, 103; 
stalactites of Alpine, 100: marginal, 
105-107; longitudinal, 109; curva- 
ture of glacier related to number of, 
110-412. 

Crystallization of metals, 29; of sugar, 
30; of saltpetre. 30; of alum, 30; of 
chalk, 30; of carbon, 30; reversal of 
the process of, 36. 


D 


De owes theory of glacier-motion, 


194 


Dilatation theory, 155, 156. 

Dirt-bands of Mer de Glace, observed 
by Prof. Forbes, 180; description and 
explanation of, 131, 182. 

Distillation, oceanic, 18; ordinary, 21. 

Dome du Goité, broken crags of, 56. 

Drifting of huts on ice, 59, 60. 

Dr. William Hopkins’s conclusions re- 
garding the obliquity of the lateral 
crevasses, 107. 


E 


Feralets, passage through the, 53. 

Electric light, dark waves of, 14. 

Equivalent points, comparison of veloci- 
ties of, 75, ‘76, 106. ~ 

Erratic blocks, 147-150. 

Evaporation, caused by the heat-rays of 
the sun, 138. 

Expansion of water, 121, 155. 

Experiments to show the heat-power of 
the dark rays, 14-19; illustrative, 22, 
23, 25, 26; Dr. Franklin’s experi- 
ment, 112. 

Extract from Bordier’s book, 157, 162. 


FE 


Faraday’s theory regarding regelation, 
171; special solidifying power ex- 
erted by substances upon their own 
molecules, 172,178; opinion of Prof. 
James Thompson, 174, 175; experi- 
ments illnstrating the subject, 174; 
quotation from Faraday, 175. 

Fog, its formation in ballrooms, 5. 

Forces, of crystallization, 30; of gravi- 
tation, 30; of Nature, 31; attractive 
and repulsive, 127. 

Freezing mixture, 120, 168. 


G 


Glacier, the source of the Rhone, 7; fed 
by mountain-snow, 7. 21; melted by 
the sun’s dark rays. 13; terminal mo- 
raines of, 388; questions regarding 
motions of, 54-58; action of the ends 
of, 58; motion at top and bottom of, 
80,81; lateral compression of, 81, 82; 
longitudinal compression of, 84, 85; 
slow movement in winter of, 87; 
motion of Grindelwald, 94; motion 
of Great Aletsch, 94; motion of Mor- 
teratsch, 95; crevasses at the side of, 


106: action, 146, 147; ice, 155; veined | 
| Ice-river through the vale of Hasli. 146. 


or ribboned structure of, 178; blue 
veins of, 176; tables, 113, 114; mills, 
116-118; theory of Scheuchzer re- 
garding, 155; ancient, 145-147; im- 
purities thrust out by. 144; white- 
ness of a clean, 438, 176; measure- 


INDEX. 


ments by Hugi and Agassiz of, 59, 
60; epoch, 152-167. 

Glacier des Bois, description of, 38-43. 

ar Bossons, 56; mass of ice upon, 

—— of Aletsch, sand-cones of, 116. 

-— des Périades, 51. 

--— du Taléfre, boundary of, 53; width 
of, 82; chasms of the, 98. 

—— de Léechaud, motion of, 80; width of, 
82; compression of, 190. 

— du Géant, névé ot the, 49; motion of, 
79; width of, 2; cracks above the 
ice-falls of, 99; honey-combing of, 
115; shortening of, 190. 

— Unteraar, movement of, 61; appear- 
ance of Prof. Forbes on, 161; meas- 
urements by Agassiz on, 162. 

—— Gdormer, sand-cones of, 116; descrip- 
tion of, 140-144; moraines of, 143; 
advance and retreat of, 144; objects 
of interest on, 144; structure and 
bedding on, 181. 

Grand Plateau, crevasse on, 57, 118. 

Greenland’s icy mountains, 21. 

Growth of knowledge, 59. 

Guesses in science, 74. 


H 


Harmony of life and its conditions, 125. 
Heat, waves of, 12; invisible, 14; office 
of the invisible waves of, 36; ab- 
sorption of solar, 100; demanded for 
pee liquefaction of ice, 134; latent, 
Hoar-frost, 5,6; not melted by light- 
waves, 13, 18. . 
HOtel des Neuchatelois, movements of, 


60. 
—— at Riffelberg, 141. 
I 


Ice, structure of. 35.36, 119: towers of, 
104; sea, 132-134; retreat of. 145: 
development in the Alps of, 150: 
freezing of pieces of, 164; liquefac- 
tion by pressure of, 168, 169: trans- 
lucent, 177; difference between hard 
and soft, 87. ; 

Icebergs, of arctic seas. 123: described 
by Sir Leopold McClintock, 133, 134 : 
drifting of, 134: origin of, 134; of 
Switzerland, 136-138; colors of, 138; 
formation of chains of, 165. 

Ice-lens, concentration of sun’s rays by 
means of, 37. 


Icicles, 99; how produced, 100; a theory 
| of, 100-102. 
| Imagination, scientific use of. 34. 
| Impurities thrust ont by glaciers, 144. 
' Infinite Wisdom, designs of, 124. 


INDEX. 


J 


Jardin, description of, 53. 
Junegtrau, 136, 137. 


K 


Killarney, luxuriant vegetation of, 27, 
ca ie 


L 


La Grande Jorasse, crests of, 43; roses 
of cloud about, 90. 

Lake of Geneva, an expansion of the 
river Rhone, 6. 

Latent heat, 153, i167. 

Lateral moraines, origin of, 54. 

Light, wave-theory oi, 10, 11; inference 
from the phenomena of, 11; length 
of wave of, 12. 

Likeness of glacier-motion to river-mo- 
tion, 72-76. 

Liquefaction of ice, 168, 169; experi- 
ment by Mr. Bottomley, 170; experi- 
ment by Mr. Boussingauit, 170, 171. 

agi of the point of swiftest motion, 


Longitudinal crevasses, how formed, 
109; examples of, 110. 


M 


Magillicuddy’s Reeks, 27, 150, 151. 
Magnet, poles of, 32; repelling corners 
and ends of. 126. a 
Margelin See, 138; icebergs in the, 138. 
Marginal crevasses, explanation of, 106- 
109. 
Mauvais Pas, 41. : 
Measurements of glaciers by Hugi anc 
Agassiz, 59, 60. 
Medial moraines. how accounted for, 55. 
Mer de Glace. 41; its sources, 43-45: view 
of the, 44: branching of ihe, 45; me- 
dial moraines of the, 51, 52; triangu- 
lation of, 62: motion of, 66, 70; daily 
motion of, 67; unequal motion of the 
- two sides of, 70-72; motion of axes 
of. 78: summer condition of, 87; 
winter on, 88-92; dirt-bands of, 127; 
dimensions of, 145: winter motion 
of, 93; greater number of crevasses 
on eastern side of, 112; glacier ta- 
bles of, 113: grand moulin of, 117, 
118: approximate weight of, 154. 
Molecules, of water, 31, 34; expansion 
of, 125; forces acting upon. 127; ex- 
clusiveness of water. 132, 133. 
Montanvert, auberge of the, 41, 48; 
appearance in winter, 89. : 
Moraine, lateral, 41; medial moraines 
of the Mer de Glace, 51, 112: cedars 
of Lebanon growing on ancient, 150; 


195 


explanation of the cause of ridges 
on, F12; $43. 

Morteratsch glacier, cause of the widen- 
ing of tbe medial moraine of, 97 ; mo- 
tion of, 95, 96; sand-cones of, 116. 

Motion, of Mer de Glace, 93; of Grindel- 
wald, $4; of Great Aletsch glacier, 
94; of Morteratsch glacier, 95; sand- 
cones of, 116. 

Moulins, description of, 116; dangers 
from, 117; sounding of, 118. 

Mountain condensers, 27, 150. 


tion of the, 179. 
O 


Obliquity of the lateral crevasses, 167; 
illustration, 107, 108. 


N 
Névé, explanation of term, 49; stratifica- 
| P 
Petit Plateau, 56. 
Piz Bernina, route to, 95. 
_ Place de la Concorde of Nature, 16. 
Plastic theory, 156; advocated by Bor- 
dier, 157; advocated by Rendu, 158. 
| Poles, atomic, 82, 126; attractive and re- 
pellent, 30. 
| Pontresina, village of, 95. 
Precious siones. examples of crystalliz- 
/ ing power, 380. 
| Precipitation. 23. 25; atmospheric, 27. 
| Promontory of Trélaporte, 44; of Tacul, 


51. 

Proofs of glacier-motions, 58. 

Pyramid of Aiguille du Drn, 48; of 
Aiguille des Charmoz, 48. 


Q 


, Quotation fyom Rendn, 158 


R 


Rain, its source, 3; tropical, 23, 25. 

Rainfali, observations on amount of, 28. 

Regulation, theory, 163-167; observations 
‘made by Mr. Faraday, 164; forma- 
tion of chain of icebergs by, 165; 
cause of, 167; Faraday’s view of, 
171-176. 

Relation of structure to pressure, 183; 
veined structure described by Guyct, 
183-185; illustration, 186; connection 
established, 187. : 

| Retina, how excited, 8; theory of Sir 

Isaac Newton, 9. 
Riffelberg Hotel, location of, 144. 

) Rivers, their sources, 1, 7, 19. 


196 


S 


Sand-cones, 116. 

Scientific facts, connection of, 72. 

Siedelhorn, view from the summit of, 
146. 

Snow, its conversion into ice, 156; con- 
solidation in Alpine regions, 166; 
line, 49; its formation in Russian 
ballrooms, 5; in subterranean sta- 
bles, 5, 14; in polar revions, 21; its 
architecture, 29-82, 34, 91; absorbs 
solar heat, 100. 

Solidifying power of camphor and met- 
als, 173 

Source of the Severn, 2; the Thames, 
2; the Danube, 2; the Rhine, 2; the 
Rhone, 2; the Ganges, 2; the Eu- 
phrates, 2; the Garonne, 2; the Elbe, 
2; the Missouri, 2; the Amazon, 2; 
Albula, 2; the Arveiron, 38; the 
Aar, 59. 

Stalactites of Alpine crevasses, 100. 

Steam, its condensation. 3, 4. 

Sunbeames, office of, 19-21. 

Sun, its heat the source of Alpine ice, 7: 
vibratory motion of the aioms of 
the, 11; position of, 19; indtrect 
heat of the, 23. 

Switzerland, ancient glaciers of, 145-147. 


ft 


Theodolite, description of, 68; use of, 
64, 65. 

Theory. of Dilatation, 155; developed by 
De Charpentier, 156; sliding, 156; 


INDEX. 


plastic, 156-160; viscous, 161-163: 
regulation, 163-167; of glacial epoch, 
155-167. 
Trade-winds, 20. 
ee crevasses, formation of, 104, 
Trélaporte, promontory of, 44: motion 
oF the water through the narrows of, 
(oe 
iG 


Universe, order of the, 82. 


Vv 


Valley, of Hash, 146, 147; Black, 151. 

Vapor, in the atmosphere, 5. 

Viscous theory, advocated by Prof. 
erage 161; rejected by M. Agass.z, 


WwW 


Water, changes of volume of, 118-122; 
maximum density of, 120; effects of 
expansion of, 121; not a solitary ex- 
ception to general law, 124; mo- 
lecular expansion of, 125-127; tem- 
perature necessary to freeze the sea, 
152; special solidifying power of, 
173; freezing-point of, 168. 

Waves, of light, 8-11, 127; length of, 12; 
of heat, 12. 

Whiteness of a clean glacier, 48, 176; of 
Margelin Sce, 138, 176; of snow, 176; 
of FER formed in freezing mixtures, 

ree 


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