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INTERNATIONAL FORESTRY EXHIBITION.

WORKS ON FOREST SCIENCE.

By tar REV. J. C. BROWN, LL.D.
0
EvinpurcH: OLIVER & BOYD.

Lonpon : SIMPKIN, MARSHALL, & CO., anv W. RIDER & SON.
MontTREAL : DAWSON, BROTHERS.

v4
v

I.—Introduction to the Study of Modern Forest-
Economy. Price 5s.

In this there are brought under consideration the exten-
sive destruction of forests which has taken place in Europe
and elsewhere, with notices of disastrous consequences
which have followed—diminished supply of timber and
firewood, droughts, floods, landslips, and sand-drifts—and
notices of the appliances of Modern Forest Science success-
fully to counteract these evils by conservation, planting, and
improved exploitation, under scientific administration and
management.

Extract From Prerace.—‘ At a meeting held on the 28th of March
last year (1883), presided over by the Marquis of Lothian, while the
assemblage was representative of all interests—scientific, practical, and
professional—it was resolved :—‘‘That it is expedient in the interests
of torestry, and to promote a movement for the establishment of a
National School of Forestry in Scotland, as well as with a view of
furthering and stimulating a greater improvement in the scientific
management of woods in Scotland and the sister countries which has
manifested itself during recent years, that there should be held in Edin-
burgh, during 1884, and at such season of the year as may be arranged,
an International Exhibition of forest products and other objects of
interest connected with forestry.” It was then moved, seconded, and
agreed :—‘‘ That this meeting pledges itself to give its hearty co-opera-
tion and patronage to the promotion of an International Forestry Exhibi-
tion in Edinburgh in 1884; and those present resolve to give their best
efforts and endeavours to render the Exhibition a success, and of such
importance and general interest as to make it worthy of the name of
International.” ;

‘It isin accordance with this resolution, and in discharge of obligations
which it imposed, that this volume has been prepared.’

2

Il.—The Forests of England; and the Management of
them in Bye-gone Times. Price 6s.

Ancient forests, chases, parks, warrens, and woods, are
described ; details are given of destructive treatment to
which they have been subjected, and of legislation and
literature relating to them previous to the present
century.

Extract From PREFACcE.—‘ Contrast with this [the paucity of works
in English on Forest Science], the richness of Continental languages in
literature on such subjects. I have had sent to me lately O/versight of
Svenska Skogsliteraturen, Bibliograsiska Studieren of Axel Cnattingius, a
list of many books and papers on Forest Science published in Sweden ;
I have also had sent to me a work by Don José Jordana y Morera,
Ingenero de Montes, under the title of Apuntes Bibliographico Forestale,
a catalogue raisonné of 1126 printed books, MSS., &c., in Spanish, on
subjects connected with Forest Science.

‘Tam at present preparing for the press a report on measures adopted
in France, Germany, Hungary, and elsewhere, to arrest and utilise drift-
sand by planting them with grasses and trees ; and in Der Huropaeische
Flug-sand und Seine Cultur, von Josef Wessely General Domaenen-
Inspecktor, und Forst-Academie-Direktor, published in Vienna in 1873,
I find a list of upwards of 100 books and papers on that one department
of the subject, of which 30, in Hungarian, Latin, and German, were
published in Hungary alone.

‘ According to the statement of one gentleman, to whom application
was made by a representative of the Government at the Cape, for infor-
mation in regard to what suitable works on Forest Economy could be
procured from Germany, the works on Forst- Wissenchaft, Forest Science,
and Forst-Wirthchaft, Forest Economy, in the German language may be
reckoned by cartloads. From what I know of the abundance of works
in German, on subjects connected with Forestry, I am not surprised
that such a report should have been given. And with the works in
German may be reckoned the works in French.

‘In Hermann Schmidt's Fach Katalogue, published in Prague last
year (1876), there were given the titles, &c., of German works in Forst und
Jagd-Literatur, published from 1870 to 1875 inclusive, to the 3lst of
Gctober of the latter year, amounting in all to 650, exclusive of others
given in an appendix, containing a selection of the works published
ae to 1870. They are classified thus :—General Forest Economy, 93;

orest Botany, 60 ; Forest History and Statistics, 50 ; Forest Legislation
and Game Laws, 56; Forest Mathematics, 25; Forest Tables and
Measurements, &., 148; Forest Technology, 6; Forest Zoology, 19;
Peat and Bog Treatment, 14; Forest Calendars, 6; Forest and Game
Periodicals, 27 ; Forest Union and Year Books, 13; Game, 91; Forest
aud Game in Bohemian, 44. In all, 652. Upwards of a hundred new
works had been published annually. Amongst the works mentioned is
avolume entitled Die Literatur der letaten sieben Jahre (1862-1872) aus

3

dem Gesammétgebiete der Land-und Forst-wirthschaft mit Hinschluss der
landw. Geweber u. der Jagd, in deutscher, franzisischer u englisher
Sprache Herausg. v. d. Buchandl, v. Gerold and Co., in Wein, 1873, «
valuable catalogue filling 278 pages in large octavo.

‘ This volume is published as a small contribution to the literature of
Britain, on subjects pertaining to Forest Science.

‘It is after due consideration that the form given to the work— that
of a compilation of what has been stated in works previously published
—has been adopted.

III.—Forestry of Norway. Price 5s.

There are described in successive chapters the general
features of the country. Details are given of the geo-
graphical distribution of forest trees, followed by discussions
of conditions by which this has been determined—heat,
moisture, soil, and exposure. The effects of glacial action
on the contour of the country are noticed, with accounts
of existing glaciers atid snow-fields. And information is
supplied in regard to forest exploitation and the transport
of timber, in regard to the export timber trade, to public
instruction in sylviculture, and to forest administration,
and to ship-building and shipping.

EXTRACT FROM PREFACE.—‘In the spring of 1877, while measures
were being taken for the formation of an Arboretum in Edinburgh, I
issued a pamplet entitled The Schools of Forestry in Hurope: a Plea
for the Creation of a School of Forestry in connection with the Arboretum
in Edinburgh. After it was made known that arrangements were being
carried out for the formation of an International Exhibition of forest
products, and other objects of interest connected with forestry, in Edin-
burgh with a view to promoting the movement for the establishment
of a National School of Forestry in Scotland, and with a view of
furthering and stimulating a greater improvement in the scientific
management of woods in Scotland, and the sister countries, which has
manifested itself during recent years, the council of the East Lothian
Naturalists’ Club resolved on having a course of lectures or popular
readings on some subject connected with forestry, which might enable
the members and others better to profit by visits to the projected Exhibi-
tion, and which should be open to the public ata moderate charge, The
conducting of these was devolved upon me, who happened to be vice-
president of the club. The following treatise was compiled from
information then in my possession, or within my reach, and it constituted
the basis of these lectures.’

4

IV.—Finland: its Forests and Forest Management.
Price 6s 6d.

In this volume is supplied information in regard to
the lakes and rivers of Finland, known as The Land of a
Thousand Lakes, and as The Last-born Daughter of the
Sea ; in regard to its physical geography, including notices
of the contour of the country, its geological formations
and indications of glacial action, its flora, fauna, and
climate; and in regard to its forest economy, embracing a
discussion of the advantages and disadvantages of
Svedjande, the Sartage of France, and the Koomaree of
India; and details of the development of Modern Forest
Economy in Finland, with notices of its School of Fores-
try, of its forests and forest trees, of the disposal of its
forest products, and of its legislation and literature in
forestry are given.

Extract From PREFAcE.—‘I happened to spend the summer of 1879
in St. Petersburg, ministering in the British and American Chapel in
that city, while the pastor sought: relaxation for a few months at home.
I was for years the minister of the congregation worshipping there, and
T had subsequently repeatedly spent the summer among them in similar
circumstances. I was at the time studying the Forestry of Europe ;
and I availed myself of opportunities afforded by my journey thither
through Norway, Sweden, and Finland, by my stay in Russia, and by
my return through Germany and France, to collect information bearing
upon the enquiries in which I was engaged. On my return to Scotland
T contributed to the Journal of Forestry a series of papers which were
afterwards reprinted under the title Glances at the Morests of Northern
Europe. In the preface to this pamphlet I stated that in Denmark
may be studied the remains of forests in pre-historic times ; in Norway,
luxuriant forests managed by each proprietor as seemeth goodin his own
eyes; in Sweden, sustained systematic endeavours to regulate the
management of forests in accordance with the ‘latest deliverances of
modern science; in Finland, Sartage disappearing before the most
advanced forest economy of the day; and in Russia, Jardinage in the
north, merging into more scientific management in Central Russia, and
Réboisement in the south. This volume is a study of information which
I then collected, together with information which I previously possessed,
z isve subsequently obtained, in regard to the Forests and Forestry of

‘inland.

Translation of Extracts from Letters from Dr A. Buomgvist, Director
of the Finnish National School of Forestry at Evois :—‘On my return
from Salmos three weeks ago I had the great pleasure to receive your
volume on the Forests and Forest Management in Finland. I return

5

you grateful thanks for the gift, and no less for publishing a description
of the forestal condition of our country. It is with sentiments of true
gratitude I learn that you had previously taken part in a work so
important to our country as the preparation of a new edition of the New
Testament in Finnish. Your descriptions of our natural scenery are
most excellent and interesting. Personally I feel most interest in your
accounts of Koomaree. I value it much, and not less so your concurrent
final conclusion in regard to the effects of the exercise of it in Finland.’

Translation of Statement by M, De La Gry, in the Revue des
Eaux et Férets of January 1884 :—‘In an address delivered some weeks
since at a banquet of exhibitors in the French section at Amsterdam,
M. Herisson, Minister of Commerce, expressed an intention to publish
a series of small books designed to make koown to French merchants
foreign lands in a commercial point of view. If the Minister of Commerce
wishes to show to our merchants the resources possessed by Finland, he
need not go far to seek information which may be useful to them, they
will be found in « small volume which has just been published by Mr
John Croumbie Brown.

‘ Mr Brown is one of those English ministers, who, travelling over the
world in all directions [some at their own cost], seeking to spread the
Word of the Lord in the form of Bibles translated into all languages,
know how to utilise the leisure left to them at times while prosecuting
this mission. Some occupy themselves with physical science, others with
archeology, some with philology, many with commerce ;, Mr Brown has
made a special study of sylviculture. He has already published on this
subject many works, from amongst which we may cite these : Hydrology
of South Africa; The Forests of England ; The Schools of Forestry in
Europe ; Réboisement in France; Pine Plantations on Sand Wastes in
France,

‘His last book on Finland is the fruit of many journeys made in that
country, which he visited for the first time in 1833, but whither he has
returned frequently since that time. Mr Brown gives narratives of his
voyages on the lakes which abound in Finland, and his excursions in the
immense forests, the exploitation of which constitutes the principal
industry of the country. The School of Forestry at Evois has furnished
to him much precise information in regard to the organisation of the
service, and the legislation and the statistics of forests, which, added
to what he had procured by his own observation, has enabled him to
make a very complete study of this country, poetically designated The
Land of a Thousand Lakes, and which might also justly be called The
Kingdom of the Forest, for there this reigns sovereign.’

V.—Forest Lands and Forestry of Northern Russia.
Price 6s 6d.

Details are given of a trip from St. Petersburg to

the forests. around Petrozavodsk on Lake Onega, in

the government of Olonetz; a description of the forests

6

on that government by Mr Judrae, a forest official of
high position, and of the forests of Archangel by Mr
Hepworth Dixon, of Lapland, of the land of the Samoides
and of Nova Zembla; of the exploitation of the forests
by Jurdinage, and of the evils of such exploitation; and
of the export timber trade, and disposal of forest products.
Tn connection with discussions of the physical geography
of the region information is supplied in regard to the
contour and general appearance of the country ; its flora,
its forests, and the palaeontological botany of the regions
beyond, as viewed by Professor Heer and Count Saporta ;
its fauna, with notices of game, and with copious lists of
coleoptera and lepidoptera, by Forst-Meister Gunther, of
Petrozavodsk.

Exrract rrom Prerace.—‘In the spring of 1877 I published a
brochure entitled The Schools of Forestry in Europe: a Flea for the Crea-
tion of a School of Forestry in connection with the Arboretum in Edin-
burgh, in which with details of the arrangements made for instruction in
Forest Science in Schools of Forestry in Prussia, Saxony, Hanover,
Hesse, Darmstadt, Wurtemburg, Bavaria, Austria, Poland, Russia,
Finland, Sweden, France, Italy, and in Spain, and details of arrange-
ments existing in Edioburgh for instruction in most of the subjects in-
cluded amongst preliminary studies, I submitted for consideration the
opinion, ‘‘ that with the acquisition of this Arboretum, and with the ex-
isting arrangements for study in the University of Edinburgh, and in
the Watt Institution and School of Arts, there are required only facil’ -
ties for the study of what is known on the Continent as Forest Science
to enable these Institutions conjointly, or auy one of them, with the
help of the other, to take a place amongst the most completely equipped
Schools of Forestry in Europe, and to undertake the training of furesters
for the discharge of such duties as are now required of them in India, in
our Colonies, and at home.”

‘This year has seen world-wide arrangements for an International
Exhibition of forest products and other objects of interest connected
with forestry in Edinburgh, *‘In the interests of forestry, and to pre-
mote a movement for the establishment of a School of Forestry in Scot-
land, as well as with a view of furthering and stimulating a greater im-
provement in the scientific management of woods in Scotland and the
sister countries which has manifested itself during recent years.”

‘ The following is one of a series of volumes published with a view to
introduce into English forestal literature detailed information on some
of the points on which informatiou is supplied to students at Schools of
Forestry on the Continent; and to make better known the breadth of

study which is embraced in what is known there as Forstwissenscaft, ov
Forest Science.’

t

VI.—French Forest Ordinance of 1669 ; with Historical
Sketch of Previous Treatment of Forests in France.
Price 4s.

The early history of forests in France is given, with de-
tails of devastations of these going on in the first half of
the seventeenth century ; with a translation of the Ordi-
nance of 1669, which is the basis of modern forest econo-
my; and notices of forest exploitation in Jardinage, in La
Methode & Tire et Aire, and in La Methode des Comparti-
ments.

Extract rrom Prerace.—‘ “The Celebrated Forest Ordinance of
1669 :” Such is the character and designation generally given at the
present day to the Ordinance in question. It is known, by reputation
at least, in every country on the Continent of Europe ; but, so far as is
known to me, it has never before been published in English dress. It
may possibly be considered antiquated ; but, on its first promulgation, it
was welcomed, far beyond the bounds of France, as bringing life to the
dead ; and I know of no modern system of Forest Exploitation, based on
modern Forest Science, in which I cannot trace its influence. In the
most advanced of these—that for which we are indebted to Hartig and
Cotta of Saxony—I see a development of it like to the development of
the butterfly from what may be seen in the structure vf the chrysalis ;
and thus am I encouraged to hope that it may prove suggestive of bene-
ficial arrangements, even where it does-not detail what it may be deemed
desirable to adopt.

‘In my translation I have followed an edition issued with Royal ap-
proval in 1753, with one verbal alteration to bring it into accordance
with certain older approved editions, and with another verbal alteration
to bring it into accordance with editions issued in 1699, 1723, 1734, and

1747.’

Translation of notice by M. DE La Grrz for July 1883 in the Revue
des Haux et Férets: ‘ Mngland, which with her immense possessions in
India, in Canada, and in the Cape of Good Hope, is beyond all question
a State rich in forests, has never up to the present time given to this
portion of her domains more than a very moderate share of her attention ;
but for some years past public opinion is becoming alarmed, in view of
the immense devastations which have been committed in them, and the
forest question coming forward spontaneously has hecome the subject of
numerous publications : amongst which, after the excellent monthly
collection, the Journal of Forestry and Hstate Management, comes the
Translation of the Ordinance of 1669, which has just been published by
Mr John Croumbie Brown. This translation of a monument of juris-
prudence, well known in France, but which has never before been repro-
duced in English, has furnished to Mr Brown an opportunity of giving a
historical sketch of French Forest Legislation, and an exposition of the

8

different methods of exploitation followed in our country. Drawn from
the best sources, and commented on with talent, these documents form
an elegant volume, which the author has made the more complete by
binding with it a summary of the treatise he has published on the
Forests of England.’

VII. —Pine Plantations ou Sand Wastes in France.
Price 7s.

In this are detailed the appearances presented by the
Landes of the Gironde before and after culture, and the
Landes of La Solugne; the legislation and literature of
France in regard to the planting of the Landes with trees ;
the characteristics of the sand wastes; the natural his-
tory, culture, and exploitation of the maritime pine, and
of the Scots fir; and the diseases and injurious influences
to which the maritime pine is subject.

Extracts FRoM Prerace.—‘ The preparation of this volume for the
press was undertaken in consequence of a statement in the Standard and
Mail, a Capetown paper, of the 22d July 1876, to the effect that in the
estimates submitted to Parliament £1000 had been put down for the
Cape Flats, it was supposed with a view to its being employed in car-
rying out planting operations as a means of reclaiming the sandy tracts
beyond Salt River. *

‘This volume was originally compiled in view of what seemed to he
required at the Cape of Good Hope, It has been revised and printed
now, as a contribution towards a renewed enterprise to arrest and
utilise eand-wastes which stretch from Table Mountain to the Hottentot
Holland Mountains; and additional information is forthcoming if it
should be desired.’

VIII.—Reboisement in France; or, Records of the Re-
planting of the Alps, the Cevennes, and the
Pyrenees, with Trees, Herbage, and Bush,
with a view to arresting and preventing the de-
structive consequences of torrents. Price 12s.

In this are given a résume of Surell’s study of Alpine
torrents, of the literature of France relative to Alpine tor-
rents, and of remedial measures which have been proposed
for adoption to prevent the disastrous consequences fol-

9

lowing from them—translations of documents and enact-
ments, showing what legislative and executive measures
have been taken by the Government of France in connec-
tion with réboisement as a remedial application against
destructive torrents—and details in regard to the past,
present, and prospective aspects of the work.

Extract From Prerace.—‘ In a treatise on the Hydrology of South
Africa I have given details of destructive effects of torrential floods at
the Cape of Good Hope and Natal, and referred to the measures adopted
in France to prevent the occurrence of similar disastrous floods there.
The attention of the Legislative Assembly at the Cape of Good Hope
was,’ last year, called by one of the members of the Assembly to the
importance of planting trees on unproductive Crown lands. On learn-
ing that this had been done I addressed to the editor of the Cape Argus
a communication, of which the following is a copy :—

‘“T have before me details of destructive effects of torrents which have
occurred since I left the Colony in the beginning of 1867. Towards the
close of that year there occurred one, the damage occasioned by which
to roads and to house property at Port Elizabeth alone was estimated at
from £25,000 to £30,000, Within a year thereafter a similar destructive
torrent occurred at Natal, in regard to which it was stated that the
damage done to public works alone was estimated at £50,000, while the
loss to private persous was estimated variously from £50,000 to £100,000.
In the following year, 1869, a torrent in the Western Province occa-
sioned the fall of a railway bridge, which issued in loss of life and loss
of property, and personal injuries, for one case alone of which the rail-
way proprietors were prosecuted for damages amounting to £5000. In
Beaufort West a deluge of rain washed down the dam, and the next
year the town was flooded by the waters of the Gamko ; and the next
year, 1871, Victoria West was visited with a similar disaster. Such are
the sums and the damages with which we have to deal in connection
with this question, as it affects the case; and these are only the most
remarkable torrents of the several years referred to. I have spoken of
millions of francs being spent on réboisement in France, and some may
be ready to ery out, ‘ Nothing like such an expenditure can be under-
taken at the Cape!’ Perhaps not; but the losses occasioned by the
torrents seem to amount at present to about a million of francs in the
year. This falls in a great measure on individuals, that would fall on
the community ; and the community in return would benefit by water
retained to fertilize the earth, instead of being lost in the sea, and by
firewood and timber being grown where now there is none. These are
facts well deserving of consideration in the discussion of the expediency
of planting Crown lands with trees,”

© Towards the close of last year, 1874, still more disastrous effects
were produced by torrential floods. According to the report given by
one of the Colonial newspapers, the damages done could not be esti-
mated at much less than £300,000. According to the report given by

10

another, the damage done to public works alone was estimated at
£350,000,—eight millions, seven hundred and fifty thousand francs. And
my attention was called anew to the subject.

‘On addressing myself to M. Faré, Director-General of the Administra-
tion of Forests in France, there was afforded to me every facility I could
desire for extending and verifying the information I had previously col-
lected in regard to the works of réboisement to which I have referred.
Copies of additional documents were supplied to me, with copies of
works sanctioned by the Administration, and arrangements were made
for my visiting and inspecting, with every assistance required, the works
begun and the works completed ; and thus I have been enabled to sub-
mit a much more complete report than it would otherwise have been in
my power to produce,

‘While the compilation I have prepared owes its publication at this
time to the occurrence of the inundations of last year at the Cape of
Good Hope, the publication has been undertaken in the hope that ia
other countries besides South Africa the information may be turned to
practical account.’

Translation of extract from letter to the author by M. ALEXANDRE
SURELL, Ingenieur des Ponts et Chausses, chairman of the Compagnie des
Chemins des Fer du Midi et du Canal lateral & la Garonne, and author of
Etude sur les Torrents des Hautes-Alps, Ouvrage Couronne par ? Academie
des Sciences en 1842 :—‘ You are rendering an eminent service to society
in calling the attention of serious thinkers to the subject of réboisements
and gazonnements. It is a vital question affecting our descendants,
specially in southern climates, there are useful truths which have to be
diffused there, and you have fulfilled this duty amongst your country-
men.

‘In France public opinion, Jong indifferent, is now sufficiently en-
lightened on the question, and much has been done.

‘I have been able to establish in the course of a recent journey
that, throughout a great part of Switzerland, in Styria, in Carinthia,
and in the Tyrol, the same phenomena which have issued in the desola-
tion of our French Alps are beginning to produce the same effects.
There have been recognised a number of extinct torrents which had
originated in the destruction of the forests. If people go on sleeping,
and the administration or the communes do nothing to arrest the evil,
posterity will have a sad inheritance devolved upon it.

‘You have given, with very great clearness, a résumé of what I have
done in Fyance, be it by my works, or be it by my workings, for the re-
generation of our mountains.’

‘Translation of extract from letter by the late M. Ernest Cézanne, Jn-
genieur des Ponts et Chausses, Représentant des Hautes Alpes al Assemblée
Nationale, and author of Une Suite to the work of M. Surell. ‘The
post brought to me yesterday your very interesting volume on Rébdoise-
ment, Lat once betook myself to the perusal of it ; and I am surprised
that a foreigner could digest so completely such a collection of our
French documents drawn from so many diverse sources, The problem

i

of réboisement and the regeneration of the mountains is ove of the most in-
teresting which man has to solve, but it requires time and money, and
with the authorities and political assemblies, technical kuowledge which
is as yet but very sparingly possessed. It is by books so substantial as
yours, sir, that public opinion can be prepared to face the importance
of this great work.’

IX.—Uydrology of South Africa; or Details of the
Former Hydrographic Condition of Cape of Good
Hope, and of Causes of its Present Aridity, with
Suggestions of Appropriate Remedies for this
Aridity. Price 10s.

In this the desiccation of South Africa, from pre-Adamic
times to the present day, is traced by indications supplied
by geological formations, by the physical geography or the
general contour of the country, and by arborescent pro-
ductions in the interior, with results confirmatory of the
opinion that the appropriate remedies are irrigation,
arboriculture, and an.improved forest economy: or the
erection of dams to prevent the escape of a portion of
the rainfall to the sea—the abandonment or restriction of
the burning of the herbage and bush in connection with
pastoral and agricultural operations —the conservation and
extension of existing forests —and the adoption of measures
similar to the réboisemené and gazonnement carried out in
France, with a view.to prevent the formation of torrents,
and the destruction of property occasioned by them.

M. Jules Clavé, of world-wide reputation as a student
of Forest Science, wrote in the Revue des Deux Mondes of
Ist May 1882 :-—

[Translated.] ‘Since the first travels of Livingstone, the African
continent, hitherto inacessible, has been attacked on all points at once.
By the north, and by the south, by the east, and by the west, hardy
explorers have penetrated it, traversed it, and have dragged from it
some of its secrets. ‘Travellers have paid tribute and done their work
in opening up a path; it is now for science and civilisation to do theirs,”
in studying the problems which present themselves for investigation ; ’
and in drawing in the current of general circulations the peoples and
lands, which appear as if destined to stand outside; and in causing to

12

contribute to the increase of social wealth the elements of production
previously unknown. Thus are we led to receive with interest works
which can throw a new light on the condition of regions which may
have been known for a long time, and which make known the conditions
oftheir prosperity. It is under this title that the work of the Rev. J. C.
Brown on the Hydrology of South Africa appears deserving of notice ;
but it is so also from other points of view. Mr Brown, after a previous
residence in the colony of the Cape, whither he had been sent in 1844
as a missionary and head of a religious congregatioa, returned thither
iu 1833 as Professor of Botany in the College of South Africa, and he
remained there some years. In both of these positions he had occasion to
travel through the colony in all directions, and had opportunities to col-
lect most valuable information in regard to its physical geography. Mr
Brown on going out to the Cape knew nothing of the works which had
for their object to determine the influence of forests on the climate, ou
the quantity of rain, and on the river-courses in Europe; he had never
heard mention of the work of M. Surell on the torrents of the Alps, or
of that of M. Mathieu on forest meteorology, nor of those of M.
Domontzey, Costa de Bastelica, and so many others on the subject of
réboisement ; and yet in studying by himself, and without bias, the
climatic condition of South Africa, he came to perceive that the dis-
turbances in the regularity of the flow of rivers within the historic
period should be attributed in a large measure to the destruction of
forests ; and he meets in agreement on this point the savants whose
names have been mentioned. We have thought it might not be with-
out interest to readers of the Revue to lave in the lines of Mr Brown a
collection of phenomena which, in their manifestation at any speci-
fied point-are not less due to general causes, the effects of which
may be to make themselves felt everywhere where there may be
existent the same conditions than to aught else.’ And there follows a
lengthened article in illustration.

X.—Water Supply of South Africa, and Facilities for
the Storage of it. Price 18s 6d.

In this volume are detailed meteorological observations
on the humidity of the air and the rainfail, on clouds, and
winds, and thunder-storms; sources from which is derived
the supply of moisture which is at present available for
agricultural operations in the Colony of the Cape of Good
Hope and regions beyond, embracing the atmosphere, the
rainfall, rivers, fountains, subterranean streams and reser-
voirs, and the sea; and the supply of water and facilities
for the storage of it in each of the divisions of the colony

138

—in Basutoland, in the Orange River Free State, in
Griqualand West, in the Transvaal Territory, in Zululand,
at Natal, and in the Transkei Tertitory.

Exrract From Prerace.—‘ Appended to the Report of the Colonial
Botanist at the Cape of Good Hope for 1866 was an abstract of a Memoir
prepared on the Hydrology of South Africa, which has since been
embodied in a volume which has been published on that subject, and an
abstract of a Memoir prepared on Irrigation and its application to
agricultural operations in South Africa, which emlraced a Report on
the Water Supply of the Colony ; its sources, its qnantity, the modes of
irrigation required in different circumstances, the facilities for the adop-
tion of these in different districts, and the difficulties, physical and
other, in the way of works of extensive irrigation being carried out
there, and the means of accomplishing these which are at command.

‘In the following volume is embodied that portion of the Memoir
which related to the water supply, and the existing facilities for the
storage of this, with reports relative to this which were subsequently
received, and similar information in regard to lands beyond the Colony
of the Cape of Good Hope, which it has been sought to connect with the
Colony by federation, or otherwise ; and the information relative to
irrigation has been transferred to a Report on the Rivers of the Colony,
and the means of controlling floods, of preventing inundations, of
regulating the flow of rivers, and utilising the water by irrigation
‘otherwise. --

‘In the series of volumes to which this belongs its place is immedi-
ately after that on the Hydrology of South Africa, which contains
details of the former hydrographic condition of the Cape of Good Hope,
and of causes of its present aridity, with suggestions of appropriate
remedies for this aridity; and it has been prepared to show that, not
in a vague and general use of the terms, but in strict accordance with
the statement, the severe, protracted, and extensive droughts, and
destructive floods and inundations, recorded in the former volume, find
their counterpart in constantly alternating droughts and deluges in
every district of the Colony,—and that, in every so-called division of it,
notwithstanding the deluges, there were protracted sufferings from
drought, and, notwithstanding the aridity, there is a supply of water
at command, with existing facilities for the storage of the superabundant
supply which at present proves productive of more evil than good.’

Statement by Reviewer in Huropean Mail :-—‘ Dr Brown is well known
at the Cape, for in the exercise of his duties he travelled over the prin-
cipal part of it, and much, if not indeed the substance, of the bulky
volume before us, has been before the Cape public in the form of Reports
to the local Government. As these reports have been commented upon
over and over again by the local press there is little left for us to say
beyond the fact that the author reiterates his opinion that the only
panacea for the drought is to erech dams and other irrigation works for
the storage of water when the rains come down. There can be no doubt

14

that this is sage and wholesome advice, and the only question is, who
is to sustaia the expense? Not lovg ago, somewhere about the time
that Dr Brown was prosecuting his labours, it will be remembered that
General Wynard said that ‘‘ Nature had furnished the cups if only
science would take the trouble to make them secare.” It is but to
repeat an oft-told story that with a good supply of water South Africa
would be one of the finest of nature’s gardens, and would be capable of
producing two crops a year, in addition to furnishing fodder for sheep
and cattle. The question of the water supply for irrigation and other
purposes has been staved off year after year, and nothing has been done.
It is not too much to say, however, that the question must make itself
felt, as it is one of the chief factors in the ultimate prosperity of South
Africa. The author is evidently ia love with his subject, and has con-
tributed a mags of facts to Hydrology which will be useful to all coun-
tries of an arid character.’ =

|
XI.—Forests and Moisture; or Effects of Forests on

Humidity of Climate. Price 10s.

In this are given details of phenomena of vegetation on
which the meteorological effects of forests affecting the
humidity of climate depend—of the effects of forests on
tbe humidity of the atmosphere, and on the humidity of the’
ground, on marshes, on the moisture of a wide expanse of
country, on the local rainfall, and on rivers—and of the
correspondence between the distribution of the rainfall and
of forests—the measure of correspondence between the
distribution of the rainfall and that of forests—the distri-
bution of the rainfall dependent on geographical position,
or determined by the contour of a country—the distribution
of forests affected by the distribution of the rainfall—and
the local effects of forests on the distribution of the rain-
fall within the forest district.

Extracts rroM Preracre.—‘ This volume is one of a series. In the
first of the series—a volume entitled—published last year, Hydrology
of South Africa ; or, Details of the Former Hydrographic Condition of
the Cape of Good Hope and of Causes of its recent Aridity, with Sugges-
tions of appropriate Remedies for this Aridity,

‘This volume, on the effects of forests on the humidity of the atmos-
phere and the ground, follows supplying illustrations of the reasonable-
ness of the suggestion made'in regard to the conservation and extension

of forests as a subordinate means of arresting and counteracting the
deseccation and aridity of the country.’

15

Extracts FRoM LETTERS to the author from the late Hon. George P.
Marsh, Minister of the United states at Rome, and author of The
Larth as Modified by Human Action :—‘I am extremely obliged to you
for a copy of your Réboisement in France, just received by post. I hope
the work may have a wide circulation. . . . Few things are more
needed in the economy of our time than the judicious administration of
the forest, and your very valuable writings cannot fail to excite a
powerful influence in the right direction. ae

‘I have received your interesting letter of the 5th inst., with the
valuable SS. which accompanied it. I will make excerpts from the
latter, and return it to you soon.. I hope the very important facts you
mention concerning the effect of plantations on the island of Ascension
will be duly verified.

. . . ‘I put very little faith in old meteorological observations,
and, for that matter, not much in new. So much depends on local
circumstances, on the position of instruments, &c,—on station, in short,
that it is only on the principle of the tendency of some to balance each
other that we can trust to the registers of observers not known to be
trained to scientific accuracy. Even in observatories of repute, meteoro-
logical instruments are seldom properly hung and guarded from dis-
turbing causes. Beyond all, the observations on the absorption of heat
and vapour at small distances from the ground show that thermometers
are almost always hung too high to be of any value as indicating the
temperature of the stratum of the atmosphere in which men live and
plants grow, and in most tables, particularly old ones, we have no
information as to whether the thermometer was hung five feet or fifty
feet from the ground, or whether it was in any way protected from heat
radiated from near objects.’

Extract Lerrer from the late Professor Henry, of the Smithsonian
Institution, Washington :—‘The subject of Forest Culture and its in-
fluence on rainfall is, just at this time, attracting much attention in the
United States. At the last meeting of the American Association for the
advancement of science a committee was appointed to memorialise Con-
gress with reference to it. Several of the Western States Governments
have enacted laws and offered premiums in regard toit. The United
States Agricultural Department has collected statistics bearing on the
question, and we have referred your letter to that establishment.

‘Tne only contribution that the Smithsonian Institution has made to
the subject is that of a series of rain-fall tables, comprising all the obser-
vations that have been made in regard to the rainfail in the United
States since the settlement of the country ; a copy of this we have sent
to your address.

“Tt may be proper to state that we have commenced a new epoch,
and have, since the publication of the tables in question, distributed
several hundred rain gauges in addition to those previously used, and to
those which have been provided by the Government ia connection with
the signal service.’ : : ;

These notices and remarks are cited as indicative of the importance
which is being attached to the subject discussed.

16

Extract rrom Lrrrer to the author from Lient.-Col. J. Campbell
Walker, Conservator of Forests, Madras, then Conservator-in-Chief of
Forests, New Zealand; author of Report on State Forests and Forest
Management in Germany and Austria:—‘I am in receipt of yours,
along with the notices of your works on Forestry, by book post.
I think very highly of the scope of the works, and feel sure that they
and similar works will supply a want much felt by the Indian forest
officers.

‘It contains many important data which I should have vainly sought
elsewhere, and it will be regarded by all competent judges as a real
substantial contribution to a knowledge of the existing surface, and the
changes which, from known or unknown causes, that surface is fast
undergoing.’

Copies of any of these Works will be sent post-paid to
any address within direct Postal communication with
Britain, on receipt by Dr Jonny C. Brown, Haddington,
of a.Post-Office Order for the price..

FORESTS AND MOISTURE:

OR

EFFECTS OF FORESTS ON HUMIDITY OF CLIMATE.

By same Author.

Narrative of an Exploratory Tour to the Northeast of the Colony
of Cape of Good Hope, by the Revs. T. Arbousset and F, Daumas, of
the Paris Missionary Society. (A Translation.)

Hydrology of South Africa ; or Details of the former Hydrographic
condition of the Cape of Good Hope, and of causes of its present
Aridity, with suggestions of appropriate remedies for this Aridity.

Reboisement in France ; or Records of the replanting of the Alps,
the Cevennes, and the Pyrenees with trees, herbage, and bush, with
a view to arresting and preventing the destructive consequences and
effects of torrents.

In the Press, and speedily will be Published,

Water Supply of South Africa: its sources, its quantity, the diff-
culties (physical and other) in the way of works of extensive irrigation
-being carried out at the Cape, and the means of accomplishing these
which are at commund, with notices of what has been done in con-
nection with the storage of water and irrigation in other lands,

FORESTS AND MOISTURE;

OR

EFFECTS OF FORESTS

ON

HUMIDITY OF CLIMATE.

COMPILED BY
JOHN CROUMBIE BROWN, LL.D.,

Formerly Government Botanist at the Cape of Good Hope and Professor
of Botany in the South African College, Capetown, Fellow of the
Royal Geographical Society, Fellow of the Linnean Society, and
Honorary Vice-President of the African Institute of Paris, ete.

EDINBURGH:
OLIVER AND BOYD, TWEEDDALE COURT.
LONDON: SIMPKIN, MARSHALL AND CO,
L877.

KirxcaLpy : Jonn CRAWFORD, PRINTER.

[All rights of Translation.and Reproduction are reserved.)

CONTENTS AND ARGUMENT.

Inprx to AUTHORITIES CITED,

PREFACE,
States circumstances in which the volume is published.

InrRopUcTIoN, - - - - ;

States subjects to be discussed as being more particularly the effect of

forests on the humidity of the climate, including the rainfall ; but

treating this only as accessary to other effects, and these such as

may be produced by every blade of herbage according to its
measure,

PART I.—PHENOMENA OF VEGETATION ON WHICH THE METEOR-
OLOGIOAL EFFECTS OF FORESTS AFFECTING THE HuMIDITY
or CLIMATE DEPEND,

Cuarter I1.—Primary Phenomena of Vegetation,

Primary phenomena of vegetation are expounded as seen in the Red
Snow, the Yeast plant, Conferve, and Algs (p. 3), ‘and thus is
illustrated the absorption of moisture by endosmose (p. 5), which
process is more fully detailed (p. 6). The Jiquid absorbed is traced
from the rootlets to the leaves (p. 10); the rise of the sap is ex-
plained in accordance with the supposition of its being attributable
to endosmosic action (p. 12). The differeace between this and
capillary attraction is explained (p. 13), and the difference between
this and what is called vis @ tergo (p. 15). The structure of the
leaf is described (p. 17), and the process of the evaporation of the
moisture by the stomates of the leaves is illustrated (p. 19).

PAGE,

xi

xiii

vi CONTENTS.

Cuapter II.—On the Quantity of Moisture Evaporated through
the Stomates of the Leaves,

Facts il'ustrative of the quantity of moisture evaporated through the
stomates of leaves are cited from Marsh and others, embracing
observations on the oak by Marshal Vaillant (p. 21), and on the
maple and the birch in America (p. 22).

CuarTer III.—Disputed and Secondary Phenomena of Vege-
tation,

Section I.—On the Absorption of Moisture by Leaves,

It is alleged that there isa lack of evidence of moisture being absorbed
by leaves in great quantity (p. 25).

Section Il.—On the Production of Water by Plants,

A reference is made to quantities of water found in the Kaffir iron-
wood (p. 26), the pitcher plant and the teazle (p. 27), to water
secreted by ants (p. 28) and by the cuckoo-spit (p. 29); and it is
intimated that it is not unreasonable to suppose that water may be
secreted by vegetables (p. 31).

Szotion III.—On the Dropping of Water from the Leaves of

certain Trees, -

Reference is made to observations on a cel2brated laurel in Fervo
(p. 31), and it is suggested that the dropping -of water from its
leaves may be attributable to a copious deposit of dew (p, 32), and
this is again referred to in explanation of similar phenomena ob-
served in Madeira (p. 35) and in Europe (p, 37).

PART II.—Errects or Forests oN tHE Hummpity oF THE
CLIMATE, - as

Cuapter l—Immediate Effects of Forests on the Humidity of
the Atmosphere, :

Reference is made to controverted views on this subject, and these are
discussed (p. 38),

Szction L—On the Humidity of Atmosphere in the vicinity of
Trees, indicated by the dampness of houses overshadowed
by Trees, or situated in close proximity to a Wood, -

This is attributed to the moisture evaporated through the stomates of
the leaves being absorbed or retained by the walls (p. 39).

Sgction I—On Clouds occasionally seen surmounting Woods
while the Atmosphere around is comparatively clear,

There is discussed a statement by Marsh in favour of the popular
view that mountains attract clouds (p, 46); and phenomena seen

21

bd
oO

26

31

38

38

39

40

CONTENTS. vil

on Table Mountain, at the Cape of Geod Hope, are adduced to
show that these, like the alleged attraction of clouds by forests, are
attiibutable to a reduction in the temperature of the air (p. 48).

Cuapter Il —EF fects of Forests on the Humidity of the Ground, 51

Section L—On the Wetness of Roads where these are over-
shadowed by Trees, - 51

While the profuse evaporation from the trees through the stomates
of the leaves is nct overlooked, the wetness of roads is traced to the
effect of the shadow occasioned by the trees preventing evaporation
from the overshadowed portion cf the road (p. 51); in illustration
of which effect of shade are adduced experiments and observations
made at the Cape cf Good Hope (p. 52), and observations on the
eff-ct of shade on ponds in England (p. 55).

Section IL—On the Desiceation of Ground by Drying Winds
being prevented by the Shelter afforded by clumps of Trees, 55
Illustrations are given of the effect of shelter in arresting evapora-
tiop, and of the extent to which even bash may ac’ as a wind-
brake (p. 56>.

Secrion I1L—On the General Phenomena of Evaporation from
Forests, 57

There are given indications of evaporation being retarded by forests

(p. 59), observations on the quantity of rain arrested by leaves

made by Marshall Vaillant (p. 61) and by M. Mathieu (p. 62),

observations by the latter on the different quantities of water

evaporated in woods and in adjacent open land (p. 63), and notices

of corresponding observations made by Risler (p. 64), with the con-

clusion from the whole that under the same measure of rainfall the

soil of the forest retains notably more water than does uncovered

ground (p. 65).

Szction IV.—On the Moisture being attracted from the Atmos-
phere, or otherwise retained in the Ground by Vegetable
Mould, - - 65

Ik is stated how it may be seen that there is a greater quantity of
moisture in the soil of a forest than in the soil of open country
(p. 65); illustrations are given of the process whereby such mois-
ture is absorbed (p. 65); the difference between this and the
deposit of dew is pointed out (p. 66); the property is stated to be
possessed in a high degree by clay and by vegetable mould (p. 67);
the latter is shown to be a product of forests, and a mode of deter-
mining the quantity of it in the soil is described (p. 70), and the
humus is shown to be liable to decomposition when exposed to the
rays of sun, unshaded by herbage and trees (p. 71).

_ wilt CONTENTS.
73

Cuaprer III.—Z fects of Forests on Marshes,

Section I.—On the Drying-up of Marshes on the Growth of ;
- - 7

Trees,
It is stated that what is evaporated through the stomates of the

leaves is derived from the ground (p. 73). and that the quantity
often exceeds many times that of the rainfall (p. 74); that to a great
extent what the atmosphere thus gains the earh loses (p 79); and
an illustration of the effect in drying up wet ground is given (p. 80).

Srcrion IL.—On the occcasional appearance of Marshes on the
81

destruction of Forests, -
Cases of the appearance of marshes on the destruction of forests are

cited, which are attributed to the interruption of the withdrawal
of excess of moisture from the soil by the trees (p. 81).

Szorion II].—On the occasional Destruction of Forests by the
83

Creation of Marshes, -
The destruction of forests by marshes is attributed to the damming-up
of water outlets at a lower level (p. 83), and illustrative cases are

given from Russia (p, 83), Canada (p. 85), and the United States
of America (p. 88).

Section IV.—Ox the Desiccating Effects produced on Marshes
90

by Forests in prolonged periods,

The gradual conversion of marshes into habitable and arable land is
discussed (p. 90), and Ireland and Denmark are referred to in

illustration (p. 91).

Cuapter IV.—On the Effects of Forests on the Moisture of a

wide expanse of Country, =

Szorion I.—Cases in which the extensive destruction of Forests
does not appear to have perceptibly affected the quantity of
the Rainfall over a wide expanse of Country,

The difference between moisture and rainfall is pointed out (p. 94);
and illustrations of little eff ct having been produced on the quantity
of rain falling over a wide expanse of country having been produced
by an extensive destruction of forests are given from France (p. 95),
and from the United States of North America (p. 98),

Szcrion II.—Cases in which the extensive destruction of Forests
appears to have been followed by a marked desiccation of
Land and aridity of Climate, -

It is stated that the extensive destruction of grass and herbage and
trees in South Africa has been followed by drought (p 104); and
there are cited statements in regard to corresponding observations

93>

94

99

elsewhere by Marsh (p. 106); by Hooker (p. 108); by Schleiden
and Fries (p. 108); Fraas(p. 109) ; Beequerel (p. 110); Laurent,
&. (p. 111); Humboldt (p. 112); Boussingault (p. 113); and
Hough (p. 115).

Secrion ILl.—Cases in which the Destruction of Trees have been
followed by desiccation; and the planting of Trees has been
followed by the restoration of humidity, 117

St. Helena (p. 117) and the Mauritius (p. 124) are adduced as cases
in which the destruction of trees has been followed by desiccation ;
and the replanting of trees with restoration of humidity. The
Island of Ascension is brought forward as a case in which the
absence of trees was accompanied by aridity, and the planting of
trees was followed by humidity (p. 128); the measures adopted are
detailed (p. 134); and the successfal resuits are reported (p. 141).

Section 1V.—Cases ilustrative of Effects of Forests on
Humidity corresponding to such as have been adduced, 144
Accounts are given of climatal changes on the Island of Madeira
(p. 144); and reference is made to alleged changes in Alexandria
and in Egypt “p. 146; South Africa (p. 148); South America, &c.
(p. 149).

Cuarter V.—Local Effects of Forests on the Rainfall and on
Rivers, - - 150

Section 1.—On the production of Rain, 151 —

The production of rain is traced to the deposit of moisture in excess
of what can be retained at a reduced temperature by air by which
it had been absorbed ; and in view of this there is detailed the rise
of the Trade Winds (p. 151), the course of currents of air from
the polar to the equatorial regions, and their return thither deposit-
ing moisture absorbed while proceeding toward the equator (p. 152).
Reference is made to the quantity which must have been so absorbed
(p. 153). The production of clouds by eddies and whirlwinds is
described (p. 156); and the production of rain as detailed by Sir
John Herschel (p. 158)

Secrion Il.—The Effects of Forests on the quantity of the Local
Rainfall, - - - 159
There are brought forward the views of Boussingault and Becquerel
that forests increase the local rainfall (p. 159). Observations by
Mr Draper are again brought forward, but with them an illustration
of the effect of forests by Coultas (p. 160); and statements of the
views of Marsh and the observations of Mathien in accordance with
the views of Boussingault (p. 161); with remarke on the same by
M. Cézanne (p. 162).

x OONTENTS.

Szction IIl.—Zffects of Forests and of the Destruction of

Forests on Rivers and Streams, 165

Cases are cited from America North and South (p, 166), from France
(p. 167), from Germany and from the Cape of Good Hope (p. 172);
illustrative of the flow of streams and rivers varying with the exist-
ence and destruction of forests. A resumé is given of a treatise by
Herr Wex on the diminution of water in springs and rivers, with
augmentation of floods (p. 175); with reports on the same by the
Academy of Science of Vienna (p. 199), and by the Academy of
Science of St. Petersburg (p. 203); and a resumé of observations
reported by Dr Ernst Ebermayer (p. 204).

Szotion IV.—Immediate Effects of Trees in Arresting the Flow

and Escape of Rainfall, 212
There are cited objections to the views of M. Becquerel in regard to

the effects of trees advanced by Marshal Vaillant (p. 212); but
with these, observations reported by M. Coute-Grand Champs, and
M. d’Arboise de Jubainiville (p. 214), by Mr Marsh and by M. Jules
Clave (p. 216), showiog that trees have the effect of arresting the
flow and escape of the raintall; observations by Mr Marschand on
the increased hydroscopicity, capillarity, and permeability of soil
oceasioned by the growth of trees (p. 217); and additional
illustrations of the same supplied by Cézanne (p. 221), by
d’Hericourt, and by Marsh (p. 223).

Section V.—Secondary Effects of Trees in Arresting the Flow
and Escape of the Rainfall, and thus Equalising to some
extent the Flow of Rivers, 225

The secondary effects of trees in arresting the flow and escape of the
rainfall, and thus equalising to some extent the flow of rivers, are
illustrated by reference to the effect of floods in washing away
earth, and sometimes covering fertile land with infertile earth, in
connection with which are cited statements by Marsh in regard to
these effects (p. 226); and statements by Surell in regard to the
prevention of them by the growth of trees (p. 237) ; statements by
Cézanne in regard to natural arrest of torrents by forests (p. 242) ;
and by Costa de Bastelica on the effect of trees in increasing the
humidity of the soll and consequent drainage of water to subter-
ranean reservoirs (p, 244); of Marchand on the occasion of storms
in the Alps (p. 249); with a historical narration of the application
of rebotsement to arrest and prevent the effects of such storms
(p. 251).

Cuarter VI.—On the correspondence between the distribution of
the Rainfall and of Forests, - - 255
There is stated the course to be followed in this discussion (p. 255).

CUNTENTS. xi

Section L—On the Measure of Correspondence between the
Distribution of the Raivrall and that of Forests, 256
bis is iastrated from statements by Dr Bzandis in regard to India
(p. 256). by Mir Maclaren in regard to America (p. 259). by a ecm-
parison of repcrt on the rainfall in North America, issued by the
Sm:ibsonian Ins-itation (p. 2<!;. with the account of the forests
of North America given by M. Marny (p. 26); and a statement
in regard to the destruction of forests in Soath Africa (9. 26),

Section IL.—On the Distribution of the Rainjall dependent on
Geozriphical Position, bein7 determined by the Contour of
a Country, - 271
An illustration of the distribution of the rainfall bzing affected by the
altituie of a country is given in the effects of s wini-wave which
passed over Europe in September 1266 (p. 2721; with an iltastra-
tion of the same operation in ihe prodaction of a “ mackerel sky” ;
and of the Table Cloth on Tab'e Mountain (p. 273). Which are
followed by an exposition by Cézanne of Lis doctrine that it is
determined in a great measure by the rapidi-y with which the
atm spheric current rises (p. 274); and iliastrations of this being
the case supplied 5; Ranlin (p. 200).
Section IL.—On the Distribution of Forests Aifected by the
Distribution of the Rainfall, 283
There :s cited a statement by Marsh relative to a tendency manifested
by ligneous vegetables to secure the universal occupancy of land
(p. 283). Tke operation of laws regulating the dispersion of
vegetables is illustrated (p. 2:¢.: and the operation of thcse on the
dispersion of trees is seen to depend in part upon the rainfall
(p. 289).
Sgcrion IV.—On the Local Evrects of Forests on the Distrvbu-
tion of the Rainjgall within the Fsrest District, 293
The general effect of forests is shown to be to retard the flow of the
rain-water precipitated (293), and so in prehistoric times to have
converted torrents into peaceful streams (294), while the sare effect
is shown to be produced by them still (p. 295). There are cited
observations addaced to prove that apparently they inflaence some-
what the quant'rr of the rainfall and the local distribut‘on of it over
the year (p. 299); and the reconciliation of conflicting observations
and opinions (p. 302) is shown to be possible (p. 303).

CoNcLtsion, - - 307

INDEX TO AUTHORITIES CITED,

0

Academy of Science of St. Petersburg, 203. Academy of Science
of Vienna, 199, 299,

Baines, 69. Balfour,4. Barnard, 129, Barrington, 128. Becquerel, 110, 212.
Belgrand, 294. Bell, 137. Berghaus, 176, 180, 194. Blanqui, 120, 148.
Bloget, 301. lore, 52, Boussingault, 113, 148, 159. Brandis, 256.
Breton, 248. Brown, 142. Bryand, 150, Burnet, 129.

Cantegril, 174. Cézanne, 21, 59, 65, 68, 94, 147, 157, 162, 221, 242, 274,
293, 303, 805. Chapman, 26. Chouseul-Graffier, 213. Clavé, 216,
Chavery, 215, Conte-Grandchamps, 214, Costa de Bastelica, 244, 251.
Cotle, 96. Coultas, 160.

D'Arboise de Jubainville, 214. Dallinger, 18. D’Hericourt, 223,
Draper, 100, 111, 160. Drysdale, 18. Duponchel, 232. Dutrochet, 6.

Ebermayer, 204. Emerson, 23. Emsman, 117. Espy, 304.

Faber, 236. Fraas, 109. Fries, 108. Frisi, 231.

Gosse, 25. Graham, 35, 145. Gras, 248. Gray, 5,9, 59. Grebanau, 177, 184.
Guglielmini, 231.

Hagen, 177, 178,183, Hales, 15. Hayes, 155. Henry, 98, 115, 262. Her-
schel, 32, 34, 49, 158, 282, 303. Home, 56, 145. Harker, 108, 112, 128,
Hough, 100, 148. Humboldt, 34. Hummel, 169. Huxley, 18,

Irving, 154. Jamieson, 300, Janisch, 118, Job, 10. Johnstone, 37, 55.
Johnstrus, 225,

Kieser, 4.

Labuissiere, 295. Laurent, 111. Lemoine, 221. Lenneps, 32. Leslie,
41,43. Livingstone, 28. Lombardini, 233.

Maas, 177,179. Max Graham, 113. Maclaren, 159. Macvicar, 71. Marschand,
167, 217,249. Mardigny, 232, Marny, 264. Marsh, 21, 22, 45, 46, 57,
64, 74, 88, 90, 106, 115, 125, 144, 148, 161, 167, 171, 216, 223, 226, 288.
Mathieu, 62, 64, 161. Maury, 156. Meguscher, 38, Meldrum, 134.
Mitchell, 43. Moffat, 104, 173. Mohl, 19,

Orlebar, 55.

Perrot, 192. Pfaff, 21,25. Piper, 169. Playfair, 124.

Renou, 302. Rogers, 126. Raulin, 95, 97, 279.

St. John, 127. Saussure, 34. Scheubler, 92. Schleiden, 21, 25. Scoresby,
153. Shott, 100. Siemni, 169. Steinmitz, 152. Surell, 174, 230, 237.
Symons, 300. :

Tennant, 30. Thomas, 164. Thomson, 272, Thornton, 124. Thurmann, 67.

Vaillant, 21, 61, 75, 212, Valles, 252. Van Reenan, 172. Vampell, 90, 291.

Wells, 82. Wex, 175. Williams, 23, Wiseman, 204, Wisner, 175.

PREFACE

Tus volume is one of a series. In the first of the series—a
volume published last year, entitled “ Hydrology of South Africa ,
or, Details of the former Hydrographic condition of the Cape of
Good Hope, and of causes of its present Aridity, with suggestions
of appropriate remedies for this Aridity,”’—it is stated that the
desiccation of the country is attributable, primarily and mainly to the
upheaval of the land and the consequent rapid draining off of the
water with which it was covered and of the subsequent rainfall;
and secondarily, to rapid evaporation occasioned by the temperature
and latterly promoted by the destruction of forests and herbage
and grass. There are adduced facts and testimony indicative of
this having been the case; and in view of these the appropriate
remedies for the prevailing aridity are stated to be—the erection of
dams to prevent the escape of a portion of the rainfall to the
sea,—the abandonment or restriction of the burning of the veldt,
—the conservation and extension of existing forests,—and the
adoption of measures similar to the reboisement and gazonnement
carried out in France, with a view to prevent the formation of
torrents and destruction of property occasioned by them.

There is now in the press, and shortly will be published, a
continuation of that volume on the “ Hydrology of South Africa,”
supplying illustrations of the practicability of applying the first of
these remedies being a report on the water supply of South Africa:
its sources, iis quantity, the difficulties (physical and other) in the
way of works of extensive irrigation being carried out at the Cape,
and the means of accomplishing these which are at command, with
notices of what has been done in connection with the storage of
water and irrigation in other lands.

xiv PREFACE.

This volume, on the effects of forests on the humidity of the
atmosphere and of the ground, follows in the series, supplying
illustrations of the reasonableness of the suggestion made in regard
to the conservation and extension of forests, as a subordinate
means of arresting and counteracting the desiccation and aridity
of the country. :

And early in the present year was published a volume entitled
“ Reboisement in France: or, Records of the replanting of the.
Alps, the Cévennes, and the Pyrenees with trees, herbage, and. -
bush, with a view to arresting and preventing the destructive
consequence and effects of torrents.” ;

Should encouragement: offer, the publication of this volume will,
be followed by the publication of a volume on the effects of
forests on-the temperature of a country, and the correlation -of,
humidity and temperature in. meteorological phenomena ; a volume
on ‘the chemistry of vegetation, and the effects thereby produced
on the salubrity of a climate; and a compilation of official docu-
ments, showing what arguments for the conservati on and exten-
sion of forests have been submitted to the consideration” of
legislative and scientific bodies in different countries, in view of
the meteorological effects of forests,—and what measures have been
adopted in-view of these to secure more extensively for the benefit
of mau the meteorolggical benefits which may be thus produced.

Happineton, December 1876.

EFFECTS OF FURESTS

ON THE

BUMIDITY OF THE CLIMATE

INTRODUCTION.

Tue following treatise on Meteorological Effects of Forests relates
mainly to the effects of these on the humidity of the atmosphere and
of the soil. Besides these there are effects produced by forests on the
temperature and the salubrity of a country, and all of these are cor-
related—each of them affecting the others, and the others, each.

It is a matter of common observation that houses in the close
proximity of trees are often damp; it is also frequently observed that
both in summer and winter the temperature in a wood is different
from what it is in the open country ; and it is becoming generally
known that vegetation so affects the constitution of the atmosphere
as to keep the air fit for the support of man and beast. Phenomena
connected with each of these effects, and different phases of these,
will incidentally come under our notice ; and their correlation may be
attended to; but the discussion of these does nut come within the
scope of this treatise.

No effects are attributed by me to forests which are not produced,
or might not be produced, by any and every blade of herbage or of
grass according to its measure. The difference is considered to be only
a question of degree. As the hue of a single hair, or a thread of spun
glass, may be imperceptible to many observers to whom the hue of a
mass of the same hair or glass may be apparent at once, so the
meteorological effect of a tiny leaf or a tiny moss, scarcely percep-
tible by a hurried glance, or those of a-single tree, may be inappre-
ciable because infinitesimally small, but the effects produced by a
forest with its ccuntless trees, boughs, and leaves be most manifest ;
and then, with these effects known, we may with advantage proceed

2 INTRODUCTION,

to the closer study of any one of them, or of phenomena connected
with them in such of the less complicated vegetable structures as
supply facilities for the study of these phenomena free from compli-
cations which are met with in such masses of vegetation as are met
with in forests; and by reasoning from the lesser to the greater, as
well as from the greater to the less, we may attain to what are at
once clearer and more comprehensive views of the truth on the
subject. This is what I propose to do in the sequel.

To prevent misapprehension I may call attention to the circum-
stance that in treating of humidity it isnot the rainfall alone of which
I speak. I attribute not a little of the prevalent popular opinions in
regard to the effects of forests, and controversies in regard to these to
the difference between these being overlooked.

PAK TL

PHENOMENA OF VEGETATION ON WHICH METEOROLOGICAL EFFECTS
or Forests DEPEND.

Cuap. I.—Protary PHexowens oF VEGETATION.

Tue study of the phenomena of vegetation, on which meteorological
effects of forests depend, may advantageously be begun by the con-
sideration of what takes place in some of the more simple forms of
vegetables.

The simplest form of vegetable appears to be what is called Red
Snow. In Alpine and Arctie regions, there are occasionally seen on
the rock or on the snow patches of red-coloured matter, not unlike
dust. When this matter is examined microscopically it is found that
each particle of the dust-like substance is a small cell, or bladder-like
body ; it is not a crystal; it does not appear to be an animal; it
seems to be a plant—and a plant of simpler structure it would be
difficult to conceive. It is known to botanists as the Protococcus
Nivalis,

A plant similar to this, but somewhat more complex in structure
—if the term complex can be employed with propriety in speaking
of a structure so very simple—is seen in the Yeast Plant.

With a stick or a spoon there may be drawn from yeast in active
fermentation thread-like bodies which, when examined microscopi-
cally, appear like a string of beads, each bead being a cell, not unlike
the Red Snow in structure, but colourless. This is the Yeast Plant,
and if the thread be broken each cell may be developed into a thread-
like plant similar to that from which it has been dissevered.

In Conferve, and in many confervoid plants found in streams and
fresh water pools, we find a similar structure, but this is enclosed in
an investing skin, and the cells are drawn out from a globular into a
more or less elongated cylindrical form. And in the larger Alga, or
sea weeds—some of which there are which are 1000 feet in length—
when they are examined microscopically we find, and find only, a
mass of such cells less regularly arranged, enclosed in an investing
skin of similar cellular structure.

4 CELLULAR GROWTH.

The growth of all such bodies—as it is of many others, but it is of
these I speak at present—is effected by the multiplication of the cells
of which they are composed. The process of cell growth and cell
production has been studied in numerous structures, both vegetable
and animal, with similar results ; and it may be described in general
terms thus :—In many cells, when examined microscopically, there
may be seen at one place a thickening of the cell wall; in some may
be seen, in the cell contents, floating bodies, two, four, or more in
number, from which there is being developed a fine transparent
membrane, with an appearance like that presented by the glass on a
watch ; this gradually expands and is distended with liquid, until, in
process of time, the mother cell is ruptured by their distension, and
they continue to expand as independent cells, giving birth to others,
and in like manner giving place to these in their turn.

It is not necessary to my present purpose that I should discuss the
question of how this process is originated and maintained. It is with
the process and what follows from it with which I have to do. To
prevent misapprehension, I may state that I do not know of the process
having been in any case observed continuously from its commence-
ment to its completion ; but different cells have been seen and studied
‘n all the stages of growth and reproduction to which I have referred.

The increase of bulk in each cell may be too minute and too slow to
be noted, but with the process going on simultaneously in a long line
of cells the effect may be perceived. I have seen the extremity of a
conferva, held fast at the other end, advance across the field of vision
in a microscope with which I was examining it. Nor will this be
astounding if it be considered with what rapidity the process of cell
production, growth, and reproduction must sometimes go on. Large
tracts of snow in Arctic regions, and in Alpine districts, are some-
times quite suddenly reddened by the production of the Red Snow
plant, to which reference has been made, the consequence of the
development of innumerable cells. One form of fungus, the Phallus
umpudiens, has been observed to shoot up three inches in the space
of twenty-five minutes. Another, Bovista Gigantea, the giant puffball,
‘‘has grown,” says Balfour, “in a single night in damp weather from
the size of a mere point to that of an enormous gourd. From an
approximate calculation it is found that in this plant not less than
20,000 new cells are formed every minute. Kieser estimated that
the tissue of some fungi augmented at the rate of 60,000 cells
per minute,”

In South Africa I have frequently observed a marked difference in

ABSORPTION. 5

the altitude of the flowering stem of the American Aloe, Agave
Americana, as1 returned to my home in the evening from what it had
been in the morning as I passed on my way to Capetown. Dr Asa
Gray, writing on the cell increase in this gigantic peduncle, says,—
“ After waiting many years, or even for a century, to gather strength
and materials for the effort, Century Plants which grow in our con-
servatories send up a flowering stalk which grows, day after day, at
the rate of a foot in twenty-four hours, and becomes about six inches
in diameter. This, supposing the cells to average 1-300th of an inch

in diameter, requires the formation of over twenty thousand millions
of cells in a day!”

It is by such cell production, development, and multiplication
that the growth of all plants, from the Snow Plant to the monarch of
the wood, is effected ; nor is it without consideration that I make use
of the term multiplication in speaking of the increase of their number,
for it is the case that it is by such metrical progression that the
increase is effected. Not only may each cell be studied as in itself a
complete organism, an integer, and consequently an integral part of
the more comprehensive structure into which it enters—as a man is
in himself complete, an integer, and, consequently, an integral part of
the nation to which he belongs, and as such may be made the subject
of study apart from the other men of whom, along with him, the
nation is composed,—but, in the Red Snow, we have a single cell
constituting a complete plant; and in this we may study more
conveniently some of the phenomena of vegetation on which some of
the alleged meteorological effects of forests depend as consequences.

The absorption of moisture appears to be an invariable concomitant
of cell growth and, consequently, of cell development and cell
increase. We may afterwards enquire what function the moisture
fulfils in the vegetable economy, at present it is only the fact and the
mode of its accomplishment which are brought under consideration.

A cell is too minute for ocular demonstration of the mode of
absorption of moisture through the cell wall to be given by it.
The cells vary in different plants, from about the thirtieth to the
thousandth of an inch in diameter ; an ordinary size is from 1-300th
to 1-500th of an inch, so that there are generally from 27 to 125
millions of cells in the compass of a cubic inch of vegetable cellular
structure. In cells so minute occular demonstration of the modus
operandi is not to be expected, But they have been spoken of as

6 ENDOSMOSE

pladder-like bodies ; and with a bladder may be shown on a large scale
what is done by them on a small.

If a bladder be partially filled with water holding salt or sugar in
solution, have the orifice closed tight, and be put into a basin of
water, it will be found after a time that the bladder will become filled
and distended ; water has been absorbed through the tissue. While
it is thus with the bladder, if the remaining water in the basin be
examined it may be found to have acquired the peculiar taste of the
salt or the sugar of which a solution was introduced into the bladder
before its immersion; or if the taste be not perceptible, an appli-
cation of appropriate chemical tests will show that there is such salt
or sugar there in solution. Apparently there must have been a
transference of water from the outside into the inside of the bladder,
and a transference of a lesser portion of the solution of salt or sugar
from within to the water without in the basin; apparently this can
only have taken place through the tissue of the bladder; and all
that is known of the process goes to prove that it is not only so to
appearance but that it is so in fact. To these two distinct operations
the designations Hndosmose and Eaxosmose have been given by
Dutrochet, a French physiologist ; and these designations have come
into general use in treatises on the subject in our own and other
languages, Hndosmose being applied to the passage of pure water, or
of weaker solution, or a solution of other matters, from without, and
exosmose to the passage of the water with matter in solution from
within.

Reasoning from a widely extended analogy, it is thus that the
moisture is imbibed, absorbed, or, to speak more guardedly, trans-
ferred from without into the interior of the cell,

In consideration of this process being the initiative of phenomena
of vegetation on which the alleged meteorological effects of forests
depend, it may be well to ascertain, as satisfactorily as we can, how
it is that what takes place is effected, that we may carry with usa
definite conception of this radical operation in our subsequent con-
sideration of subsequent operations to which attention must be given.

Without entering on the question how matter is held together, I
may call attention to three manifestations of the attractive force :
that of cohesion, whereby particles of the same substance are held
together, as in a piece of wood, a drop of quicksilver, or a drop of
water; adhesion, whereby particles of one substance adhere to
another substance, as water, treacle, or tar adheres to the finger

AND EXOSMOSE. 7

dipped into it, while quicksilver does not; and chemical affinity,
whereby particles of one substance attract and enter into combina-
tion with particles of another substance with which they may be
combined, as in a solution of soda-water powders the tartaric acid
attracts the soda from the carbonate of soda and combines with it,
leaving the carbonic acid with which it was combined disengaged and
free to escape as it does in the effervescence which it occasions.

A clear conception of the differences thus indicated will make the
process of endosmose and exosmose more intelligible. In the illustra-
tions of adhesion which I have given, the attraction of adhesion
between the finger and the quicksilver was of less force than the
attraction of cohesion by which the particles of matter of which the
finger is composed, and than the attraction of cohesion by which the
particles of quicksilver are held together, and the finger could be
withdrawn unbroken leaving the quicksilver entire. But in the
other cases mentioned the attraction of adhesion, though less in force
than the cohesion betwixt the particles of matter of which the finger
is composed, was greater than that by which the particles composing
the water, the treacle, or the tar were held together, and this giving
way a portion adhered to the finger.

In the endosmose taking place in the case adduced for illustration
the adhesion to the bladder of the water in the basin must have been
greater in force than the attraction of cohesion by which the particles
of water were held together, and the chemical affinity of the saline
solution within the bladder for the water greater in force than the
attraction of adhesion by which it was held by the bladder. From
the moistened tissue of the bladder, water by which it was moistened
was attracted by and combined with the saline solution; this was
replaced by more from the basin, which in like manner was with-
drawn, and the process went on continuously, producing the pheno-
menon of endosmose. ;

The process of exosmose was similarly produced: the force of
adhesion between the saline solution and the inside of the bladder
was greater than the force of cohesion by which the particles of that
solution were held together ; but the chemical affinity of the water
in which the bladder was immersed for that saline solution was still
greater in force than that adhesion, and thus a portion of the saline
solution was withdrawn and combined with the water in the basin.

This is not given as a full explanation of all the phenomena of
endosmose and exosmose, but as an explanation of the more striking
phenomena produced, which is all that is required for the object in

8 RATIONALE OF

view. I may add that the explanation given does not render
necessary the ‘supposition of two distinct currents flowing in opposite
directions and crossing each other, one flowing in unbroken continuity
from without inwards, and the other flowing in unbroken continuity
from within outwards, either in the same or in different channels.
More probable is it that the transference is going on continuously,
simultaneously in both directions—a process which may perhaps be
made more intelligible by an explanation of what takes place in the
decomposition of water by galvanic influence. If a plate of zinc and
a plate of copper connected by a wire be kept apart and introduced
so into a vessel of water, the water will be decomposed, one of its
elements, oxygen, will be disengaged in connection with one of these
plates, and hydrogen, the other constituent element, will be dis-
engaged at the other; but there is no appearance of decomposition
taking place at any one or more points, and of the elements flowing
thence to their respective issues,—and what is actually seen, may be
explained by supposing that in immediate contact with one plate, or
with each, a particle of water is decomposed by the liberation of one
of the constituents which escapes, and the other is transferred from
particle to particle, only becoming visible when it escapes in contact
with the other plate.

The process may be illustrated mechanically by means of a six-
inch parallel rule, thus: let the one scale represent oxygen and the
other hydrogen ; let perpendicular lines divide them into six equal
spaces, which conjointly may represent particles of water composed
of oxygen and hydrogen ; let these be numbered, the first couple
each marked 1, the second couple 2, and so on ; let the two scales of
the ruler next be drawn in opposite directions, and if the spaces
marked on them be equal to the distance which each projects beyond
the other, you will have again spaces appropriately representing
particles of water ; but you will have oxygen No. 1 above hydrogen
No. 2, oxygen No. 2 above hydrogen No, 3, and so on ; hydrogen No. 1
and oxygen No. 6 representing what seems to take place in the
decomposition of water by that simple galvanic apparatus.

As in the decomposition of water by galvanism thus illustrated,
the escape of the hydrogen of water in contact with one plate, and
that of the oxygen of water in contact with the other plate, seem to
result from a transference of hydrogen from particle to particle, and
simultaneously with this a transference in the opposite direction of
oxygen from particle to particle, through the whole line of particles
of water intervening between the two plates,—so in the exosmosic

ENDOSMOSE. 9

and endosmosic action may the tranference be going on from particle
to particle, through the whole tissue of the bladder, without the
formation of any distinct currents of the two fluids as they exist.

It may be mentioned that the effect would be similar if the pure
water were put into the bladder, and the solution of salt or sugar
into the basin in which the bladder is immersed ; but in this case, in
accordance with what has been stated, the exosmose would be in
excess of the endosmose, more water would be withdrawn than would
be replaced. The difference in the quantity passed by endosmose
and exosmose may in both cases be attributed to the difference
between the force of the chemical affinity of the saline solution, or
the salt init, for water, and the force of the attraction of adhesion, by
which the water is kept attached to the bladder, being greater than
the difference between the force of the chemical affinity of the pure
water for the saline solution, and the attraction of adhesion by which
that solution is attached to the bladder.

If the chemical affinity of the saline solution for water be equivalent
to 8, and the attraction of adhesion of this solution to the bladder be
equivalent to 6, the difference between these is 2. If the adhesion of
water to the bladder be equivalent to 1, and the chemical affinity of
the pure water for the salt in the solution be equivalent to 1, the
difference between these is 1 ; and the endosmose would be to the
exosmose as 2 is to l.

Dr Asa Gray, Professor of Natural History in Harvard University,
Cambridge, Massachusets, in writing of endosmose and exosmose with
a solution of sugar as the subject of experiment remarks, in
accordance with what I have stated,—“ At the same time, the water
in the vessel will become slightly sweet; showing that a small
quantity of syrup has passed through the pores of the membrane into
the water without, while a much larger portion of water has entered,
The water will continue to enter, and a small portion of syrup to
leave it, until the solution is reduced to the same strength as the
liquid without. Ifa solution of gum salt, or any other substance, be
employed instead of sugar the same result will take place. If the
same solution be employed both in the vessel and in the [bladder]
no transference or change will be observed. But if either be stronger
than the other a circulation will be established, and the stronger
solution will increase in quantity until the two obtain the same
density. If two different solutions be employed, as, for instance,

10 ‘ MOISTURE ABSORBED IN

sugar or gum within [the bladder] and potash or soda without, a
circulation will in like manner take place, the preponderance being
towards the denser fluid, and in a degree proportionate to the
difference in density, Instead of animal membranes, any vegetable
matter with fine pores, such as a thin piece of wood, or even @
porous mineral substance may be substituted with the same result.”

All this is in accordance with observations made by Mateucci, an
Italian physiologist, who gave very careful consideration and study
to the phenomena as produced by experiments with various
substances, transferred by endosmose and exosmose through various
media, embracing the analogues, or homologues of almost every action
of the kind observed in animal physiology; and many, if not all
similar actions observed in vegetable physiology may be accounted for
as being thus produced. Thus, apparently, is the moisture absorbed
by uni-cellular plants like the Red Snow, and by the cells of which
such plants as the Yeast Plant, the Confervee, and the sea-weeds are
composed, and by the cells entering into the structure of such plants
as grass, and herbs, and bushes, and trees.

With the knowledge thus attained, attention may be given to the
absorption of water as a concomitant of vegetation.

“ There is hope of a tree if it be cut down that it will sprout again
and that the tender branch thereof will not cease. Though the root
thereof wax old in the earth, and the stock thereof die in the ground ;
yet through the scent of water it will bud and bring forth boughs like
a plant.” Thus wrote the author of the Book of Job more than three
thousand years ago—more than fifteen. hundred years before the
coming of Christ! On the other hand, drought is, I shall not say
destructive, but, interruptive to vegetation.

We need not yet enquire into the function of the moisture in the
cell development, we have only to do at present with the two facts
adverted to, that the scent of water promotes and revives vegetation,
while drought interrupts it.

In the case of the most of the lower forms of vegetation which have
been cited, the absorption is supposed to take place over all parts of
their surface, and in the case of all of these, excepting the Red Snow,
they are found growing surrounded with moisture; and thus the
growth of the gigantic sea-weeds is continued by the absorption of
moisture by the myriads of cells of which exclusively their covering
is composed.

But forests consist of trees and not of sea-weeds. And trees are

THE PROCESS OF VEGETATION. 11

not alge and conferve, but gigantic plants growing on dry land—
land hard and dry as the mountain brow. And to another phase of
vegetation promoted by the absorption of moisture attention may
now be given.

As with algee so with grasses and herbs, and shrubs and trees, their
whole structure is built up of cells, some of which may have been
elongated into vessels, or otherwise metamorphosed ; and the dry
dead cell walls of these constitute the pith and the woody fibre of
which trees seem chiefly composed. Of some of the vessels through
which the milk sap flows it may be that they have been formed
otherwise ; but the principal difference between the gigantic tree
and the gigantic sea-weed in the source of growth is only this, that
while the latter absorbs nutriment over the whole of its surface the
former does it mainly by the roots, and almost exclusively by the
cells at the extremities of the rootlets, where are masses of them,
which have, in reference to this function, received the designation
spongioles, or little sponges, resembling these as they do, not in their
structure, indeed, but in their power of absorption. They are often
represented in cute as rounded elongated expansions, but they are
not always to be so seen by the enquiring learner; examined micro-
scopically, they appear as numerous unprotected living cells at the
extremities of the rootlets, of which those furthest from the root to
which they belong continue to increase and multiply with rapidity in
appropriate soil, while those behind, and nearer to the stem, seem to
have lost in a great measure this power of reproduction.

It may seem that the absorbing surface bears but a very small pro-
portion to the entire bulk of the plant, and I am not concerned to
dispute the correctness of the conclusion that proportionally it. is
small, but what is proportionally small may be absolutely great.
Count the rootlets of an onion, or of a leek, or of a stalk of wheat,
and estimate if you cannot measure the superficial extent of the
spongioles ; calculate if you cannot count, and estimate if you cannot
even calculate, the hair-like fibrillee of the roots and ramified rootlets
of a shrub or a tree, and by reasoning try to form some idea of the
vastness of the superficies of the spongioles there, and you may find
that it is not to be despised. Bear in mind that much of the mass of
a growing tree is fixed and stable,—that a small streamlet may have
filled and may keep filled an extensive lake, provided only the out-
flow do not exceed the supply,—that a very small orifice or mouth,
and that used only occasionally for the purpose, may suffice and does
suffice for the feeding of a man or other animal,—and any prejudice

12 RISE OF SAP

hindering the ready acceptance of the doctrine, that the absorption of
moisture by the spongioles of a tree is the homologue of the absorp-
tion of moisture by the whole surface of the confervee of the streamlet
and of the algee of the sea, will be removed. ,

I have oftener than once made use of the term absorption, but
as may have been seen, from the explanation of exosmose and endos-
mose which has been given, it is scarcely applicable with propriety to
such a process; but with this caveat I may be allowed to make use
of it in lack of some term less exceptionable. It is solely in reference
to that process that I here employ it.

The water thus absorbed by the several cells composing the
spongioles of the root is by a similar process absorbed from them by
cells behind them ; and by continuous repetition of it by those beyond
the moisture absorbed from the soil is passed on and on, from the
extremities of the rootlets to the extremities of the smallest twigs,
and to the furthest and the loftiest extremities of the branches of the
trunk. There, through the leaves, a part, and that a large portion
of it, is given off into the atmosphere, while a part, comparatively a
small portion, is returned by the same duplex process of exosmose and
endosmose by the same cells, and others, their progeny, towards the
root. By the way is deposited, by exosmose, nutriment for the tree,
the leaf, the flower, and the fruit; and the residuum is in part deposited
by the same process in the leaves, the bark, or the root, and passed
off into the soil by the exosmosic action of the cells composing the
spongioles of the root.

It may now be seen how vegetation may have some effect in
increasing the humidity of the atmosphere ; but, as a preliminary to
the consideration of this, some further attention may be given to the
phenomenon of the rising of the sap.

The rise of the sap in trees is to many a phenomenon or fact for
which they cannot account satisfactorily to themselves ; or, if this
they can do, or think they can, they cannot do so in such a way as to
cover all the pheromena to the satisfaction of others. The pressure
of the atmosphere will not account for what is seen. Capillary
attraction has been thought of, but this does not account for a down-
ward flow of the sap, which is a part of the phenomenon, and it is a
downward as well as an upward flow which has to be accounted for,
Experiments have been made with a view to account for the upward
flow, the results of which, and perhaps some others, could be

BY ENDOSMOSE, 13

accounted for by what was called a vis a ¢ergo, a power or pressure
from behind ; but this, like the older aphorism that Nature abhors
a vacuum, will not stand examination ; and the elasticity and tension
of the wood accounts for all that was seen in the experiment which
suggested the phrase vis a tergo, or pressure from behind, though not
for all the phenomena connected with the rising of the sap. But in
endosmose there may be found a satisfactory mode of accounting for
all that is known to take place in connection with the flow of the sap.
I do not know a more simple illustration of exosmose and endosmose
than that which I have given, but to illustrate more fully the pheno-
mena, with a view to the explanation of the rising of the sap, I may
give the following: Let a piece of bladder be stretched over the
mouth of a funnel and tightly fastened there, and let a tube, if one
of glass so much the better, be attached to the orifice of the funnel ;
let this funnel, half-filled with a solution of salt, be immersed in water
with the tube projecting upwards. The water in the vessel will
become slightly saline through the escape, by exosmose through the
organic tissue, of a small portion of the solution of salt, but this will
be replaced by a much greater quantity of water entering by endos-
mose, and so increasing the quantity of water within the funnel
and tube, that this will be seen to rise in the tube, until—through
the dilution of this, and the loss, by exosmose, of a portion of the
substance held in solution—an equilibrium be established between
the strength of the solution on the one side and on the other of the
separating membrane. But should the tube be insufficient to contain
such a quantity as this would render necessary, the surface of the
solution will rise till the solution overflows, and it will continue to
flow until the equilibrium spoken of be established.

This experiment, with its results, makes manifest the difference
between endosmose and capillary attraction, depending, as they do, on
different actions; and it seems to indicate that the process of endosmose
may supply a satisfactory explanation of the rise of the sap in lofty
trees, though capillary attraction fails to do so.

yg The phrase capillary attraction is employed to account for the rise
of liquids to a considerable height in tubes of small diameter, and
through interstices of similar size in solid bodies. If several tubes
of different diameters of bore have their lower extremities immersed
in water and be held erect, the water will rise in them to different
heights and be sustained so elevated. The smaller the bore is the
greater will be the height to which the water will rise and at which
it will be sustained, hence the derivation of a name from ¢apilla, a

14 CAPILLARY ATTRACTION.

hair. In such phenomena the attraction of adhesion may be inferior.
in force to the attraction of cohesion, or equivalent thereto, but it is
80 great as to overcome the attraction of gravitation and to elevate
the contained column of water above the level of the mass to which
the attraction of gravitation would lower it but for the conteracting
influence thus exercised upon it. The quantity of water thus raised
is proportional to the area of the surface of adhesion, and to this the
attraction is confined; and thus it comes to pass that capillary
attraction cannot raise water till it overflow, as it does in the experi-
ment on endosmosic action which has been spoken of, and for which
the different action by which endosmose is effected enables us to
account. That action has already been explained.

If a worsted thread six inches long have two inches at the one end
immersed in water filling a basin to within half an inch of the top,
and the other end be allowed to hang down outside the vessel, the
water may rise in it and after a time begin to drop from the pendant
extremity, which it will do more readily if it be thoroughly
moistened immediately before ; and this may seem at variance with
what I have just said. If, however, we distingnish things which
differ, we may see that it is not so. The water may be raised in the
capillary interstices of the worsted thread in opposition to the attrac-
tion of gravitation to the level of the basin, and it may be onward
beyond it ; it may have been attracted a little way on its descent out-
side by the same force, but here there came into operation along with
this the attractive force of gravitation; as the water was drawn
onwards and downwards by capillary attraction, the co-operating force
of gravitation would be increased ; and at length the worsted thread
without ceasing to act by capillary attraction would become a verit-
able syphon, in which the gravity of the water in the longer limb,
and the pressure of the atmosphere on the surface of the water in
the basin would occasion a continuous flow.

I have not said all that might be said in regard to this; but I have
said enough to show that this is different from the overflow at its
upper extremity of a tube filled by endosmose from below, and, con-
versely that this is different from that, leaving it free to indicate that
endosmosic action may, as has been said, supply an explanation of
the rise of sap in lofty trees, though capillary attraction fails to do so.

I have referred to an opinion that the rise of the sap may be
attributable to a ws a tergo, and some of my readers may think that
in endosmose he has found this vs a ¢ergo, or, at least, a vis a tergo
which will explain all; and to this I would next attend. ,

,

VIS A TERGO. 15

The indication of the existence of what is called a vs a tergo, and
the illustration of its power usually given, is one supplied by an experi-
ment devised by Hales to measure, as he thought, the force with
which sap ascends ina stem. A tube, bent so as to ascend, descend,
and ascend again, had a quantity of mercury introduced into the
curvature between the descending and re-ascending portion, and was
attached firmly to a stem, the top of which had been cut off. It was
fastened on the stem by means of a copper cap which was secured by
a lute, and this was covered with a piece of bladder firmly bound
above ahd below the upper and the lower extremities of the cap ; the
level of the mercury at the commencement of the experiment was
noted, and as the sap rose in the stem, and through the stem into
the ascending limb of the tube, which it did, the pressure caused the
mercury to sink in the descending limb and rise in the ascending
one ; and thus could the pressure occasioned by the ascending sap
be measured.

Brucke, experimenting with such an apparatus, found that in a
vine the spring sap, having a specific gravity of 1:0008, raised a
column of mercury to the height of 44 inches, and therefore must
have created a pressure equal to that of a column of water 195 inches
high. In another experiment, sap of specific gravity 1:0009 raised
mercury to the height of 174 inches.

The force of the pressure in one experiment which was tried was
found to be equal to 38 inches of mercury, which Hales states is
nearly five times greater than the force of the blood in the crural
artery of a horse, and seven times greater than the force of the blood
in the same artery of a dog.

These statements I accept unhesitatingly. I know not what
precautions were adopted against error, and I cannot divest my mind
of the impression that the force of the pressure may have been due in
some measure to the elasticity of the stem released of the pressure of
the portion of the tree cut off. Knowing of no vis,a tergo but that of
endosmose, I accept the facts as an approximate measurement of that
action, and an indication of the rapidity with which it is carried on ;
but I do so only provisionally. The impression to which I have
referred remains. I have oftener than once cut down a banana plant
in vigorous growth, and in a few minutes seen the inner portion half
an inch or more above and beyond the entire integument, which may
have been occasioned by rapid growth ; but in the one case as in the
other, in the absence of certain knowledge, I cannot divest myself of
the impression that the phenomena may have been to some extent

16 EVAPORATION FROM LEAVES,

the result of the elasticity of the stem released of the pressure of the
portion cut off; and I claim only to have shown, as yet, how water is
taken up by trees from the soil, and that endosmose may supply an
explanation of the rising of the sap to the highest twigs, and to
the extreme ramifications of the most distended boughs.

Exosmose and endosmose are found to take place freely through
two tissues, the surfaces of which are contiguous to each other, the
double tissue acting much as a homogeneous tissue, thicker than
either of them would do; and in the knowledge of this—the know-
ledgé of the fact that sap does rise from the rootlet to the stem, the
knowledge that capillary attraction cannot explain all the phenomena
of the case, the knowledge of the fact that no other ws a tergo has
been discovered, and the fact that by endosmose and exosmose all
the phenomena of the case are explicable,—it seems not unreasonable
to conclude that thus it is that the rise of the sap may be effected.

At this stage of our consideration of these phenomena the determi-
nation of this is of importance, mainly, in satisfying us that we have
not lost sight of the moisture in tracing, or endeavouring to trace, its
course from the rootlets to the leaves. It will subsequently again’
demand our attention. It is the absorption of moisture from the soil
and the emission of a large portion of this into the atmosphere with
which we have chiefly to do in studying the meteorological effects of
forests on the humidity of a climate. It is by the spongioles that it
is absorbed, and by the leaves that it is emitted. The transmission
of that moisture from the spongioles to the root is, in so far as our
present study is concerned, not unimportant, but its importance is
only secondary in view of the absorption and emission ; and to the
means whereby this passage of moisture from plants by their leaves
is effected would I next direct attention.

The passage of moisture from plants by their leaves is effected
by means of what may be described, in mechanical phrase, as a
beautifally simple self-regulating ventilating-evaporating apparatus.
The operation of this I would illustrate thus: In the oxalis as in the
clover we have a leaf composed of three leaflets. In an oxalis
brought from Guatemala the whole leaf is almost transparent, and it
is said that six sets of vessels can be distinctly traced—three pairs,
one pair proceeding from each leaflet; and it is conjectured that in
other plants a similar arrangement exists; but in most plants it ig
difficult to separate and distinguish the different sets of vessels.
These vessels, with less or more of cellular matter, constitute the

STRUCTURE OF STOMATES, 17

mid-rib and leaf-stalk, and go to form the twig, branch and stem, or
trunk and root.

When the leaf itself is broken across, or cut, it may appear to be as
homogeneous as a sheet of paper of the same thickness, with scarcely
space sufficient for any more complicated structures; but when
examined with a microscope of considerable power it is seen to be
composed of a great number of cells piled loosely together, six or
eight or even more it may be in depth, with large spaces
intervening, and framed by a layer of similar cells, compactly
arranged like a brick floor, forming the back of the leaf,
and a double or triple layer of cells, similarly compactly arranged
like brick-work, two bricks or three bricks thick, forming the face of
the leaf. These are compact enough, but those constituting the
body of the leaf, filled with sap, are so loosely grouped, apparently
without any very determined or strongly marked arrangement, that
they only touch each other on parts of their surface, and the air may
play freely almost entirely round each and through amongst them
all. A simpler arrangement for thorough ventilation perhaps man
could scarcely imagine.

In the back of the leaf are numerous stomates, or mouths, The
structure of these differs in different plants, but what may be con-
sidered the typical structure is two elongated cells, resembling a
microscopic black pudding or thick sausage, so built into the struc-
ture of the skin of the leaf that this will not admit of their being
further elongated ; each of these is, along one side, attached to that
skin, but on the sides along which they are in contact they are free.
When moisture is in excess they become distended, but the structure
of the skin of the leaves is such that they cannot be elongated, and
they bulge away from each other, leaving a wide opening between
them through which the vapour with which the air surrounding the
cells in the interior of the leaf is charged finds an open exit. When
the pressure is relieved they, having lost some of the moisture or water
with which they were filled and distended, collapse to such an extent
as to diminish the opening ; and in this way, exactly to the degree
required, they vary and regulate that aperture—varying it, it may be,
I shall not say twenty times in the day, but, if necessary, twenty
times in the minute; and if drought become such as to render it
desirable that every drop of moisture in the plant should be preserved,
under the influence of that drought they become flaccid and com-
pletely close the aperture.

Such is the arrangement, in these galleries of the laboraturies of the
B

18 SIZE OF CELLS.

tree, for carrying off by evaporation all moisture which may escape from
the cells, which may ooze out, or may be passed by exosmosie action ;
and a little further consideration may lead to the conclusion that the
arrangement has been made, not to get rid of accidental leakage, but of
all moisture in excess of what is actually required after the sap has been
so elaborated as to fit it to minister to the nutriment of the tree. Be
this as it may, it is not unreasonable, but the reverse, to suppose that,
however compact the tissue or structure of the cell wall may be, there
may be, or that there must be, interstices between the molecules of
which it is composed. A drop of water falling upon a heap of fine
dust, or of powdered rosin, immediately draws around it a water-
proof covering of the material amongst which it has fallen, which,
though waterproof, is not airproof, and the enclosed waters may be
evaporated through the interstices of the investing covering. So may
it be with these, though on a scale infinitesimally reduced.

Professor Huxley, in a paper ‘On the Border Territory between
the Animal and Vegetable Kingdoms,” which appeared in Macmillan’s
Magazine for February 1876, citing some remarkable observations on
certain monads by Messrs Dallinger and Drysdale, which were
embodied in two papers in the Monthly Microscopical Journal for
1873, speaking of certain granules, living embryos, remarks,—‘ The
authors whom I quote say that they cannot express the excessive
minuteness of the granules in question, and they estimate their
diameter at less than 1-200,000th of an inch. Under the highest
powers of the microscope at present applicable such specks are hardly
discernible. Nevertheless, particles of this size are massive when
compared to physical molecules ; whence there is no reason to doubt
that each, small as it is, may have a molecular structure sufficiently
complex to give rise to the phenomena of life.” Compared with such
embryos, cells such as those of which the substance of a leaf is com-
pose are giants. In a cubic inch of a leaf of the carnation there are
said to be upwards of three millions of cells ; in some of the cucumber
tribe, and in the pith of aquatic plants, what are reckoned larger cells
are found—they are from 1—50th to 1-30th of an inch in diameter 5
but cells are frequently seen only 1—300th, 1-500th, and 1-1000th
of an inch in diameter. It would be difficult for many to conceive of
the size ofa cell 1-1000th of an inch in diameter ; but these granules,
were not the two hundredth part of that in diameter, and one of
these smallest cells, could contain six millions of the granules in
question !

To one conversant with structures so minute there is nothing

NUMBER OF STOMATES, 19

astonishing in the supposition that molecules of moisture should pass
through interstices between the molecules of which the cell walls are
constructed ; and, with what is known of endosmosic and exosmosic
action, it seems to be not unreasonable to suppose that any moisture
passing through the cell wall from within outwards might, by the
increased density following the evaporation of a portion of it, deter-
mine a current to follow it which would flow continuously. To the
consideration of what function of the leaf is thus subserved we shall
afterwards return: it is with the arrangement for the passage into
the atmosphere of moisture taken up by the spongioles with which
alone we are at present concerned,

Of the extent of the provision made for this evaporation some idea
may be formed from a consideration of the number of the stomata or
stomates to be found in the leaves of plants, often symmetrically
disposed. The number varies in different plants, for which variation
a reason may be found in the different conditions of growth to which
they are subjected in their several natural habitats. In the back of
the leaf of the apple tree there are about twenty-four thousand
stomates to the square inch. In the leaf of the lilac there are
a hundred and sixty thousand of them to the square inch.
Sixty thousand have been reckoned in a square inch of the under
surface of the white lily and three thousand in a square inch of
the upper surface. In the leaves of the cherry-laurel there are
none on the upper surface of the leaf, but ninety thousand have
been counted on the lower surface of the leaf. In the true lilies
they are so large that they may be seen with the aid of a
simple lens of an inch focus. In the water lilies, and other
plants having leaves which float upon water, all the stomates
are on the upper surface, where alone evaporation can take place.
Leaves of plants which grow entirely under water, where there can be
no evaporation, have none.

The mechanism of the opening and shutting of stomates has been
carefully investigated by Mohl, a distinguished German botanist, the
results are given in the Botanische Zeitung for 1866, p. 697 ; and it
appears that, while the general action is such as I have described,
other processes co-operate to ensure the result. It is partly controlled
by the effects of light, though depending mainly upon endosmose,
Mohl has shown that while the cells of the stomate themselves act so
as to open the stomate in moist weather and close it in dry, the

20 PHENOMENA OF VEGETATION.

adjacent cells of the epidermis, or skin enveloping the leaf, in swelling
when moist, tend to close the stomate, and their contraction when dry
to open it ; so that the actual state of the stomate at any one time is
the resultant of nicely adjusted opposing forces, and thus is secured
a self-regulation of the apparatus far more efficient than could be
secured in any laboratory of man, though an attendant were stationed,
hydrometer in hand, ready to close partially or entirely, or to reverse
such action in the ventilators of the evaporating chambers exactly in
‘regard to time and extent as the ever-varying state of the process of
evaporation in the chamber and state of the atmosphere might render
desirable.

But further, it is possible that in some cases, under peculiar
conditions or circumstances, it might happen that more moisture
might be evaporated than was conducive to the vigorous vitality of
the plant—in other words, the process of evaporation might go too
far—and we find that provision against this exists in many leaves,
in the existence of hairs which by endusmosic action can imbibe
additional moisture.

These hairs are always more numerous on the back of the leaf than
on the face, which in some plants is entirely devoid of them, though
the back be densely covered with them; and they may be found in
some plants to be always at the junction of veins in the back of the
leaf, as if designed only to act when it should become manifest that
surplus water which might happen to be retained in one of these
would not suffice to counteract a deficiency in the other.

Such is the beautifully-simple self-regulating ventilating-evaporating
apparatus in the leaf of a plant.

In the absorption of moisture by the spongioles of the rootlets, the
ascent of the sap, and the evaporation of excess of moisture after the
elaboration of the milk sap, we see some of the principal phenomena
of vegetation on which meteorological effects of forests depend.

CHAPTER. If.

Ow THE Quantity oF Moisture EvaPoRaTED THROUGH THE STOMATES
oF Leaves.

On results obtained by observation and calculation in regard to the
quantity of moisture evaporated through the stomates of leaves a
considerable difference of opinion exists.

Remarking on the results arrived at by observations of Schleiden,
Pfaff, and others, Marsh says,—‘ Allowing two hundred days for the
period of forest vital action, the wood must, according to Schleiden’s
position, exhale a quantity of moisture equal to an inch and one-fifth
of precipitation per day ; and it is hardly conceivable that so large a
volume of aqueous vapour, in addition to the supply from other
sources, could be diffused through the ambient atmosphere without
manifesting its presence by ordinary hygrometrical tests much more
energetically than it has been proved to do; and in fact the observa-
tions recorded by Kbermeyer show that though the relative humidity
of the atmosphere is considerably greater in the cooler atmosphere of
the wood, its absolute humidity does not sensibly differ from that of
the air in open ground. The daily discharge of a quantity of aqueous
vapour corresponding to a rainfall of one inch and a fifth into the cool
air of the forest would produce a perpetual shower, or at least a drizzle,
unless, indeed, we suppose a rapidity of absorption and condensation
by the ground, and of transmission through the soil to the rootlets
and through them and the vessels of the tree to the leaves, greater
than have been shown by direct observation.”

Cézanne, also, writing in regard to the action of vegetables as
“veritable alembics, which distil into the air a certain quantity of
water which their roots have drawn up from the soil,” says,—
“The Marshal Vaillant put a branch of an oak like a bouquet into
a vase full of water; he measured the water lost through its leaves
and he considered himself enabled to conclude that the tree from which
this branch had been detached would be emitting into the atmosphere
in twenty-four hours upwards of two thousand kilogrammes of water.*

* “ Revue des Kaux et Foréts,” July 1865 and June 1867,

22 PHENOMENA OF VEGETATION.

But this experiment has not satisfied all others. First of all, the
branch thus treated died in three days ; and then, even if it had lived
longer, it might have been said that the vegetable cut off from the
nourishing sap may have been able to absorb more than its usual
ration of clear water. It was in the situation of an animal deprived
of substantial aliment, which availed itself of pots of weak boudllon,
and yet died of hunger. And, moreover, the experiment has been
repeated not with a branch but with a young tree deprived of its
roots, and the evaporation proved to be very insignificant.”

But whatever may be said of such experiments, and of calculations
founded on them, we have other means of testing the quantities of
water passing through trees in the process of their growth; and we
find they must be far from inconsiderable. I have cited one state-
ment by Marsh, with this I cite also the following :—

“The amount of sap which can be withdrawn from living trees
furnishes, not, indeed, a measure of the quantity of water sucked up
by the roots from the ground—for we cannot extract from a tree its
whole moisture—but it supplies numerical data which may aid the
imagination to form a general notion of the powerful action of the
forest as an absorbent of humidity from the earth.

“ The only forest tree, known to Europe and North America, the
sap of which is largely enough applied to economical uses to have
made the amount of its flow a matter of practical importance and
popular observation, is the sugar maple, Acer saccharinum of Anglo-
American Provinces and States. In the course of a single ‘ sugar
season,’ which lasts ordinarily from twenty-five to thirty days, a sugar
maple, two feet in diameter, will yield not less than, twenty gallons of
sap, and sometimes much more. This, however, is but a trifling
proportion of the water abstracted from the earth by the roots during
this season ; for all the fluid runs from two or three incisions or
augur holes, so narrow as to intercept the current of circulation of
comparatively few of the sap vessels, and, besides, experience shows
that large as is the quantity withdrawn from the circulation, it is
relatively too small to affect very sensibly the growth of the tree.
The number of large maple trees on an acre is frequently not less than
fifty, and, of course, the quantity of moisture abstracted from the soil
is measured by thousands of gallons to the acre, The sugar orchards,
as they are called, contain also many young maples too small for
tapping, and numerous other trees—two of which, at least, the Black
Birch, Betula lenta, and Yellow Birch, Betula excelsa, both very
common in the same climate and far more abundant in sap than the

EVAPORATION. 23

maple—are scattered among the sugar trees ; for the North American
native forests are remarkable for the mixture of their crops.

“The sap of the maple and of other trees with deciduous leaves,
which grow in the same climate, flows more freely in the early spring,
and especially in clear weather, when the nights are frosty and the
days warm ; for it is then that the melting snows supply the earth
with moisture in the justest proportion, and that the absorbent
power of the roots is stimulated to its highest activity.”

In foot notes he adds :—“ Emerson (in his TZ'rees of Massachussets,
p. 493), mentions a maple, six feet in diameter, as having yielded a
barrel, or 314 gallons of sap in 24 hours, and another, the dimensions
of which are not stated, as having yielded one hundred and seventy-
five gallons in the course of the season. The Cultivator, an American
Agricultural Journal, for June 1842, states that twenty gallons of sap
were drained in eighteen hours from a single maple, two and a-half
feet in diameter, in the town of Warner, New Hampshire ; and the
truth of this account has been verified by personal enquiry made on
my behalf. This tree was of the original forest growth, and had been
left standing when the ground around it was cleared. It was tapped
only every other year, and then with six or eight incisions. Dr
Williams ( History of Vermont, p. 91), says,—‘ A man much employed
in making maple sugar, found that, for twenty-one days together, a
maple tree discharged 74 gallons per day.’

“ An intelligent correspondent, of much experience in the manufac.
ture of maple sugar, writes me that a second growth maple, of about
two feet in diameter, standing in open ground, tapped with four
incisions, has for several seasons generally run eight gallons per day
in fair weather. He speaks of a very large tree from which sixty
gallons were drawn in the course of a season, and of another, some-
what more than three feet through, which made 42h of wet sugar,
and must have yielded not less than 150 gallons,

“The same correspondent informs me that a Black Birch, tapped
about noon with two incisions, was found the next morning to have
yielded sixteen gallons. Dr Williams (History of Vermont, I. p. 91)
says,—‘ A large birch, tapped in the spring, ran at the rate of five
gallons an hour when first tapped. Eight or nine days after, it was
found to run at the rate of about two and a-half gallons an hour, and
at the end of fifteen days the discharge continued in nearly the same
quantity. The sap continued to flow for four or five weeks, and it
was the opinion of the observers that it must have yielded as much
as sixty barrels [1890 gallons].”

24 PHENOMENA OF VEGETATION.

These observations may give some idea of the quantity of moisture
taken up by the rootlets of trees.

Such is a report of facts ascertained in regard to the maple. It
does not follow that an equal quantity of moisture is raised by every
kind of tree ; but it may be said a corresponding quantity is, by every
one, or a quantity which may be spoken of as something like an
approximation to this. And though the fact has not, so far as I
know, been tested by exact observation, it is probable that the greater
portion of the moisture thus raised from the ground by plants,
whether arborescent or herbaceous, is by many of them passed into the
atmosphere by the stomates of the leaves—succulent plants with few
stomates being the exception—and that a portion, and it may be a
large portion, of the remainder passes into the soil by the process of
exosmose by which the circulation of sap in the plant is effected,
but returns to the soil only to be again taken up by the rootlets of
the same, or of some other plant, when it has been relieved of some
of the residuary matter with which it returned charged, and has taken
up a return load of nutriment ; but the probability that the quantity
thus returned to the soil bears but a small proportion to the quantity
passed into the atmosphere may be demonstrated by an observation
of the process referred to.

To some one charged with the watering of flowers, and who finds
the charge a burden, it may have occurred that he seemed to have
to supply far more water than could be employed in the structure of
the plant, that some, such as the balsam, seemed to require a fresh
supply morning, noon and night to keep them growing, and that to
planted cuttings and transplanted plants he could scarcely give too
copious a supply, and unless he had trimmed them by removing some
of the leaves scarcely would what he gave have sufficed : now perhaps
it may be understood why all this was necessary, and how the diminu-
tion of the foliage helped the growth of the plant when the supply
of moisture might otherwise have been inadequate to its maintenance
in life.

CHAPTER IIl.
DisPUTED AND SECONDARY PHENOMENA’ OF VEGETATION.

BEsmEs the phenomena of vegetation which have been detailed
there are other alleged phenomena, the import of which is more open
to question : amongst these may be reckoned the absorption of mois-
ture by the leaves of plants, the production of water by the plants
themselves, and the dropping of water from the leaves of certain
trees.

Szot. 1—Onx the Absorption of Moisture by the Leaves of Plants.

It is a prevalent opinion that moisture is absorbed by plants by
their leaves. I scarcely open a popular treatise on the subject in
which I do not meet with it ; but I have met with no evidence that
this is a normal action of leaves, excepting to a very limited and
easily defined extent. Abnormal action of leaves absorbing moisture
would prove as little as the abnormal absorption of moisture and
nutriment into the human frame by enemas and baths; and the absorp-
tion of moisture by gigantic algae over the whole surface of their stalks
and their fronds proves as little. But this cannot be said of experi-
ments which have been made on the growth of epiphytes and of
mundane plants, which have grown and flourished when freed of all
soil; or of trees growing naturally and at the same time luxuriantly
on narrow ridges, on steep declivities, on partially decayed stumps
many feet above the ground, on walls of high buildings, and on rocks,
in situations where the earth within reach of their roots could not
possibly, it is alleged, contain the tenth part of the water which,
according to Schleiden and Pfaff, they evaporate in a day. There
are, too, forests of great extent on high bluffs and well-drained table-
lands where, it is said, “ there can exist neither in the subsoil nor in
infiltration from neighbouring regions an adequate source of supply
for such consumption.”

These are facts established beyond all question ; but in regard to
what seems to be the natural conclusion, that in such cases the mois-

26 PHENOMENA OF, VEGETATION.

ture must have been absorbed by the leaves, I may remark that this
appears to me to be a non-sequitur ; and the burden of proof rests on
those by whom it is advanced.

In regard to the general opinion that moisture is absorbed by the
leaves of trees I may state that I believe this to be the case where
leaves are covered more or less densly with hairs, which are highly
hygroscopic, and which appear to be organs well fitted for the accom-
plishment of such a function, and are often placed as if such were
their function in given conditions ; and further, that to some extent
moisture may have been absorbed by endosmose where a deposit of
what may be called a secretion on the surface of the leaf gives some-
thing like an indication of this having occurred, but that the effect of
this must be small.

I have no testimony to the alleged absorption of moisture to an
appreciable extent by leaves having been observed ; and on the other
hand I have testimony on which I can rely that in South Africa there
are fig trees growing on rocks, over which the roots spread like
solidified molten lava or rosin, dipping down into every crevice and
spreading onward to the earth beyond ; and in the absence of evidence
of extensive absorption by leaves I consider it more probable that the

moisture is absorbed by such roots than by the leaves of the tree,
and the conclusion justified in such cases suggests the conclusion that
so may it be in others,

Sect. IL—On the Production of Water by Plants.

Amongst trees brought under my consideration in Africa by the
late Mr James Chapman—a man of careful observation who travelled
extensively throughout the whole region from Walfish Bay to the
Victoria Falls of the Zambesi and thither from Natal, traversing in
various directions the country intermediate between the region thus
indicated and Table Bay at the Cape of Good Hope—was the Kusché,
a large tree with a smooth dark grey-coloured bark and dark-coloured
oblong leaves, in the heart of the trunk of many of which is found a
large reservoir of water. From the description given to me, the tree
appeared to be the Millettva Caffra, known elsewhere in South Africa
as the Oomzambeete, or Kaffir Iron wood.

Mr Chapman first saw this tree when he and his companions were
suffering from thirst. Observing one of his native servants placing
forked boughs against a tree and preparing to climb, he asked what
he was going to do. “Look for water,” was the reply. The man

APPARENT]PRODUCTION OF WATER. 27

having mounted, cried ‘‘ Here it is.” The hard wood had decayed,
leaving a very deep hole, which was almost closed at the top,
apparently by the spreading arch of subsequently formed bark. One
of the companions of the man cutting then a twig or shoot from the
root, cut through the bark of this at two places two feet or thirty
inches apart, treated this as boys in Europe treat branches of alder,
of which they wish to make whistles, beating and pressing it; and
drawing out the wood, like drawing a sword from its sheath, he
handed up the bark to the man aloft, who, using this as a suction-
pipe, soon quenched his thirst, and made way for the others in
succession to do the same.

Frequently did Mr Chapman while travelling avail himself of the
supply of water thus retained.

Between the Victoria Falls of the Zambesi and Daka these trees
are found in clusters, sometimes 10 feet in circumference, and of
a much greater height than the other trees of the forest-country
around. They generally grow in clumps, in the higher portions of
the country.

Similar supplies of water are found in the Pitcher Plant, and several
other herbaceous plants of somewhat similar structure; and in the
Teazel, the Dipsacus fullonum, a quantity of water is often found in
the cup-like receptacle formed by the opposite leaves embracing
the stem.

In more than one of these cases the water may possibly be only
rain-water collected and retained, and in the other cases it may be
elaborated sap, the water of which was derived from the soil ; but
even were such cases thus disposed of, the question has been raised
and awaits an answer—May not water be a secretion of plants
themselves ?

I have intimated or stated explicitly what are my views in regard
to the source of the great bulk of the moisture passed into the atmos-
phere by the stomates in the leaves of vegetable production ; but I
know of nothing incompatible with the supposition of a portion being
added from the combination of oxygen and hydrogen, meeting in a
nascent condition in the process of chemical changes accompanying
vegetation.

Water is a product of the combustion of wood, and of coal, of oil,
of tallow, and of gas; it is a product of respiration in man and many
other animals, and may be obtained deposited by their breath ; and
there are lower forms of animals by which it is produced, and that,

28 PHENOMENA OF VEGETATION.

in proportion to their size, much more abundantly. The question,
Whence is this obtained ? has been raised oftener than once.

Dr Livingstone, in describing a severe and long-continued droughy
at Kolobeng (the mission station occupied by him before he entered
on his journeyings in the interior), a drought during which “ needles
lying out of doors for months did not rust, and a mixture of sulphuric
acid and water, used in a galvanic battery, parted with all its water to
the air instead of imbibing more from it, as it would have done in
England,” says,—“ The leaves of indigenous trees were all drooping,
soft and shrivelled, though not dead ; and those of the Mimose were
closed at mid-day, the same as they are at night. In the midst of
this dreary drought, it was wonderful to see those tiny creatures the
ants running about with their accustomed vivacity. I put the bulb
of a thermometer 3 inches under the soil in the sun at mid-day, and
found the mercury to stand at 132° and 134°; and if certain kinds
of beetles were placed on the surface they ran about a few seconds
and then expired; but this boiling heat only augmented the activity
of the long-legged black ants.” And having raised the question,
‘Where do these ants get their moisture?” he proceeds,—“ Our house
was built on a hard ferruginous conglomerate, in order to be out of
the way of the white ant, but they came in despite the precaution ;
and not only were they, in this sultry weather, able individually to
moisten soil to the consistency of matter for the formation of galleries,
which in their way of working is done by night (so that they are
screened from the observation of birds by day in passing and repassing
towards any vegetable matter they may wish to devour), but when
their inner chambers were laid open these were also surprisingly
humid ; yet there was no dew, and the house being placed on a rock
they could have no subterranean passage to the bed of the river,
which ran about 300 yards below the brow of the hill. Can it be
that they have the power of combining the-oxygen and hydrogen of
their vegetable food by vital force so as to form water ?”

A still more remarkable case is mentioned by Dr Livingstone.
Writing from Golungo Alto Angola, on the west coast, lat. 91° S., he
says,— Before leaving I had an opportunity of observing a curious
insect which inhabits trees of the fig family (Ficus), upwards of
twenty species of which are found here. Seven or eight of them
cluster round a spot on one of the smaller branches and there keep
up a constant distillation of a clear fluid, which, dropping to the
ground, forms a little puddle below. If a vessel is placed under
them in the evening it contains three or four pints of fluid in the

APPARENT PRODUCTION OF WATER. 29

morning. . . To the question, Whence is this fluid derived? the
people reply that the insects suck it out of the tree, and our own
naturalists give the same answer. I have never seen an orifice, and
it is scarcely possible that the tree can yield so much. A similar, but
much smaller homopterist insect, of the family Cercopide, is known
in England as the frog-hopper (Aphrophora spumaria) when full-
grown and furnished with wings ; but while yet in the pupa state it
is called ‘ Cuckoo-spit,’ from the mass of froth in which it envelopes
itself. The circulation of sap in our climate, especially in the
Graminacee, is not quick enough to yield much moisture. The
African species is five or six times the size of the English. In the
case of branches of the fig-tree, the point the insects congregate on
* is soon marked by a number of incipient roots, such as are thown out
when a cutting is inserted in the ground for the purpose of starting
another tree. I believe that both the English and African insects
belong to the same family and differ only in size, and that the chief
part of the moisture is derived from the atmosphere. I leave it for
naturalists to explain how those little creatures distil, both by night
and day, as much water as they please, and are more independent
than Her Majesty’s steam-ships, with their apparatus for condensing
steam, for without coal their abundant supplies of sea water are of no
avail. I tried the following experiment :—Finding a colony of these
insects busily distilling on a branch of the Ricinus communis, or
castor-oil plant, I denuded about 20 inches of the bark, on the tree-
side of the insects, and scraped away the inner bark so as to destroy
all the ascending vessels. I also cut a hole in the side of the branch,
reaching to the middle, and then cut out the pith and internal
vessels. The distillation was then going on at the rate of one drop
each 67 seconds, or about 2 ounces 54drams in 24 hours. Next morning
the distillation, so far from being affected by the attempt to stop the
supplies, supposing they had come up through the branch from the
tree, was increased to a drop every 5 seconds, or 12 drops per minute,
making one pint (16 ounces) in every 24 hours. I then cut the
branch so much that during the day it broke ; but they still went on
at the rate of a drop every five seconds, while another colony on a
branch of the same tree gave a drop every 17 seconds only, or at the
rate of about 10 ounces 44 drams in 24 hours,

“T finally cut off the branch ; but this was too much for their
patience, for they immediately decamped, .as insects will do from
either a dead branch or a dead animal, which Indian hunters soon
know when they sit down on a recently killed bear. The presence

30 PHENOMENA OF VEGETATION.

of greater moisture in the air increased the power of these distillers ;
the period of greatest activity was in the morning, when the air and
everything else was charged with dew.

“Having but one day left for experiment I found again that
another colony on a branch denuded in the same way yielded a drop
every two seconds, or 4 pints 10 ounces every 24 hours, while a
colony on a branch untouched yielded a drop every 11 seconds, or
16 ounces 232 drams in 24 hours. I regretted somewhat the
want of time to institute another experiment, namely, to cut a branch
and place it in water, so as to keep it in life, and then observe if there
were any diminution of the quantity of water in the vessel. This alone
was wanting to make it certain that they draw water from the atmos-
phere. I imagine that they have some power of which we are not
aware besides that nervous influence which causes constant motion to
our own involuntary muscles, the power of life-long action without
fatigue. The reader will remember, in connection with this insect,
the case ‘of the ants already mentioned.”

The same question is taken up by Sir J. E. Tennant, in writing of
what he had observed at Ceylon.

“ Entomologists,” says he, “have raised the interesting question,
Where do the termites, or so called white ants—though of another
genus than the common ant—where do they derive the large sup-
plies of moisture with which they not only temper the clay for the
construction of their long-covered ways above ground, but for
keeping their passages uniformly damp and cool below the surface 2
Yet their habits in this particular are unvarying—in the seasons of
drought as well as after rain, in the dryest and least promising
positions, in situations inaccessible to drainage from above, and cut
off by rocks and impervious strata from the springs below. Dr
Livingstone, struck with this phenomena in Southern Africa, asks—
Can the white ants possess the power of combining the oxygen and
hydrogen of their vegetable food so as to form water? And he
describes at Angola an insect resembling the Aphrophora spumaria,
seven or eight individuals of which distil several pints of water every
night. It is highly probable that the termites are endowed with
some such faculty. Nor is it more remarkable that an insect should
combine the gases of its food to produce water, than that a fish
should decompose water to provide itself with gas. Fourcroix found
the contents of the air-bladder in a carp to be pure nitrogen ; and
the aquatic larves of the dragon-fly extracts air for its respiration,
from the water in which it is submerged. A similar mystery per-

DROPPING FROM LEAVES, 31

vades the enquiry—Whence plants, under peculiar circumstances,
derive the water essential to vegetation ?”

The constituents of water are oxygen and hydrogen; the con’
stituents of ammonia are hydrogen and nitrogen ; the constituents of
carbonic acid are carbon and oxygen; and the principal constituent
of atmospheric air are nitrogen and oxygen; with these is combined
or intermixed carbonic acid ; carbonic acid and ammonia are likely to
be absorbed largely by water, and so carried into the plant ; carbon is
fixed, being the principal constituent of wood, and thus oxygen is set
free; a smaller quantity of nitrogen is fixed, but enough to indicate a
decomposition of ammonia to have taken place; and it is not un-
reasonable to suppose that all the ammonia taken up by the plant
may have been decomposed, the nitrogen combining with oxygen, set
free by the decomposition of the carbonic acid yielding material for
the woody structure, and appearing as atmospheric air, and the
hydrogen combining with oxygen and forming water.

With regard to the second statement by Dr Livingstone, I would
require to be in possession of much more information than I am
to enable me to form an opinion on the subject; but I may state
that I find nothing in the narrative incompatible with the supposition
of the moisture in this case having been obtained from the tree ; and
I avail myself of the interest which such a narrative may have
excited to direct attention to the similar copious supplies of moisture
flowing from leaves and from incisions in the trunks of trees.

Szcr. III.—On the Dropping of Water from the Leaves of certain Trees.

Of the dropping of water from trees there are numerous instances ;
but while in some of the more remarkable cases the popular opinion
is in favour of the supposition that this was one of the primary
phenomena of their growth, the consideration of the conditions under
which it occurs leads to the conclusion that it is one of the secondary
effects of vegetation.

I have spoken of some of the more remarkable cases. In an old
work, entitled Historia de la Conquista de las siete islas de Gran
Canaria de Juan de Abreu Gal indi, published in 1832, at page 47,
mention is made of a celebrated laurel, in Ferro, which is said to
have furniched drinkable water to the inhabitants of the island.
According to the statement, every morning the sea breeze drove a
cloud towards the wonderful tree, which attracted it to its huge top,

32 PHENOMENA OF VEGETATION.

and the water flowing from its foliage uninterruptedly, drop by drop,
was collected in cisterns.

I have met with a similar account of a tree to the east of Tocat in
Asia-Minor, visited by the Rev. Mr Van Lennep, and described by
him. Mr Lennep is said to be well-known as a competent observer.

In the case mentioned first there is the explicit statement that
“Every morning the sea breeze drove a cloud towards the wonderful
tree.” And there is nothing in any of the statements I have seen
relative to these phenomena inconsistent with the supposition that
they may have been produced by the deposition of moisture on the
surface of the leaves, irrespective of the source whence the moisture
was obtained. ;

Dr Wells, in an essay on Dew,—a little work which, according to
Sir John Herschel, deserves to be considered as a model of experi-
mental enquiry,—was the first to place in a clear light the nature of
the process of dew formation. According to his views, as epitomised
by Sir John Herschel, “ The chief facts to be accounted for are these :
1. Dew (as distinguished from small rain or moisture produced by
visible fog) is never deposited except ona surface colder than the air.
2. It is never deposited in cloudy weather ; and so strict is its con-
nection with a clear sky that its deposition is immediately suspended
whenever any considerable cloud passes the zenith of the place of
observation. 3. It is never copiously deposited in a place screened
or sheltered from a clear view of the sky, even if the screen be of very
thin material, such as muslin or paper suspended over it. 4. It is
most copiously deposited on all such leaves as are good radiants and
bad conductors of heat, such as grass, paper, glass, wood, &c., but
little or not at all on bad vadiants, such as polished metals, which are
also good conductors. And lastly, it is never deposited if there is
much wind. All these circumstances, as Dr Wells has shown, point
to the escape of heat from the bodies exposed by radiation out into
space, or into the upper and colder regions of the air, faster than it
can be restored by counter-radiation, or by conduction, from contact
with the warm air—or with solid substances—the wind acting in this
respect with great efficiency by continually removing the air in con-
tact. Hoar frost differs only from dew by being frozen in the
moment of deposition, and therefore accreting in crystalline spicule.”

It may have been observed that tufts of grass and other herbage
are often covered with dew-drops in the early morning, or with hoar
frost if it be winter, though the ground be not so; and it may have
been observed that heavy drops of water fall from a tree in a fog

DROPPING FROM LEAVES. 33

though not a drop of rain may be seen to fall beyond it. The
phenomena may be similar.

The temperature of the human body, as ascertained by a thermo-
meter with its bulb placed in the shoulder-pit or under the tongue,
is within a very limited range—when the man is ina state of health—
the same in the Arctic regions and in the tropics, and the degree
known as blood-heat is as stable as is the boiling point of water.
Scarcely less stable is the freezing point of water or the freezing
point of mercury. It is something similar with trees. According to
experiments made by Meguscher, in Lombardy, and results of these
recorded in Memoria sur Boschi della Lombardia, and cited by Marsh,
trees maintain at all seasons a constant mean temperature of 54° Fahr,

Observations which have been recorded by others have made it
appear questionable whether a tree does resist the cooling process
induced by external cold, but I know not of any question having been
raised in regard to its counteracting the effects of external heat of
a higher temperature than its own. This seems to be generally
admitted. In the animal this resistance is effected by evaporation;
in the vegetable it is probable it is effected by the same means, or by
evaporation and radiation combined. The subject will again come
under consideration, when it may be discussed at greater length,

I have called attention to the dew and hoar-frost being seen on
the grass and herbage at early morn. In hygrometry mention is
frequently made of the dew-point : this is the temperature at which
the air is exactly saturated with the quantity of moisture it contains,
any fall from which would occasion a deposit of all that was in excess
of what exactly saturates the air at the lower temperature. In
accordance with observation, and with reasoning on the subject, the
dew-point is frequently the same as the lowest temperature of the
night; and the lower temperature of the grass and herbage, con-
sequent on radiation from their surface, occasions a deposit of dew-
drops in the same way as a glass of cold water, by lowering the
temperature of the air adjacent to it, is in like manner bedewed.

According to the observations of Meguscher, whenever the temper.
ature of the air is above 67° degrees Fahr., the temperature of the
tree will be, to the extent of the excess, lower. If the temperature of
the atmosphere be 90°, and the dew-point 75°, there will be a copious
deposit of dew; and if the lower temperature be the consequence of
radiation the deposit may be expected to take place over the whole of
the upper surface of the leaves, these in the aggregate, according to

o

34 PHENOMENA OF VEGETATION.

the statement of Humboldt, measuring several thousand times the
area of the ground they cover. And there should be as little to
startle one in finding dew-drops falling from a tree while the sky
is cloudless and serene, as in finding melted hoar-frost dropping
when the sun has arisen upon the tree in winter.

But in the case of the laurel at Ferro it is expressly stated, “ every
morning the sea breeze drove a cloud towards the wonderful tree,
which attracted it to its huge top.” Such were the phenomena, and
the explanation which suggests itself is more simple. In regard to
fog or mist—and a cloud is only a form of this—Sir John Herschel,
in the treatise from which I have already quoted, says,—“ The form
in which the moisture so precipitated first appears will necessarily be
that of very minutely-divided particles, which, however, having the
refractive power of water, reflect and refract light as such, and appear
therefore as a mist, fog, or cloud of greater or less density and opacity,
according to the amount precipitated in a given volume. It is a
favourite dogma with many meteorologists that the particles so pre-
¢ipitated assume the form, not of drops, but of hollow spheres or
bubbles. De Saussure states that he has seen such, floating before his
eyes in clouds and fogs on the Alps, and the dusty appearance of the
vapour floating over a cup of coffee in the sunshine is adduced in
illustration. The strongest argument adduced in their favour, however
for there is great room for optical illusion in such matters), is that
adduced by Kratzenstein, that the sun striking on a cloud or fog
produced no rainbow, which it ought to do were the water collected in
spherical drops. This argument does not admit of a ready answer ;
but the difficulty, on the other hand, of conceiving any possible mode
in which such bubbles can be formed disposes us to believe that the
extreme minuteness of the globules may be found to afford one, their
diameter being of an order comparable with the breadth of the
luniniferous undulation.”

Thus wrote Herschel in the article in the Encyclopedia, To the
second edition of the article, published as a volume in 1861, he added
in one foot-note that he had never himself seen such a phenomenon as
was spoken of by Saussure, and that hehad questioned Alpine excursion:
ists of far more extensive experience than his own, with a like negative
reply. And in a second foot-note he says,—‘“On the Newtonian
doctrine of fits of easy transmission and reflection, or (which comes to
the same thing) on the hypothesis of light consisting in rotating cor-
puscles with attractive and repulsive poles, there would be no difficulty
of the kind [mentioned in the text]. A globule, or a particle of water

DROPPING FROM LEAVES. 35

of any other form, whose greatest linear diameter did not exceed the
thickness of that central spot in a soap bubble which reflects no light,
would be equally non-reflective, and therefore incapable of forming a
rainbow. In the undulating theory, however, it is the parallelism of
the surfaces of the film of which that central spot consists which
renders it non-reflective. I suspect, however, that in the case con-
templated in the text that theory, carefully re-examined, would render
a somewhat different account of the singular abruptness of transition
from the most brilliant reflexion to an almost absolute extinction of
the reflected ray, and of the uniformity over large areas of a thin film
of the still remaining fraction of the incident light which it does
reflect, than that usually given.”

Of the undulatory theory of light I shall have occasion, in a sub-
sequent part, to treat at some length.

Whatever may be the form of the cloud particles, be they drops or
bubbles, they are in the cloud or mist so far apart—and are kept
apart by conflicting attractions, exercised by all upon each and by
each upon all—that it is long before multitudes coalesce to form rain.
drops, and a slight rise of temperature may lead to their being again
absorbed by the air without their falling to the ground; but the
particles deposited on the leaves, brought into closer proximity, and in
many cases contact, rush into each other like drops of quick-silver,
and the attraction towards the earth becoming greater than the
attraction of adhesion they fall from the leaf to the ground. And
thus may the dropping reported have been occasioned.

In passing through a fog the moisture collects like dew-drops on the
hair, the whiskers, the eye-brows, and even on the eye-lashes, and on
every projecting filament of wool in the clothes; and so is it also
with the cloud or mist surrounding a tree, or borne through the
interstices of its twigs by the wind, the minute drops collect upon
its leaves. And I presume the fact has only to be mentioned to
recall to some of my readers that in a mist they have seen heavy
drops falling from foliage while there was no rain.

I find some pertinent observations on this point in a work entitled
“The Climate and Resources of Madeira,” by Dr Graham, a work
which I shall afterwards again have occasion to quote. The author
remarks,—“ The power of trees upon mist is very great. Where
there are no trees, the cloud drives along, depositing little or no
moisture. But trees largely intercept mist ; and the small component
vesicles of water coalesce upon the leaves and branches, and fall in
drops of water upon the earth. The mists form, whether there be

36 PHENOMENA OF VEGETATION.

trees or not; but the water is strained out and saved by the forest
foliage.” He says, “I have watched with much interest for the com-
mencement of dripping, in reference to the pre-eminence of certain
kinds of foliage in powers of condensation. The pine trees invariably
begin first, the rough brush-like clusters of leaves being well adapted
to intercept the smallest particles of moisture. The yield of water
from this source is very great. The laurels extract water plentifully
from mists which are more sensibly damp.”

Dr Graham further states that,—“In one of the Canary Islands,
the people show the place where, at the head of a deep valley, stood
a fine solitary til tree, which daily used to strain a large quantity of
water from the humid mist, conveyed inland by the sea breeze.
The tree is mentioned by Cordeyro and subsequent writers. But
both the spring of water and the tree are now gone; and the mists,
though they still remain, pass over unstrained of their moisture.”

The difference noted by Dr Graham in the effect of different kinds
of trees may be attributed in some cases—in others if not in those
mentioned by him—in some measure, First, to differences in the
number of stomates through which the evaporation from the leaves
of the tree itself is effected. These vary in different plants from a few
to 160,000 or more in the square inch of surface. The number in
the leaves of the cherry-laurel is 90,000 in every square inch on the
back of the leaf. In such state of atmosphere as is specified by
Dr Graham, every stomate would probably be distended, an atmos-
phere of dense moisture would surround the tree and this precipitated
by a fall of temperature might in part create the supply.

The difference may be attributable, in some measure, Secondly, to
differences in the extent of the radiating surface, supplied by the
leaves, whereby the temperature might be effected. This is much
greater in the foliage of a pine tree than in the herbage of a laurel.

And the difference between the effect produced by the laurel and
other trees may be attributable, in some measure, to difference in
the attraction of adhesion between water and the leaf. From the
glossy surface of the laurel leaf the moisture deposited might run off
quickly, while to the leaves of other trees it might cleave, as if loathe
to shake itself free, and adhere till again evaporated, or till it fell in
drops undistinguishable from the rain, when this began to drizzle.

In all such cases as have been mentioned, whether fog be visible
or it be otherwise, the precipitation and consequent dripping is
attributable to the temperature of the atmosphere surrounding the
tree being below the dew-point, and the moisture contained in it

DROPPING FROM LEAVES. 37

there being in excess of what saturates it, in accordance with the
elements by which that dew-point is determined. These are ascer-
tained by observation of the difference of temperature indicated by a
wet and a dry bulbed thermometer, of the barometric pressure, and
of the elastic force of the vapour at the temperatures, and under
such pressure. The elements are numerous, but the formula of
calculation simple, and copious tables for facilitating this have been
published.

In regard to the effects of different trees, I find it stated by a
writer on the subject, in “The Farmers’ Magazine,” Mr Cuthbert W.
Johnstone, that “the dew under some large oak trees, by the side
of his bowling green, at Croydon, is always considerable of an
evening ; but that under a witch-elm growing by their side the dew is
almost always absent.” In Europe, generally, it has been found that
the most copious humidity or moisture has been produced by the
elm, and, in decreasing order, by the poplar and horse-chestnut, while
the least effect is produced by firs.

PART IT.
ErFrects oF Forests ON THE Hummpiry oF THE CLIMATE.

Cuap. I.—Imuepiate Errects or Forests oN THE HumMIDITY
OF THE ATMOSPHERE.

Tuer is a wide-spread opinion that forests attract clouds and rain,
and a similar effect is attributed to mountains, The facts which have
been adduced may enable us satisfactorily to account for the pheno-
mena upon which the former opinion is founded; and with the
explanation thus supplied we may be enabled also satisfactorily to
account for the latter. The phenomena referred to may be stated
generally to be these: forests and mountains are frequently seen
surmounted by clouds, stationary or passing over them, when few or
none are seen elsewhere in the heavens; and, though it may be an
unwarrantable conclusion that they have been attracted thither, it
does not excite surprise that this conclusion has been drawn from the
phenomena observed. In the case of forests we know, however, of
no kind of attraction exercised by them which could produce this
effect ; the effect can be accounted for satisfactorily in accordance
with the phenomena of vegetation which have been under consider-
ation ; and in these circumstances it is reasonable to conclude that
these, supply the correct rationale of what is seen. Of this a simple
exposition can be given, and one not less simple can be given of the
similar phenomena in the case of the mountains ; and the exposition
of the former supplies at the same time the means of accounting for
the proverbial dampness of houses overshadowed by trees, or situated
in close proximity to woods,

The meteorological effects of trees and forests may be apparently
paradoxical, and accounts of them conflicting and contradictory ; but
if instead of acting on the principle of cutting the knot we act on
the principle of unloosing it we may find that all facts observed and
reported are consistent with each other, and that many of them can
be accounted for satisfactorily in accordance with what is known of
operations patent to all. If, instead of attempting the reconciliation

DAMPNESS NEAR WOODS. 39

of eonflicting theories, we study the facts separately and apart,
we may find that, when all is done, there are no conflicting views to
reconcile ; and this I shall endeavour to do, stopping at any point
when lack of information renders further advance hazardous,

Szcr. .—On the Humidity of the Atmosphere in the Vicinity of Trees, -
indicated by the Dampness of Houses overshadowed by Trees,
or situated in close proximity to a Wood.

It is matter of common observation that houses closely surrounded
with trees are damp. Oftener than once have I heard a sufferer from
rheumatism told, You must get your husband to cut down that tree
overshadowing the house, or you will never be well.

There may be nothing injurious in damp itself, but in evaporation
damp induces cold, and cold may be injurious to the human frame;
damp, moreover, is conducive to the decomposition of dead organic
matter; the products of vegetable decay or decomposition tend to
produce ague, intermittent fever, rheumatism, neuralgia, and tooth-
ache ; and in the absence of appliances for determining the hygro-
metric condition of the atmosphere, the frequent occurrence of such
maladies may be considered indicative of the existence of the moisture
to which reference is made.

With the information which has been produced, one need not be
surprised at the dampness of houses so situated. With evaporation
going on continuously, from stomates so numerous in every one of
such a multiplicity of leaves, the quantity of moisture in the air must
be much greater than it is in an open space; and though the
temperature may be such as to keep it suspended in solution, an
affinity for moisture in the material of which the house is built will
attract it thence and keep the walls, and the apartment within, damp,
or at least less dry than otherwise they would have been.

The quantity of moisture which clay, bricks, and granite, and other
forms of stone can retain in their structure, while to touch and to sight
they appear to be dry, has been ascertained, and it has been found to
be great ; and some of them not only retain moisture, but absorb
moisture from the atmosphere. I know a noble mansion uninhabit-
able in consequence of the dampness produced by this property of the
stone of which it is built. I have known a wall to be kept constantly
damp through the attraction of moisture from the atmosphere by the
sand employed in the manufacture of the mortar; and I do not
recollect of ever seeing a house, built of unburnt brick, perfectly dry,

40 EFFECTS OF FORESTS ON HUMIDITY.

—and I have seen hundreds,—the clay having this property in @ pres
eminent degree.

The walls of houses built of such materials, standing in an atmos-
phere kept humid by over-shadowing trees, or trees growing in close
proximity, or even in a proximity not very close, absorb moisture
with which the atmosphere is charged. The moisture transmitted or
permeating it to the inner surface may be evaporated by the heat of
the apartment within, but only to be followed by more and more,
keeping the interior of the house constantly humid. Many have
suffered for years in consequence of taking up their abode in a newly
built house not thoroughly dried. In the case of such a house as I
have referred to, it is never thoroughly dried, the drying process will
go on continuously, or be continuously renewed, for a hundred years
and more, if the house stand as long.

Not a little of the dampness may be attributed to the shade and
the shelter of the trees, and the consequent want of ventilation ; all
which will afterwards come under consideration. What is brought
under consideration at present is the humidity of atmosphere
consequent on the copious evaporation of moisture by the leaves
of trees. Reference has been made to the hydroscopicity of the
walls of houses simply to show that the damp is not produced, but
only transmitted by them; and it must be apparent that, in
like manner, the damp experienced in connection with want of
ventilation with shade and shelter, is damp not produced but
only retained by them. The dampness of houses overshadowed by
trees, or situated in close proximity to a wood, is indicative of
humidity of atmosphere; and this humidity of atmosphere is
occasioned, in part at least, by the copious evaporation proceeding
from the leaves of the trees.

Sct. II.—On Clouds occasionally seen surmounting Woods, while
the Atmosphere around is comparatively Clear.

The clouds occasionally seen over woods, while the atmosphere
around is comparatively clear, are consequent on the condensation of
the humidity occasioned by the evaporation from the leaves. ?

There is always moisture existing in the atmosphere ; it is reckoned
one of its constant constituents, but it varies in quantity. The quantity
is minute compared with that of the oxygen and nitrogen of the air ;
but it is never absent. There it is, on the highest mountain and in

CLOUDS SURMOUNTING FORESTS, 4}

the deepest. mine ; on the ocean’s surface and on the dry land a
thousand miles away.

But, as has been mentioned, while moisture may be found in the
atmosphere everywhere, it is not always present in the same quantity
in the same space. In almost any circumstances, but more especially
where there is an unlimited supply of moisture, the quantity varies
with the temperature, and varies with the temperature to a very
great degree. According to Sir John Leslie, it doubles with every
rise of twenty-seven degrees of temperature; and, according to
subsequent observers, it varies to a still greater extent, the doubling
taking place at different intervals, which increase slowly with the
temperature—the mean being 23° 4'—from the freezing point to 100°
Fahrenheit.

According to Leslie’s calculation, the air at a temperature of 59° or
60° will hold twice as much as at 32°, or the freezing point ; and at
86° it will hold twice as much again. And, according to later
observers, at 121° it will hold twice as much again, or sixteen times
a8 much as at 32°, eight times as much as at 53°, or four times as
much as at 75°.

It is customary to speak of this as the solvent power of the atmos-
phere, as if the moisture were dissolved in the air as sugar may be
dissolved in water ; but it is more in accordance with fact to consider
that as water requires a certain amount of heat to keep it from
passing into a state of ice, so it requires a certain amount of heat to
keep it in a state of vapour and prevent it from passing into a state
of water.

In accordance with this, it happens that if air of a higher temper-
ature, having as much moisture in it as can be sustained in a state of
vapour, be cooled down some degrees, a quantity of moisture, which
can no longer be maintained in a state of vapour, will assume the
form of water in minute drops, and appear as fog, or cloud, or mist ;
but let the temperature be again raised to the same elevation as
before, and this water will again assume the state of vapour, and the
air become transparent, the fog or cloud having melted away. In
illustration of this fact, I may refer to what is seen in the laying of
the cloth on Table Mountain when the south-east wind blows, The
temperature on the top of Table Mountain is lower than that of the
wind blowing over its summit, and the mountain cooling down the
air, a quantity of the vapour intermixed with it is deposited in the
form of a cloud which is blown over the face of the mountain, and
falls, threatening to bury the city below; but before it can reach

42 EFFECTS OF FORESTS ON HUMIDITY.

Cape Town it must pass through an intermediate stratum of air of a
higher temperature than that to which it has been reduced. By this
it has its temperature again raised, and the cloud evaporates and
disappears, followed by continuous masses of cloud, which on reaching
the same level vanish into thin air, leaving no trace behind.

The quantity of moisture passing into the atmosphere from the
leaves of a forest in active vegetation must be considerable. Cal-
culate the number of stomata, or stomates, on a leaf, multiply this
by the number of leaves on a branch, the product by the number of
such branches on a tree, and the product of this by the total number
of trees in the clump, or the total number of trees in the forest, and
the final product will indicate the provision made for evaporation
from the forest. There are similar stomates on every verdant plant
on the dry land ; but the evaporating surface supplied by the leaves,
rising tier above tier, far exceeds in extent that supplied by the
herbage and the grass growing elsewhere ; and in many places these
may be found growing as luxuriantly on the soil of the forest as in
the fields beyond, or perhaps more so, and adding their quota of
evaporation to the evaporation from the trees.

Of the moisture thus raised by the tree, and no longer required
when the sap has been elaborated in the leaf, the air will only take
up what quantity it can, at the temperature at that time and place,
dissolve and hold in solution ; and cases have been cited in which the
excess is so great that the leaves seem to act as alembics, distilling
water which falls in great drops to the ground.

Where this does not take place, what the air dissolves it will hold
in solution so long as the temperature is maintained at the same or a
higher point ; but if the temperature fall below the point at which it
can do this, what it cannot sustain as invisible vapour will be
deposited or suspended in the form of mist, or cloud ; and such a
reduction, may follow the setting of the sun, or even the decline of it
in the afternoon and towards nightfall; or if there come over the
trees a wind in any degree colder than the air in which they are
enveloped, the air is thereby cooled down, and a quantity of the
moisture which it held in solution may be deposited in the form of
fog, or of dew, or of rain.

But this is not all; we shall afterwards have occasion to consider
more fully the effect of vegetation on temperature, but here it may
be remarked that it will generally be found that the temperature,
both of the earth and of the atmosphere, is lower amidst abundant

CLOUDS SURMOUNTING FORESTS. 43

vegetation than in a barren, sterile, stony district, probably by heat
being absorbed and retained in a latent form by the process of
vegetation in the one case, while in the other it is reflected
unchanged. In consequence of this, if a wind in any degree hotter
blow over the district covered with trees, this wind is cooled down ;
ita power of holding water in a state of vapour is thereby diminished,
in a geometrical ratio, with every fall of temperature, and a large
deposit of moisture may follow in the form of dew, of mist, or of rain.

The deposit may be much greater than may seem to be pro-
portionate to the fall of temperature, but a reference to the
observation of Sir John Leslie, and others, that a fall of temperature
from 121° to 86°, which is not impossible in a semi-tropical country,
occasions a deposit of half of the whole of the moisture held in
solution, which is sixteen times as much as could be held in solution
by air at 32°, eight times as much as could be held at 53°, and four
times as much as could be held at 70°.

In illustration of what deposit of moisture might take place on
such a fall of temperature if the air were nearly saturated, and the
quantity of air so saturated great, I may quote the following descrip-
tive account of one of those storms which frequently relieve the heat
of Bengal, given by Mrs Murray Mitchell, in a volume, entitled
“Indian Sketches of Life and Travel,” lately published. The
oppressiveness of the heat is described as such that one’s hands
“have a boiled feeling, like a washerwoman’s who has been all day
manipulating in the tub.” Outside, the sun floods everything with
one white blaze. “ Nature is perfectly still, as if awed; the leaves
hang limp and parched ; the grass crumples up and disappears; the
poor birds hide themselves away in any corner where there is a bit of
shade; there is not even a fly abroad ; all life seems frightened into
quiescence, and mankind—at least the native portion—is asleep.” At
such a moment the storm suddenly descends. It is thus described :—

“ Last week we arranged a nice little garden entertainment for our
native friends, and invited some people to meet them. The green
was set with numbers of small tables, covered with cakes, and tea,
and ices, and flowers. Seats of all sorts and bits of carpet were put
down everywhere. Some of our friends had come, and our garden-
party promised to be both pretty and pleasant, when, lo! Mr Don
said quietly, ‘Look there!’ and truly enough a cloud like a man’s
hand had risen in the west, and we knew what would follow. Con-
gternation seized us; we all jumped to our feet ; each one snatched
up something—chair, table, cups, fruit, everything—and rushed pell-

44 EFFECTS OF FORESTS ON HUMIDITY.

mell into the house. Not a moment too soon. The heavens grew
black as ink ; the birds flew in terror to some cover, filling the air
with their screams ; the wind swept past with a low portentous sigh :
and we had hardly our goods and ourselves under shelter, and the
doors and windows secured, when the storm was upon us, and raging
in mad tumult without.

“The air becomes thick with sand, and lurid, like the yellowest of
London fogs ; the wind rises into fury, and the dust is driven hither
and thither as by a whirlwind. The sun seems blotted out, and in
the appalling darkness you see the lightning play and dart, and zig-
zag from heaven to earth, without one moment’s intermission. The
thunder comes, not in distinct explosions, and then a pause, but in
one continuous roll of terrific reverberating noise, while the rain
descends with an abandon quite in keeping with the other forces of
the storm. It generally comes in horizontal sheets of water instead
of drops, and is driven by the mighty wind as you have seen seaspray
driven from the wave-tops in showers of foam. A storm like this is
a magnificent spectacle, and its effects are delicious. In a wonder-
fully short time the conflict ceases—the thunder rolls away into the
distance, the wind is hushed, the sun shines out, and Nature, though
tearful, looks happy and refreshed. Everything literally rejoices on
every side; the air feels cool and light, and for some days there is
pleasure in existence.

“Our little fete was spoiled ; but when the war without ceased, we
made up by dog what we could for the pleasure of our guests
within, and all is well that ends well.”

I design not to convey the idea that the moisture thus precipitated
had been passed into the atmosphere by the foliage of a forest; I
find no indication that a forest was there—it is the precipitation
occasioned by the reduction of temperature alone which I seek to
illustrate.

Previous to such a downpour of rain the heavens were perfectly
clear, without a cloud to be seen ; yet there, it may be, the whole of
that moisture was suspended, dissolved in the air, The rain-cloud
may have appeared to proceed from beyond the horizon, and to come
thence, advancing onwards with resistless force, borne forwards by
the gust of wind, more like a tornado than aught else ; but there are
reasons, and these satisfactory ones, to warrant the conclusion that
the cloud had not been blown thither by the blast, but had been
formed at the various points of its advance, by the wind suddenly
cooling down the air below a temperature at which it could hold the

CLOUDS SURMOUNTING FORESTS. 45

moisture in solution: very much as is the case with the sand and
dust filling the air immediately before the falling of the rain; what-
ever proportion of these may have been brought from a distance
more or less remote, most of it may have been seen raised from the
ground on the spot as the mighty rushing wind passed on in its
course ; and the little lapse of time between the appearance of this
precursor and the precipitation of the rain was only such as was
required, or at least such as was occupied, in the aggregation of the
rain particles into the larger drops which fell, and the precipitation
of these by gravitation and by the blast, aided, it may be, by the
co-operation of electric force, the process being essentially the same
whether the blast have come on like an onward moving cold wave,
or have advanced as an advancing whirlwind which raised the air
through which it passed to an elevation at which, it may be in
consequence of sudden expansion, the temperature was too low to
retain all the moisture in solution.

With the copious evaporation going on from the leaves of a forest
there is nothing, in view of such a rainfall, surprising in any change
of wind producing a cloud or mist above a forest, where formerly
the air had been perfectly transparent; and everything known in
regard to such phenomena makes it probable that in general, if not
invariably, the cloud is produced there, and not attracted thither by
the forest.

In connection with this, there is an observation, made by Mr Marsh,
which demands attention :—“‘ There is one fact,” says he, “ which I
have nowhere seen noticed, but which seems to me to have one
important bearing on the question, Whether forests tend to maintain
an equilibrium between the various causes of hygroscopic action, and,
consequently, to keep the air within their precincts to an approxi-
mately constant condition, so far as this meteorological element is
concerned. I refer to the absence of fog or visible vapour in thick
woods in full leaf, even when the air of the neighbouring open ground
is so heavily charged with condensed vapour as completely to obscure
the sun. The temperature of the atmosphere of the forest is not
subject to so sudden variations as that of cleared ground, but, at the
same time, it is far from constant, and so large a supply of vapour as
is poured out by the foliage of the trees could not fail to be condensed _
into fog by the same causes as in the case of the adjacent meadows,
which are often covered with a dense mist while the forest air
remains clear, were there not some potent counteracting influence

46 EFFECTS OF FORESTS ON HUMIDITY.

always in action. This influence, I believe, is to be found in the
equalization of the temperature of the forest, and partly in the
balance of the humidity exhaled by the trees, and that absorbed and
condensed invisibly by the earth.”

I accept the statement with all confidence in the correctness of the
observation by Mr Marsh. The fact was previously unknown to me.

By the fall of leaves and their decay, and in other ways, the soil
in which trees grow becomes rich with humus, by which means its
power of attracting moisture from the earth is increased. In a forest
the temperature is more equable than in the open country ; to both
of these facts Mr Marsh refers, and I may add, what is also held by
him, that there is heat evolved as well as heat absorbed in vegetation,
a point which will afterwards be discussed more fully. In virtue
of this and of the shelter of a forest, it may in certain conditions
continue for a time, more or less protracted, protected from a change
of temperature, producing a fog in the open country around.

Without ampler information, or personal observation of the fact
with opportunity of noting the circumstances, I am not in a position
to say more.

Sect. III.—On Clouds occasionally seen surmounting Mountains while
the Atmosphere ws otherwise Clear.

With regard to the phenomena of clouds apparently attracted by
mountains, Mr Marsh, in his treatise “On the Earth as Modified by
Human Action,” writes,—“ In discussing the influence of mountains
on precipitation, meteorologists have generally treated the popular
belief that mountains attract to them clouds floating within a certain
distance from them as an ignorant prejudice, and they ascribe the
appearance of clouds about high peaks solely to the condensation of
the humidity of the air, carried by atmospheric currents up the slopes
of the mountains to a colder temperature ; but if mountains do not
draw clouds and invisible vapour to them, they are an exception to
the universal law of attraction. The attraction of the small Mount
Shehallien was found sufficient to deflect from the perpendicular, by
a measurable quantity, a plummet weighing but a few ounces. Why,
then, should not greater masses attract thence volumes of vapour
weighing many tons, and floating freely in the atmosphere within
moderate distances of the mountains ?”

As stated thus, the popular belief assumes a form in which it can
be dealt with more satisfactorily than in the vaguer form in which it

CLOUDS SURMOUNTING MOUNTAINS. 47

is generally met with. The answer I would give to the question is,
However plausible the supposition may be, I desiderate evidence that
gravitation can occasion a deposit of moisture suspended in a state
of solution in the atmosphere, operating on it otherwise than it
does upon the other constituents of the air; and the phenomena
seen can be accounted for satisfactorily otherwise.

All that was done by Mount Shehallien was to cause a deflection of
the plummet ; the preponderating attraction was towards the earth’s
centre. The phenomenon under consideration is not a deflection
from the perpendicular, but the appearance of clouds on the moun-
tains alone.

We cannot get rid of the idea that the earth by gravitation exerts
an attractive force upon clouds, but they do not fall precipitately upon
the earth. Solid matter, so comminuted as to appear as dust, floats in
the atmosphere for a length of time, rising even with aerial currents
in despite of gravitation ; so is it with the molecules of water ina
fog. With regard to invisible vapour, it appears to be subject to the
law of gaseous diffusion, in which, though still held by gravitation
within the atmosphere, it is free within the limits of this to go any
whither. True, moisture can be withdrawn from the atmosphere, and
it is so withdrawn, but this is not attributable to gravitation ; it is
attributable to chemical affinity, whatever that may be, and it varies
with the composition of the soil and the chemical affinity of its con-
stituents for moisture.

In lack of evidence that the attraction of gravitation exercised by
the earth abstracts moisture dissolved in the atmosphere from the
air, I see no reason to conclude that by gravitation has moisture been
abstracted from the air on the mountain top when there the cloud is
formed.

While I desiderate evidence that gravitation can occasion a deposit
of moisture suspended in a state of solution in the atmosphere,
operating on it otherwise than it does upon the other constituents of
the air, and evidence that the gravitation occasioned by mountains
differs in its nature from the more powerful gravitation exercised by
the earth, I see no evidence of their attracting clouds; and all the
phenomena connected with the appearance of clouds surmounting
mountains may be accounted for in accordance with the way in which
the appearance of clouds surmounting forest has been accounted for,
that is by a fall of temperature below that at which the vapour there
suspended in the atmosphere could be sustained by it in solution.

It is in defence of that view that the subject comes under consider-

48 EFFECTS OF FORESTS ON HUMIDITY.

ation, and what has first to be established is the possible production
of clouds in a transparent sky. The case of a Bengal storm has been
cited ; but as evidence of the case in question it may be considered
insufficient, I therefore supplement it with more explicit testimony.

At the Cape of Good Hope, again and again, I have seen the
heavens gather blackness where shortly before the sky was cloudless,
the first manifestation of a change being the appearance of clouds
the size of a man’s hand, not blown thither, but there appearing as if
formed there, and the progress and completion of the change resemb-
ling somewhat the dissolving view represented by a magic lantern. The
clouds were neither blown thither bodily nor attracted, but were formed
there, apparently by an intermixture of currents of air of different
temperatures. And again, the whole cloudland structure—bold in
its outline as the smoke belching forth from the cannon’s mouth at
the moment of discharge, and magnificent as a realization of Fancy’s
dream of Ossa piled on Pyleon, and Pyleon-like mountains on Ossa
again—passed away like the deposition of vapour breathed upon the
polished steel, passed away as if it had never been, leaving not a
wreck behind. And the corresponding phenomenon I have seen when ,
according to the local phrase, the Devil lays his table-cloth on Table
Mountain. To this I have already had occasion to refer.

At these times the summit of the mountain is covered with a dense
mass of beautiful white fleecy cloud in constant flow over the precipice,
and pouring down the almost vertical front of the mountain facing
Table Bay as if threatening to bury inan avalanche the capital of the
colony at its base; but long ere it reaches the town, notwithstanding
the continuous flow, it stops; to that line it flows on continuously,
but beyond it, not: there the cloud in unceasing flow terminates, the
spectator sees not why.

The beautiful and interesting phenomenon is occasioned by a south-
east wind, which, up to the Table Mountain range, was undimmed.
The wind was strong, but the sky blue and serene, though the wind
was loaded with vapour—vapour dissolved and invisible,

But passing over Table Mountain the elevation of this is such
that the decrease of temperature, consequent on expansion under
diminished pressure bringing this below the dew-point, the moisture
is deposited by the air in the form of cloud, which, as it reaches at
lower level to leeward, a locality with a higher temperature, the
moisture is again absorbed and the air loaded with it is again trans-
parent, as is all the air around, and as it was itself before passing
over Table Mountwin in its course.

CLOUDS SURMOUNTING MOUNTAINS. 49

From Claremont, or Wynberg, or the Flats, or any place to the
back of Table Mountain, it may be seen that the cloud is not blown
to the mountain, but there it first appears ; and if some few clondlets,
formed over the crests of hills belonging to the range situated to
windward, be seen sailing towards it, it is evident that they are
“A sailing, a sailing with the wind,” and not attracted only, for none
are seen floating towards the Table-Cloth in other direction than that
in which the wind blows.

Of this phenomenon Sir John Herschel writes, “ That the mere self-
expansion of the ascending air is sufficient to cause precipitation of
vapour, when abundant, is rendered matter of ocular demonstration
in that very striking phenomenon so common at the Cape of Good
Hope, where the south or south-easterly wind which sweeps over the
Southern Ocean, impinging on the long range of rocks which ter-
minate in the Table Mountain, is thrown up by them, makes a
clean sweep over the flat table-land which forms the summit of that
mountain (about 3850 feet high), and thence plunges down with the
violence of a cataract, clinging close to the mural precipices that
form a kind of background to Capetown, which it fills with dust and
uproar. A perfectly cloudless sky meanwhile prevails over the
town, the sea and the level country, but the mountain is covered with
a dense white cloud, reaching to no great height above its summit,
and quite level, which, though evidently swept along by the wind,
and hurried furiously over the edge of the precipice, dissolves and
completely disappears on a definite level, suggesting the idea (whence
it derives ils name) of a ‘table-cloth.’ Occasionally, when the wind
is very violent, a ripple is formed on the aerial current, which, by a
sort of rebound in the hollow of the amphitheatre in which Capetown
stands, is again thrown up, just over the edge of the sea, vertically
over the jetty—where we have stood for hours watching a small
white cloud in the zenith, a few acres in extent, in violent internal
agitation (from the hurricanes of wind blowing through it), yet
immovable as if fixed by some spell, the material ever changing, the
form and aspect unvarying. The ‘ table-cloth’ is formed also at the
commencement of a ‘ north-wester,’ but its fringes then descend on
the opposite side of the mountain, which is no less precipitous,”

I mean not to affirm that in every case the clouds capping
mountains and mountain ranges have keen formed in the same way.
All that I affirm is that thus it is there in the circumstances stated,
and thus it may be elsewhere oftimes when clouds are seen covering a

mountain brow, and that, whether these mountains be wooded or bare.
D

50 E-FECTS OF FORESTS ON HUMIDITY.

When the mountains are covered with forests of deciduous trees,
the great quantity of moisture passed into the atmosphere by the
stomates of the leaves may render the air more readily indicative of
any fall of temperature, but that is all.

The phenomenon in question comes under consideration here solely
because this and the phenomenon of clouds surmounting woods are
generally referred to as indicative of an attractive power over clouds
being exercised by the one and by the other; and it may be satis-
factory to some student of the meteorological effects of forests to see
that neither in the one case nor in the other is there any necessity to
call in the aid of some unknown, and consequently mysterious, power
of attraction to enable us to account for the phenomena observed.

CHAPTER II.
Errects oF Forests on tae Huurpity oF tas Grounp.

It may be considered a departure from the professed subject of this
treatise to speak here of the effects of forests on the humidity of the
ground; but the subjects are correlated, Practically it is humidity of
soil which is what is desired, and the conservation of m>isture in the
soil has a direct influence, in different ways, on the moisture in the
atmosphere, so important as to justify, if not to require, some
attention, being given to it in treating of the meteorological effects of
forests,

The subjects coming under consideration here are the following:
The wetness of roads when overshadowed by trees ; the shelter afforded
by trees against drying winds ; and the attraction and retention of
moisture by vegetable mould ; and to this might be added the effect
of trees in arresting the flow and escape of the rainfall—but a better
opportunity for bringing these under consideration will afterwarda
present itself.

Szor. I.—On the Wetness of Rowds where these are Overstadowed
by Trees.

We have had under consideration the dampness of houses over-
shadowed by trees, or situated in close proximity to woods. Not less
noticeable than this is the wetness of roads where these are over-
shadowed by trees. This may frequently be observed while elsewhere
the road is dry, and it may be supposed that in this we have only an
exaggerated effect of what occasions the dampness of such houses;
but there is more in the phenomenon than this would imply.

While much of the rain which falls upon the earth, and much that
falls in the form of snow and hail, flows away to the sea—the tiniest
streamlet and the mizhtiest river or flood being alike the product
of such flow—and while a portion is absorbed by the earth, a great deal
is evaporated and absorbed by the air. The higher the temperature of

52 EFFECTS OF FORESTS ON HUMIDITY.

the ground the more rapid is this evaporation. The effect may be
seen in the steaming of the streets after a short shower in summer ;
there is then more evaporated from the hot stone than the super:
incumbent air can sustain in solution, and the surplus is temporarily
deposited in a visible form. And in the wetness of the roads under
the condition stated we see, in addition to effect of the trees in
increasing the humidity of the atmosphere by evaporation through
the stomates of the leaves, the effect which they bear i in checking or
preventing such evaporation from the ground.

The quantity of moisture held suspended in solution in air, or
which may be so held, increases with the temperature, and when the
sun’s rays fall unimpeded upon the road this raises the temperature
of the earth and stones; and these by contact and radiation raise the
temperature of the incumbent air, which in its turn takes up the
moisture with which they were covered : the moisture being evaporated
in the same way as isa drop of water falling on a hot stove, or as the
moisture on a wet handkerchief when this is held to the fire, but less
rapidly, as the temperature is not so high. .

The same difference as is seen on the exposed and shaded part of
the road may be seen in the ground on the sunny and shaded sides of
a house, only less marked because the shade is less complete,

I have stated in another volume that, to test the correctness of
some statements, I had had occasion to muke at the Cape of Good
Hope, on the effect on the destruction of herbage by fire on the
desivcation of the country, Mr W. Blore, M.L.A., Fellow of the
Meteorological Society of London, and Secretary of the South African
Meteorological Society, made some experiments with the following
result :—He sunk two cylindrical jars, of the same size, in the ground
to the depth of 4 inches, leaving them projecting an inch above the
surface, as a precaution against sand and other matters being blown
into them, and covering each with wire gauze to keep out flies, &e.
The one was placed where it was partially protected, but not covered
by bush, the other was sunk in a newly cleared plot of ground,
measuring about 60 feet in dirmeter, surrounded by sugar bushes,
Protea mellifera Thbg, of a considerable height, and otherwise pro-
tected from the prevailing wind by a belt of pine trees, about 120
feet distant.

Into each of these jars was put 20 oz. of water on January 31st, at
10 a.m. On February 5th, at 5 p.m, the water remaining in each
was carefully measured, and the evaporation was calculated, when

EXPERIMENTS ON EVAPORATION. “53
it was found that the evaporation from the jur sunk in the cleared
ground had been more than double the evaporation from that which
was partially protected, though not covered by the bush; the
former being 1:854 in.; the latter °863 in.; giving an excess of
‘991 in. The experiment was repeated with similar results.

In reporting these results Mr Blore remarked that had the experi-
ment been made in a more arid district, the evaporation would have
been greater ; and that had it been made in the open country, the
difference would have been marked. But, taking the results obtained
as the basis of calculation, he arrived, by the following process, at a
conclusion for which, probavly, few who have not given attention to
the subject are prepared.

The excess of evaporation from the more exposed jar above that
from the jar partially shaded, but not covered, being one inch, more
strictly speaking upwards of ,°?, of an inch of water, and more than
double that of the latter. “An inch in six days,” says he, “ will give
for 102 days, the ordinary duration of the hot windy and dry season
in the district, 17 inches. This is equal to about three hundred and
eighty-four thousand (334,000) gallous per acre, and supposing 1,090
acres to be burued, blackened, and driel—what with sunlight, fire,
heat, and wind, the evaporation would be an excess of three
hundred and eighty.four millions of gallons of water above what
would have been evaporated if the bush or grass had been left
unburned.”

In the prosecution of his researches, Mr Blore ascertained by
experiment that on Wynberg hill, while the deposit of dew on a
green surface amounted to 4°75, that on a white surface amounted
only to 2, showinz that the deposit of dew upon a green surface is
more than double that upon a white; and he further ascertained
that, while the difference of temperature in the water in the two jars
employed in the former experiment was only a few degrees, the
difference of temperature between black ground and ground shaled
by bush was about 25°, which would occasion a vastly greater
difference in the amount of evaporation than that which occurred in
his experiment.

Tn a letter on planting trees by water-courses, appended to Report
of Colonial Botanist for 1863, it is stated :—“In the course of
my tour I have found that in some places an opinion prevails
that trees growing by the side of a stream, steal away the water,
And in support of this opinion, my attention was directed to the

54 EFFECTS OF FORESTS ON HUMIDITY.

fact that under trees or plants the moisture spreads for several
inches, eighteen or twenty it may be, over and through the banks
towards the tree, while at exposed places between the trees the
moisture spreads not above one or two inches from the surface
of the water. But this, so far from proving what was alleged,
may be adduced as evidence of the correctness of my view of the
matter. The water spreads from the stream by what is called
capillary attraction, and spreads in all probability quite as far in the
exposed as in the covered spots, but where it is exposed it is con-
tinuously evaporated by the heat of the sun’s rays, so that, excepting
during the night and early in the morning it never becomes visible in
the darkened hue of the guvil, while under the shade of the trees it
has been protected from evaporation. There the water which has
spread so far is retained with very little loss. But at the exposed
parts of the bank there is a constant drain throughout the day.
Water evaporates ; more rises to supply its place ; but this is carried
off in like manner, till the setting of the sun suspends for a time this
wasteful process. So far from the tree stealing the water, it takes up
no more than it retains in the structure of its sap, wood, flowers,
fruit, and green leaves; the heat is the thief, if thieving there be.
The tree has not stolen away the water which occasions the moisture
seen under its shade. The soil did that, and it did the same all
along the water-course; and the tree, like the faithful dog, has
watched over and protected that portion from the heat of the direct
rays of the sun, by which it would otherwise have been conveyed away
and transported by the air to regions, it may be, far remote.”

While I adhere to the statement thus made, I may add that in
the remark which called it forth there is—as there often is in pepular
remarks—a mixture of truth and error; it was neither absolutely
correct nor absolutely erroneous : the tree had actually withdrawn
moisture from the streamlet, for thence it was that the moisture re-
tained in its structure and the moisture evaporated by its leaves had
mainly been obtained ; but the blackness and dampness of the soil
between the streamlet and the tree to which it was that my attention
was called had not thus been produced,—that moisture had not been
occasioned by the vegetation of the tree but by the capillary attrac-
tion of the soil, The shade of the tree had prevented the direct rays
of the sun falling upon this as they did upou the ground around ;
thus an evaporation, such as had dried the ground beyond, had been
prevented ; and in the same way is the desiccation of a road retarded
where it is overshadowed by trees.

SHELTER TO PONDS. 55

In the Journal of the Royal Agricultural Society, N.S., vol. ii,
p. 110, there is a statement, by Mr R. Orlebar, of Willingborough, on
the advantage of planting trees around ponds, in which he says, “ It
is astonishing what effect a little shade has in checking evaporation,
A pond that is well shaded will hold water for weeks after one
of equal dimensions, but lacking shade, will become dry. The best
shade is that given by fir trees, or other evergreens, for they give it
all the year round. The yew, perhaps, would be even better for
shade than the fir, but for its poisonous qualities. After the fir, I
doubt whether there is, on the whole, any better plant for shade than
the hawthorn bush. Its leaves sprout early, and fall late; and it
possesses, besides, the great advantage that it forms its own fence.”
And the writer tenders the counsel, suitable for Europe and couutries
in the northern hemisphere, ‘“‘ Always, if possible, have the routh
of your pond on the north side, and the shade on the south side,”
A suggestion which commends itself. While the writer speaks only
of shade, it may be that the effect mentioned by him was to some
extent due to shelter afforded to the pond from wind.

I find it stated, in reference to the suggestion of Mr Orlebar, by a
writer, On the Dew of Heaven and the Influence of Forests, in the
Farmer's Magazine, Mr Cuthbert W. Johnstone, that in some parts of
England they are careful to have the oak planted around their ponds ;
and he mentions, as bearing upon this point, a fact to which I have
already referred, that the dew under some large oak trees by the side .
of his bowling-green, at Croydon, is always considerable of an evening ;
but that under a witch-elm, growing by their side, the dew is almost
always absent. Observation will show whether this difference is attribu-
table to the difference in the shade afforded, or to a difference in the
quantity of moisture evaporated through the stomates of the leaves,
in accordance with what has previously been stated with regard to
the dropping from trees (ante p. 35).

Sgct. II.—On the Desiccation of Ground by Drying Winds being
Prevented by the Shelter afforded by Clumps of Trees.

In the case of a tree by the side of a stream with the ground
between the stream and its trunk moist, while all beyond was dry, we
had an indication of the effect of a tree in preventing evapuration by
protecting the moist ground from the sun’s rays, and it may be, in
part, by reflecting or confining vapour rising from the soil ; but not
less important is the influence exerted by a clump of trees in

’ jf BOE sta

56 EFFECTS OF FORESTS ON HUMIDITY.

preventing evaporation, by protecting moist sroatit from the
esiccating effect of wind.

We often hear of a drying wind ; and many may have remarked
that. a, clear w wind does more to dey the roads in spring than does
even bright sunshine. Every clear wind is a drying wind ; it is
composed of air not surcharged with moisture ; up to the measure of
saturation every particle of this air can take up and dissolve
additional moisture, and it will do so by simple contact therewith.
Were the air stagnant, evaporation might go on slowly, the air in
contact with the moisture taking up a portion of it and slowly
transferring this to the stratum above, to be in like manner trans-
ferred to the strata beyond ; but moved on, as every particle of the
air is, by and with, and in the wind, it imbibes a portion and passes
off loaded to let more follow to do the same ; and we see the effect
in the rapid drying of ground over which the ‘wind has free course ;
while we see the effect of shelter in the continued humidity of the
ground wherever it is protected from the wind by a wall, a house, a
hedge, or a clump of trees.

To this effect of wind, and the modification of it produced by
shelter, reference is made in the before mentioned experiments and
observations made by Mr Blore.

It is stated by Mr Milne Home, chairman of the Council of the
Scottish Meteorological Society, in a paper containing suggestions for
increasing the supply of spring-water at Malta, and improving the
climate of the island, to which I shall afterwards have occasion to
refer at greater length, “ Halley found that, when water is kept in a
room, to which neither sun nor wind had access, the evaporation
amounted to 8 inches in a year ; but when exposed to sun and wind,
even in the cloudy atmosphere of London, it amounted to 48 inches
yearly. More recent and accurate observations make the natural
evaporation from soil kept moist not quite so much. Howard of
London gives, as the mean of eight years’ observations, 30 inches,
Dobson of Liverpool found, after four years’ observations, a mean
annual loss by evaporation of 37 inches ;—the least evaporation
being in December, when the temperature was 44°, the greatest in
July, when the temperature was 70° Dalton of Manchester found
that evaporation there was at the rate of 30 inches ;—the lowest
being 1:01 inches, in December, the highest 40-9, in July.

“ An instructive table was framed by Dalton, showing the number
of grains of water evaporated, from a given surface and during’ a

yo fs tits “SE Tye

rt
SHELTER TO WINDWARD. 57

ita

given period, at different temperatures, and with different velocities
of wind. The following extracts are made from this table :—

Temp. Fahr. Light Wind. Strong Wind.
50° 150 236
60° 210 333
75° 340 5-34
80° 40 629
85° 4°68 746

The shelter from drying winds, and the consequent protection
against rapid desiccation of ground, afforded by a wood, extends far
beyond the shade of the trees; and thus the prevention. of evapora-
tion by the wind becomes, in roost cases, of more importance than
the prevention of evaporation by sunshine.

Of the extent of such protection there are illustratious given by
Mr Marsh, in his treatise on the “Earth as Modified by Human
Action” (pp. 162-166), They are adduced by him in illustration of
the effects of forests on climatal temperature ; but the subjects are
correlated, and the statement by Mr Marsh will be afterwards given.

It is not only to leeward that the beneficial action of a forest
in giving direction to the wind is felt ; in some respects the calm it
secures to windward may be equal in importance to that which it
ensures beyond. Some years since a stage coach from the head of
Loch Long to Oban was usually driven by a coachman whose jests,
and jibes, and pleasantries, and humours, often kept the occupant of
the seat beside him, and the occupants of the seat immediately behind
in roars of laughter for miles. It is said that on one cold windy day
he had as occupant of the box-seat a Scottish Judge, one of the
-Lords of Session, who remarked in many places sheep crouching on
the windward side of whin bushes, aud after a time, calling the atten-
tion of the coachman to the circumstance, he asked him why they did
so. “To keep them from the wind, my lord,” was the respectful
reply. This called forth the unhappy remark. “If I were a sheep
I would lie down on the other side of the bush.” When forth came
without a moment’s warning the rejoinder, * Ah! but, my lord, if you
were a sheep ye wud hae mair sense!” The sheep and the coachman
were right. The beautiful curve of a snow-wreath shows what was
the course taken by the wind i in its formation and indicates the course

ws dU Ba

usually’ taken by it in surniounting a barrier; a long sweep on the

58 EFFECTS OF FORESTS ON HUMIDITY.

windward side, a comparatively precipitous fall to leeward. The
observatory erected by Sir John Herschel with a view to securing
calm for the immense tube of his telescope was erected in relation to
prevalent winds to windward, not to leeward, of Table Mountain.
And a calm prevails at Herschel and Bishop’s Court while the wind
is blowing strongly on the Flats, and pouring over the front of
Table Mountain like an avalanche,

‘To some to whom the fact may be new, it may prove corroborative
of what has been stated if I call attention to another fact, which has
been observed by others. In walking along the edge of a sea-cliff
facing the wind it has been found, when the breeze was slight or
moderate, that it was felt in full force up to the edge of the preci-
pice ; but when the breeze was strong, there was a breadth of perfect
calm along the edze of the cliff, while a little way inward the blast
was felt in all its fury,—the width of the calm being proportionate to
the force of the wind, the upward concave curve of the leeward current
passing into a convex curve carrying it over the head of the observer.

It is in connection with my advocacy of the conservation and
extension of forests at the Cape of Good Hope as a remedial measure
against the aridity—and progressing aridity—of the soil and climate,
that I have brought this subject under consideration. I am quite
aware that an argument in favour of the cutting down of forests,
woods, and trees, as well as an argument for the conservation and
extension of them by plantation, may be founded on the fact to
which I am calling attention. It is the case that there are places
in which the one operation may be as advisable as the other may be
in others : there are countries, in which woods and moisture are both
in excess, the clearing away of forests to a certain extent is advocated
on the very ground that their effects are such as I am endeavouring
to show that they are. But this only goes to strengthen my
argument and establish the fact which I am endeavouring to ex-
pound, irrespective of the practical application of it which may be
made by myself or others: that fact is, that belts of wood, and
fences, and forests, in their several degrees, acting as windbrakes,
retard both to leeward and to windward the desiccation of ground by
the evaporation promoted by drying winds.

Suor. III.—On the General Phenomena of Evaporation from Forests.

It appears to be unquestionable that by the shade which they
occasion, and by the shelter against drying winds which they afford,

PREVALENCE OF EVAPORATION. 59

forests exercise a considerable influence in diminishing the evapora-
tion of moisture from the soil; but, in connection with the con-
sideration of this, there should be taken into consideration the
general phenomena of evaporation from forests.

M. Cézanne in his Suite to Etude sur les Torrents des Hautes Alpes,
by M. Surell, remarks that “evaporation is for modern physical science
a phenomenon comparatively simple and well understood. Jt is known,
for each degree of temperature, what is the tension and what is the
measure of saturation of the air. But looked at from a meteorological
point of view the phenomenon is one of the most obscure; and the
limited number of observations which have been made cannot admit
of their being compared together.

“ What, in a given place, is the depth of water which is carried off
in one hour by evaporation? This varies according as the evaporating
surface specified may be drenched or only damp, be stagnant or
running water, be in the sunshine or shade, according as it may be
summer or winter, according as the air may be saturated or not, or
be more or less saturated, and according as the air may be at the
time windy or calm.

“ Two adjacent basins, placed in the same meteorological circum-
stances, evaporate unequal quantities of water if they be larger or
smaller, if their sides be more or less elevated, if they be sheltered
from the wind or not, etc.

‘When it is said that the annual evaporation at Rome is 2°462
willimétres, at Marseilles 2-289, at Paris 0-698, at London 0°754, at
Toulouse 0°649, at Copenhagen 0-209,* all that is meant to be said is
that in the circumstances in which the observers were placed they
have determined these results. But the mean annual evaporations
furnished for each place are far from having the same scientific value
as the mean annual rainfalls, which present on the contrary a specific
character. It may always be affirmed with certainty that evapcration
goes on decreasing from the equator to the pole, where, however, it is
far from being nil, even in the greatest frost ;t that it is more feeble
near the coast than in the interior of a country ; avd more feeble also
under the equatorial wind from the south-east than under the polar

* Vallés : Inondations, p. 23,
{ Hayes: La Mer libre du Pole, p. 224. Wet linen, exposed to the air,
dried at the lowest tmperatures ; and a sheet of ice, suspended
by a thread, evaporated away by little and little.

é0 EFFECTS OF FORESTS ON HUMIDITY.

cele

wind from the north-east—the former being saturated with moisture,
while the latter has been deprived of it.”*

And having stated what the effect of this is on the flow and
delivery of rivers, he goes'on to say,—‘If such be the important
part played by evaporation, it is evident that forests exercise an
appreciable influence on water-courses, according as they promote or
retard, to whatever degree it may be, evaporation. But in what do
they exercise this action? On this point the whole world seems to
be at sixes and sevens,

“Throughout all time the poets have sung of the cool shade—the
moist shade of extensive woods, A nave of verdure thrown over &
road keeps it moist, and as a consequence protects it or injures it,
according to the climate or the seasons. In every page of works on
forestry may be met allusions to the humidity, which is favourable
to the seedlings, and which the shade maintains.

“Tf any one entertain a doubt, let him follow i in the suite of a
forest-guard the day after a storm of rain ; when, although the open
country and a fortior: the roads are already dry, he may procure for
himself a cold bath in penetrating into the clumps of copse-wood.
At his feet the tall herbs are little better than a stream, and on his
head every shaken branch will pour down a douche, which will make
itself be felt.” And in explanation he adds in a foot-note,—“ Any
one may observe that on the leaves of certain vegetables, but not of
all, the rain-drops take a spheroidal form; in this state they resist
evaporation energetically, as one may see globular drops run about
on red-hot iron without ebullition, The foliage of other plants has
been dried for a long time, while these pearls sparkle still on the
herbe which bear them. Certain species preserve thus the rainfall
until the agitation of the leaves cause these spheroidal drops to fall.”

ud he goes on to say, “It seems then natural to believe that forests
oppose themselves to evaporation, and, consequently, acquire for the
ground the product of the rain. But objections are not awanting,

* Attention is called to the circumstance that the foliage of treads
arrests a notable portion of the water falling as rain. When a light
rain-storm follows some days of dry weather, it may be seen that each
tree casts a dry shadow, which on the wet ground of the road is
marked out by a dust-covered patch. The water arrested by the
leaves is lost to the ground underneath ; the tree or the air will
absorb it, and the importance of this is such as is not to be
overlooked. er a

* Schmit: Grundriss der Meteorologie.

EXPERIMENTS ON EVAPORATION, $}

“The Maréchal Vaillant has frequently drawn public attention
to forest hydrology. He instituted experiments to measure the
quantity of rain which is arrested by the foliage of trees ; and the
following : are some of the results he obtained ; the observations were
made | in the forest of Fontainebleau, during the | year 1866 :- —*

QUANTITY OF RAINFALL.
Under leafy woods

Months. Inopenair. of 30 years’ growth, Proportion,

millimetres, mn, mm.

January, ceeseeceeee 35 Gasaenn DAD isha ccionnpee or ‘70
February, ssecsesereasns TBD snscctotsnen G3 x saies casts dts eant ‘81
Marohy ics ssccoaners see BOB... eeeeeeeee DSiD cicccacosenvecses “72
APE iszadensmcralen: ae BT easteueees aes BO Os veaauanadenoesey 76
May; vcs cavanaaeadtucnes BGO issih oa BLD cadcswenetases paw 6B
OG: edeadascaeeieceert 66: avicwsseceors Bo) eiasdenes adsense 48
DULY asaitee: veewen age ens 105 8: cisscencene DOS icitaacisiessavecs 50
AUgust,...cccccerre WET. 2ealeceneane CO) cron iaatnoseatie 51
‘September,........... 1: ee OO cata sawnanee ‘51
October, ............44. DL" aeadaceucaels ASD seni dnivineG sates “45
November,............ AT D acdsee cee DY euoeiin ei dicee! si 62
December,............ Ge Oc eoule has AS Divesacsieae anand ‘70
859-5 524-7 0-60

“ From this it is seen that the leaves arrested in winter 30 /, in
summer 50%, and, on an average, throughout the year 40 /e of the
rain which fell.

“Under the Epicéas [Picea eacelsa, Link] of 35 years’ growth,
probably in dense clumps, the pluviométre received only 21% of the
years’ rain-fall: the tree arrested 797%. In a forest adjacent to
Versailles, the pluviométre, placed under a leafy wood, received 80%
of the year’s rain: the foliage arrested only 20%. Under a timber
forest of oaks, of from 70 to 100 years of age, the instrument
received 85% of the year’s rain,

“ Perhaps there may be ground for some little discussion in regard
to these experiments: the position in which the pluviométre might
have a marked influence on the results. Two instruments placed
under an umbrella, one towards the centre, the other at the cireum-
fereuce, under the droppiugs of the ribs, would give a bad measure-
ment of the mean fall of water on the soil.

* Revue des Eaux et Foréts. 1867. P. 161,

62 EFFECTS OF FORESTS ON HUMIDITY.

“M. Mathieu, sub-director of the Forest School, has undertaken a
series of experiments under very favourable conditious. Of these the
following is one which is particularly interesting, and one, the results
obtained by which scarcely agree with those of Marshal Vaillant.
Two udométres were placed at the forest station of Cinq-Tranchées,
the one in the open wuod, under a patch of beeches and hornbeams,
of average denseness, and of the age of 42 years; the other, at a
little distauce, in the middle of an open space many hectares in
extent. It may be well to note that the forest udombtre is of special
construction ; that the receiver embraces the stem of one of the
perches of the clump, and presents a surface quite equal to the
projection of the top of the tree ; that by this means the indications
of the instrument are quite exact, and represent well, without
exaggeration or diminution, the depth of the sheet of water received
by the wooded ground; and that this water, dropping from leaf to
leaf, passes through them, or flows down the truuk.

“ Under these conditions the udomttre gave, in 1868, the following
quantities of rain :—

MEASUREMENT OF RAIN.

Months. Under wood. = Outside wood. Proportion.

millimetres. mm, mn.
January,..cseceeeeee BS) cesacansmnnet 15 Beene re 0-931
February,...... 00. Dicken claeseehle DO <sdeisermesuteoiat 1-025

March, ......csccseeeee D Olisiecnas ave nian DO puseanennseres 1
April,....csccecceseeees GM cocucincaapant (Siseaveccemtney’: 945

May,...... die snst Mediates 8 se ieaaniommtea ee Soessrancasaesen 1
JONG; veiceenissinnsns swank OB asnesomseweceend aneeves ve aioe 923
Full eircorenionsiageis sah leaecegatent 2 a a ‘911
August,.....cccccceeee 2Gevaswerenervers Ol aisdiivuas vanbows 702
September, ........... DO sanieseateceess 61..., seeee "962
October,............5 TUS ariceenees LD vsaamiigeas 967
November,............ Dr sda dsien aaaes 28 wicianuesevorve 928
December,........... TOS sisidvevee <a UTS cess tboaensnies, 936
Total, 703 749 939

“Tt may be astonishing to see in the table that during the months
of February, March, and May the sheltered pluviométre received ag
much or more rain than the pluviométre in the open space; it is
necessary to consider that, either through sorne caprice of the rain,
or by some such effect of the trees, there fell more water in the wood
than in the adjacent open space, This result, moreover, might

PROPORTION OF EVAPORATION, 63

explain itself quite naturally, and without calling in any special
action of vegetation, if the open space were less accessible to the
rainy wind than was the wooded clump.

“Tt is worthy of remark that the mean proportion between the
two instruments, which was 0-939 for 1898, had been 0:938 for 1867,
and 0-952 for 1866: that is to say, that the proportion varied very
little.”

Along with the allowance, which it may be deemed necessary to
make for the quantity of rain which may be arrested by the foliage
and evaporated thence without reaching the ground, in a rough
estimate of the benefit which trees may bring to the soil by
preventing evaporation thence, it may be deemed necessary to make
some allowance in certain circumstances for the evaporation, through
the stomates of the leaves, of moisture which is dissipated in the
atmosphere, if this be in excess of the difference between what is
evaporated from the soil under the shade and shelter of the wood and
what is evaporated from adjacent open country.

I am disposed to question whether such a case be of frequent
occurrence, or if it be likely to occur at all, but the possibility of its
occurrence must not be ignored. I cannot do more than refer to it
to show that it is not ignored by me.

In a preceding section I have referred to the observations of Mr
Blore on evaporation, under shade and shelter, and in open ground,
at the Cape of Good Hope ; and in connection with a uotice of these
observations I had occasion to cite some experiments on evaporation
made by M. Mathieu. A report of these was published by the
French Government in the “Atlas Météorologique de I’ Observatoire
Imperial, 1867,” from which it appears that, during the seven months
comprised between April and October in that year, whilst the
quantity of water evaporated from forest leaves was 3.23 inches, the
quantity evaporated from land clear of forest was 16.29 inches, or
about five times as much.

In April, before the development of leaves, if 1,000 represented the
evaporation from the open country, 623 represented the evaporation
from woodland ; but after the trees became clothed with foliage the
amount of evaporation from the woodland was only 130, as against
1,000 of open country evaporation. In October the woodland evapora-
tion was to the open country evaporation as 90 to 100.

The experiments were continued in 1568,

64 EFFECTS OF FORESTS on N HUMIDITY.

tm

At the station of Belle-Fontaine, M. Mathieu measured the evapora-
tion by means of vessels exactly comparable placed outside of a wood,
and under aleafy wood. During the months of January and February
no observations could be made on account of the frost. Bat i in ‘the
Sc months the following results were obtained :— ~

WATER EVAPORATED.

Months. Outside the wood, Under the wood. Proportion,
millimetres. mm. mm.
March,........... Semen D Divan vine sicsemeens D evsiGisavieieaeaens 3.66
Aptil, esesesencaessssisae Qssessmanees ses Ls casaresekcntise xs 2.63
MAY jwnewnandieaans vee LOD Hesssicrsmaaingeess DD voeies cedrwiniwecas 4.56
JUNC) soe veeavesvierscare 107..... ecm areas 1 Oeste saciequaumnrns 5.63
DULY, sicsinet eadumsrn ceases DOs cxawasteamaens LO ps twecnaiavnesoes 9.50
August,.....ccececeeee WD avian deatwanieed Siac saanine cemsenves 9.37
September,...........5 DO wiena rae aemnense Llivssatieenewascaees 5.
October,........ssceeees 2 asetctine devine anes D:iaaissunesnciesteet 4,
November,...........00 Dueiieanowaeontew Ov ccdeua ste caaued 9:
December,...........06 Diesisialesierdaisgad den WT sais odie Seawactensn 2,
Totals, 542 106 5-11

From this it is seen that during ten months in 1868 the evapora-
tion was more than five times greater in the open space than it was
in the forest, which consists of high perches, dense and close, of horn-
beams, beeches, oaks, and ashes of sixty-two years’ growth.

There are cited by Marsh some valuable observations by Risler on
the evaporation from cultivated soils and the exhalation and exuda-
tion of humidity by field plants and forest trees, given in the Archives
des Sciences (Bibliothéque universclle de Genéve) for Sept. 15, 1869;
March 25, 1870; and Nov. 15, 1871, which seem to lead to ae
general oondlusien, that forests evaporate less than an equal extent of
pasturage, and that if we suppose a mean precipitation of two and a
half millimetres per day, of which two millimetres penetrate into the
soi), the forest takes up less than one half of this supply, the re-
mainder descending into the sub-soil and percolating through earth
‘ and rock until it issues in the form of springs, He found an evapora-
tion of one and one tenth millimetre per day to be the maximum from
a forest of firs under exceptionally favourable conditions of a fertile
and humid soil and abundance of sunlight.

Risler, in the experiments referred to found that in 1867, not far
from Geneva, no water escaped from a parcel of ground thoroughly

MOISTURE ATTRACTED BY MOTLD. 85

underdrained at the depth of 1> 25, in tie months of July, August,
September, November and December, and but a very trifling quantity
in June and October ; in _ ><>. very little m May and September and
none in June, July and Auznus:. In 15457 the total precipitation was
1066.4 millimetres ; the evaporation, as measured by the difference
between rain-fall and drainage, 133.44 millimetres; in 1868, these
quantities were 1032.36 and 755.74 millimetres respectively.

AML Cézamne remarks im rezard 1» all the observations c::<d by him,
— In conelusion, and with every allowance for the small quantity of
water which is réeca'ned by the leaves, the foregoing observations
strengthen <b: conclusion that, under the same measure of rain-fall,
the soil of the f.r<s< recetves and retams notably more water than
does uncovered ground.

Secr. IV.—On Moisture being Attracted from 2 “2 Atmosphere, or other-
wise retained in the Ground by Vegetable Mould.

Tke mece:rological effects of forests are, as has been intimated,
gomewhs: complicated, and the s<2icnt of these availing himself of
my guidance may be begmmmg +» perceive something <f the compli-
caticn in which they are ‘nvslved ; Ca: thus far =h: unravelling sf
diff-r=: strands has been found to be tracticable. and this operation
may be carried s littl: further «:-L><: difficulty.

A distimction has been drawn between the effects produced on the
ground by the =hid< from sunshine, and by the shelter from drying
winc: afforded by trees and forests. It is necessary, further, to

istirgnish between <1: ecfecs produced by shade and by vegetable
mould, which ezis<s always, in 124-21 or less quantity, in f-rest soil,
im consequence oi th: decay and decomposition of fallen leaves and
ang fallen twizs, and broken or decaying ro-lezs.

In the soil of a forest there generally =<s-s more moisture ~hin
cax be attribut=d to shade, or to shade and :4<it=r cosmbimed ; and
reoch of this is attributable to <he attraction of t«-isture manifested
by this vezetacle mould.

By a series of <i:nple experimen-s ~his fact may be dem sascrated,
the quantity sf miiscare isterciced, and the proper‘ion «t-rbutable
to each of the ¢Zcts menvcned pis aaa ascertained.

Take tre weight ofa condred zrzics or of a hundred drams, or the
weight of a hundred =: of uniform may abite eee

66 EFFECTS OF FORESTS ON HUMIDITY.

of a forest, sheltered and shaded by the trees, and expose it for some
hours to the bright sunshine ; after this weigh it, and most probably
it will be found to have lost weight. This loss will have been
occasioned by the sunshine and open air having caused an evapora-
tion of moisture from the soil, though it appeared to be dry, and the
quantity of moisture so evaporated may be determined by the
weight lost.

Take again the same weight of such forest soil, so dried in the air
and sunshine, and of such dry gravelly sandy soil as you may find on
the road, similarly exposed to the drying influences of the air and sun-
shine; expose them together on papers for an hour in an oven heated
to such a degree that the papers will be browned,-but not burned ;
weigh them again, and probably both will be found to have lost
weight, but the loss of weight sustained by the soil taken from the
forest will probably greatly exceed the loss of weight sustained by
the soil taken from the open field. The loss of weight is occasioned
in this experiment, as in the first, by loss of moisture contained in
the soil, notwithstanding that this was sun-baked and apparently dry.

Had the papers been burned there might also have been burned
organic, vegetable, or animal remains in the soil, occasioning a
loss of weight in addition to that occasioned solely by the loss of
moisture, for which allowance must have been mace; but this has
been avoided by the precaution adopted. And ths heat prescribed
was to be such as would brown the paper without burning it, to
secure as great a heat as possible short of what would have done
more than merely drive off the moisture contained in the soil. And
if the loss of weight sustained by the soil from the forest so exposed
be in excess of that sustained by the soil taken from the road, this
indicates that it, when apparently dry, contained more moisture than
did that other, which excess was attributable to moisture held fast
by products of vegetable decomposition in the soil.

But this is not all. If equal portions of the two parcels of
thoroughly desiccated soil be spread out on glass, and exposed for a
day or two to the atmosphere, protected from rain or dew (within
doors or without, in a dry room or in a cellar), and these be then
again weighed, they will be found to have gained weight, but in
different degrecs, much more having been gained by the forest soil
than by the sandy gravelly soil of the road. This will be done by
their imbibing moisture from the atmosphere, dry as that atmosphere
seemed to be; and the proof is forthcoming: expose them again in
an oven as before, and the weight gained will again be lost,

PHENOMENA OF DELIQUESOENCE. 67

In this effect of vegetable mould we see how forests may
exercise a third influence, over and above and distinct from both
shade and shelter, in maintaining a humidity of soil.

This matter may deserve a little further consideration.

In treating of Reboisement in France, I had occasion (p. 95) to cite
certain experiments made by Thurmann, made with a view to ascertain
to what extent different minerals could absorb and retain moisture,
and to state results obtained by him showing that cubes of different
minerals thoroughly dried, weighing each 100 grammes, immersed in
water for five minutes, varied in the quantities absorbed by them
from half-a-gramme to from 10 to 30 grammes.

These results have been considered indicative of the absorption of
water being proportional to the state of molecular sub-division of the
material comprising the rock, and they have been resolved into dis-
tinct phenomena—hydroscopicity and capillarity: the former, the
power of each molecule of the rock to retain around it a layer of
moisture difficult to withdraw ; the latter, the power of structures of
molecules of earth to retain in interstices by which they are separated
small globules of water. And thus may the results obtained by the
first-mentioned experiments be accounted for. They indicate greater
hydroscopicity and capillarity to be possessed by the soil of the forest
than is possessed by gravelly and sandy soil of the road—this being,
as may afterwards be proved, an effect or consequenee of forest pro-
ducts embodied in that soil.

But besides substances which manifest capillarity and hydroscopicity
there are substances which attract and abstract moisture from the
air, some of them doing so to such an extent that they deliquesce or
dissolve in their own brine ; and unless the air be kept excluded from
them, or they be kept in a warm place, where the heat will either
keep the air comparatively dry, or evaporate the moisture attracted
and absorbed by them, you cannot keep them dry. This is signally
the case with the carbonate of potash—the potash of commerce ; it
is manifestly the case with chloride of sodium, or table salt ; it is
also the case, though less manifestly so, with clay; and to a very
marked degree is it the case with humus, the product of the decay
and decomposition of vegetable matter, and une which abounds in
forest soil from the fall of leaves and twigs.

To this humus mainly may be attributed the great attraction of
the forest soil for moisture, indicated by the gain of weight when,
after being thoroughly desiccated, it is exposed to a dry atmosphere ;

68 EFFECTS OF FORESTS ON HUMIDITY.

.

and to the great quantity of humus in that soil, the excess of the
quantity of moisture absorbed from the atmosphere over the quantity
absorbed by the dry gravelly sandy soil taken from the road.

The quantities of humus and the quantities of clay, which exercise
similar power, though not to the same degree, in each of the parcels,
can easily be determined.

It may be noted that what is now spoken of is not the deposit of
dew, which depends on a reduction of temperature.

Wherever the difference of temperature between day and night is
great, and the atmosphere is heavily charged with moisture, the

: deposit of dew is considerable. In England, Luke Howard, with a
well-constructed rain gauge, found the deposit of dew in one night
towards the end of September equal to ‘01 inch of water; and in
the last six days of October he obtained ‘11 of an inch from copious
dews and mists, ,

In Algeria, at the stations on the coast, writes Steinmitz, in a
little volume entitled “ Sunshine and Showers,” after the driest and
hottest days, immediately the sun has set, the soldiers’ uniforms
become wet with dew, and in a single night the blades of knives in
the pocket become rusted.

But apart from this deposit of dew, moisture is absorbed from the
atmosphere by the soil. The driest soils contain 13% of moisture.
It has been determined by experiments by Schubler that when a
soil, which weighs about 1000 tons per acre, is pulverised so as to be
freely permeable by the atmosphere, and is exposed to the air after
being thoroughly dried, it will absorb in twenty-four hours, if a sandy
clay, what is equal to 26 tons of water; if a loamy-clay, 30; if a stiff
clay, 36 ; if garden mould, 45.

Cézanne states that, “ In the Roussillon, rain is a rarity ; the in-
habitants can recall periods extending over a year without notable rain;
and that the littoral hillocks behind the buttresses of the Pyrences
are of a very permeable limestone, but the vine flourishes in this
region, the leaves cover the rocks with verdure, and the grapes swell
with a savoury juice, while along the dusty roads the grasshopper
follows the traveller with its cry, the emblem of aridity and drought,

“Tt is certainly not from the soil devoid of humidity that the vine
drinks its supply, it is from the atmosphere; and the vine-growers
do not deceive themselves—it is not for rain that they look, they
know that hope of this would be vain—they cry for the sea breeze,
which will perfectly satisfy them.

MEASURE OF MOISTURE IN SOIL. 69

“On the other hand, in the palus of Bordeaux, the vine is seen
growing, so to speak, with its feet in the water.

“Tt is then probable that vegetables, or at least some of them, are
endowed with an eclectic power ; they take water where they find it,
they distil away subterranean water when it is in excess, and they
know also how to condense and absorb water from the atmosphere.”

I accept the facts, but demur to the reasoning. I think all can be
otherwise accounted for. M. Cézanne cites in a foot-note, in illustration,
the description given by Mr Thomas Baines of the Markwhe, a large
watery root, measuring in its greatest circumference 40 inches and
in its smallest 30, with the statement of Mr Baines that when he and
his party, travelling in an arid district of South Africa, felt thirsty the
Bushmen would pull up some of those roots, and by eating of them they
would quench their thirst. I have heard of several different kinds of
such juicy plants growing in the most arid districts of South Africa ;
but never have I heard anything in regard to their natural history,
or their structure, which would warrant the conjecture advanced ;
while the proved affinity of soil for moisture supplies a satisfactory
explanation of all the phenomena referred to.

From experiment and observation it has been deduced that pure
sand has little affinity for moisture; but that such affinity is
manifested both by clay and by humus in a high degree, and to
these conjointly may be attributed the attractive affinity of the soils
for moisture, indicated by the gain of weight in the second set of
experiments, when the desiccated soils were exposed for a long time
to the air.

To this affinity of soil for moisture attention is given in analyses
of soil in agricultural chemistry. It is in general inversely propor-
tionate to the proportion of sand, and directly proportionate to the
quantity of clay in.the composition of soil taken from the open country,
in which these constituents greatly preponderate; but it is also
proportionate in a much higher ration to the quantity of humus in
the soil, and the quantity of this can easily be determined.

If the two parcels of earth last referred to as subjects of experiment
be raised to a red heat in iron spoons, and after all appearance of
brighter incandesence in portions of the mass has ceased, they be
weighed, care being taken to remove all scales of iron or of iron rust,
they will again be found to have sustained a loss of weight ; this is
attributable to the combustion of organic matter, most of which was
humus, or capable of becoming humus, and the loss sustained by the
forest soil will be found much greater than the loss sustained by the

70 EFFECTS OF FORESTS ON HUMIDITY.

‘other. In the case supposed, the affinity for moisture will be found
to be proportionate to the different results ; but it may be modified
by the proportions of clay, if in either this be greatly in excess—and
this also can easily be determined.

If the two parcels of soil be next drenched with hot water, and this
poured off when discoloured with the muddy matter suspended in it,
and the process be repeated until the water comes off limpid, upon their
being again desiccated in an oven, as before, and weighed, the loss
they have sustained in weight will indicate the quantity of clay which
was in their composition, together with free soluble salts, the quantity
of which may be little or may be much. Thus will have been re-
moved all the materials manifesting a marked affinity for atmospheric
moisture; and in few cases, if any, the results greatly modify the con-
clusion arrived at by the removal of the humus and its constituents.

I prescribe not these proceedings as certain to give precise results,
in absolute accordance with the actual constitution of the soils made
the subject of experiment, but as rough and ready experiments which
may be made by the inexperienced, the results of which will indicate,
and to some extent measure, the property of forest soil not only to
retain moisture, but to attract moisture from the atmosphere in a
superior degree to that in which such property is possessed by the
gravelly and sandy soil taken from the highway.

Should any one desire more accurate results, the following course
of procedure may be followed :—

1, Ascertain the quantity of moisture in the apparently dry soil
by the mode of desiccation described, weighing the soil before and
after the operation.

2. Ascertain the affinity for moisture by lengthened exposure of
the desiccated soil to the air anywhere, and subsequently weighing
it to learn what it has gained.

3. Ascertain the quantity of organic matter in the soil by heating it
to incandescence as directed, but dcing this in a plantinum crucible,
previously desiccating it as before, and weighing it before and after
this third operation.

4. Drench it with spirit of salt, muriatic acid, or hydrochloric acid,
as it is now generally designated, adding soft water, and continuing
the operation till all effervescence has ceased. Drench it then with
water; let it settle ; pour off the water when Jimpid ; desiccate as at
first, and weigh: and the loss of weight will then indicate the
quantity of lime which was in the soil.

DECOMPOSITION OF HUNTS. 71

5. Ascertain the quantity of clay by the operation described.

6. By sifting the residuum through a piece of fine muslin, the sand
may be separated from the eravel, and the quantity of each deter-
mined by weighing them apart.

A comparison of the results will show the difference in the com-
position of the two szils—and in none of the constituents will the
difference be more marsed than in the orzanic constituents and in
the sani anal gravel; th2 form2r, compose] mainly of humus or the
constituents of humus, having a great affinity for moisture, being
greatly in excess in the forest soil, and the latter, having little or no
affinity for moisture, being alinost awanting.

This humus is a product of vezetation, inasmuch as it is a result
of the decay and decomposition of vegetable prolucts ; and it is not
only not decreased but it is constantly being incrers2d by vegetation.
Under no crop is this more manifestly the case than under a crop of
deciduous trees. For this the annual fall of the leaves enables us
without difficulty to account. The shelter afforded by a wood pre-
vents both the fallen leaves, and the dust to which they may be
reduced, from being borne away by the wind, and the shade prevents
the humus from being so decomposed as to be carried off by the air.

With the smaller quantity of humus in the soil not protected by
shelter and shade, it is otherwise. What there occurs is thus stated
in a paper I had occasion to cite in treating of the effect of de-
nudation of the country on the hydroscopicity of the soil,* a paper
on the philosophy of arboriculture, by the Rev. Dr Macvicar, of
Moffat, who was the first editor of the Quarterly Journal of Agri-
culture, issued by the Highland and Agricultural Society of Scotland,
and who subsequently resided in Ceylon, where he had opportunities
for prosecuting researches upon which he had previously entered.
The writer remarks, in regard to effects following the destruction of
forests,—“ The soil when stript of the clothing which the forest
afforded, and exposed naked to the heat of the sunbeam, changes very
rapidly from the rich mould which the long-continued fall of the leaf
in the forest had made it, and becomes very unproductive. Had
occasional trees in the forest been left to give shade during part of
the day, the destination of the carbon in the mould would have been
to have been slowly converted into carbonic acid, and so to supply
food to the successive crops growing on the soil, as they required it.
But when the sunbeam is left to break in its full force on the soil all

* “ Hydrology of South Africa” (p. 213).

72 EFFECTS OF FORESTS ON HUMIDITY.

day long, it burns the carbon in the soil with great rapidity into
carbonic acid ; and this gas, unless there be in the soil some oxide
having an affinity to it to retain it, goes off in gas, injuring the
salubrity of the air perhaps, and at all events wholly impoverishing
the soil,—for carbonic acid is the principal food of all plants. The
same course of things it might be shown happens with regard to
ammonia ; and thus, both as itself the immediate food of plants and
as that which by oxidation yields nitre, ammonia is lost. Thus the
indiscriminate destruction of forest over any great breadth of country,
if that country has plenty of sunshine, is a great evil.”

In correspondence with Dr Macvicar on the subject, he wrote to me,
—‘ As to the point to which you refer—the rapid generation in the
soil, and the vaporization from it of ammonia and carbonic acid,
under the impact of the tropical sunbeams and breezes—I do not
remember to have seen it dwelt upon by any writer, though both in
the writings of Boussingault and of Liebig it is implied ; and it is an
inevitable consequence of the eremacausis, or the slow combustion of
organic matter. It is familiarly verified by the process of bleaching.
Even with such sunshine as we have in this country the organic
matter which imparts colour to tissues is carried off much more
rapidly in the sunshine than out of it; and it can only be carried off
as carbonic acid and ammonia : that is, it is not merely changed from
coloured to colourless, as is proved by the loss of weight which the
web has sustained when it is bleached. In this country we have
generally less sunshine than-we require, and, except in fallows, the
surface of the soil is never left bare. Hence the effect of the impact
of the sunbeam has been but little considered. But from what I
have observed in the tropics, I am persuaded that its power of
affecting plant food in the neighbourhood, by the destruction of the
fertility of every surface that is left bare, is very great. It intensifies
to a wonderful extent that action of the incumbent atmosphere by
which the carbon and hydrogen in the soil unite with the oxygen and
nitrogen of the air, and give moisture, carbonic acid, and ammonia
almost immediately after, if they be not utilized on the spot where
they are generated, dispersing all but that quantum which the soil
can retain at a temperature of perhaps 140° or 150° F., which is
not much,”

CHAPTER IItl.
ErFects oF FoREsTS oN MarsHeEs.

Ix studying the effects of forests on marshes there come under con-
sideration the drying up of marshes by the growth of forests, the
occasonal appearance of marshes on the destruction of forests, and
also the occasional destruction of forests by the creation of marshes.

The combined consideration of all of these phenomena may be
necessary to a satisfactory view of the first ; but this is susceptible
of satisfactory explanation by itself, and the second may be con-
sidered to be confirmatory of the first, and the third not otherwise
than accordant therewith.

And by the consideration of these several phases of the correlation
of forests and marshes, we may be prepared for the consideration of
the effect of forests, in drying up marshes upon a grand scale through
protracted ages, in rendering what was a marshy land so dry as to be-
come a fit habitation for man, of which Denmark supplies an illus-
tration.

Sect. ._—On the Drying up of Marshes on the Growth of Trees.

We have latterly been considering the effect of arborescent vegeta-
tion in preserving the humidity of the soil ; but we had previously
been considering the effects of forests in increasing the humidity of
the atmosphere ; and previously to that we had under consideration
the phenomena of vegetation on which meteorological effects of forests
affecting humidity of soil and atmosphere depend: moisture being
withdrawn from the soil by the spongioles of the root, trausmitted by
the trunk to the branches and passed off into the atmosphere by the
stomates of the leaves.

It may seem paradoxical to speak of forests both drying up marshes
and keeping the soil moist ; but it is not more so than to speak of a
man blowing both hot and cold. There is a great difference between
moist soil and marsh. All moisture in excess of what can be retained
by shelter and shade and humus in the soil is free to be otherwise

74 EFFECTS OF FORESTS ON MARSHES.

disposed of, and the effect of forests in drying up marshes, viewed as
an isolated fact, may be proved as satisfactorily as any of the effects
of forests which have been under consideration.

I have already alluded to this effect in stating that the allegation
of the South African farmer, that the trees stole the water from the
water leadings, by the sides of which they were planted, was not
altogether without foundation, though the phenomenon on which his
opinion was founded was one which did not prove this, but proved
something very different.

We have had under consideration the fact that very extensive pro-
vision has been made for the evaporation of water from the leaves of
trees: in the case of one tree, the Lilac, so many as 160 thousand
stomates being found on every square inch of the under surface of
the leaf. Whence is the moisture to be so evaporated obtained?
Mainly and almost exclusively, if not entirely so, from the ground.
It seems to follow that what the atmosphere thus gains the earth
must first loge, even though a portion of it may be subsequently
restored. And the quantity thus raised from the ground and given
forth to the atmosphere is very great.

Mr Marsh, whom I have already quoted elsewhere, states :—“ The
present estimates of some eminent vegetable physiologists in regard
to the quantity of aqueous vapour exhaled by trees and taken up by
the atmosphere are much greater than those of former inquirers.
Direct and satisfactory experiments on this point are wanting, and it
is not easy to imagine how they could be made on a, sufficiently
extensive and comprehensive scale. Our conclusions must therefore
be drawn from observations on small plants, or separate branches of
trees, and of course are subject to much uncertainty. Nevertheless,
Schleiden, arguing from such analogies, comes to the surprising result
that a wood evaporates ten times as much water as it receives from
atmospheric precipitation. In the Northern and Eastern States of
the Union [America] the mean precipitation during the period of
forest growth—that is, from the swelling of the buds in spring to
the ripening of the fruit, the hardening of the young shrubs, and the
full perfection of the other annual products of the tree—exceeds, on
the average, 24 inches. Taking this estimate, the evaporation from
the forest would be equal to a precipitation of 240 inches, or very
nearly 150 standard gallons, to the square foot of surface.”

Startled by this, he questions the correctness of the conclusion at
which Schleiden had arrived ; but he states in a foot-note :-—“ Pfaff,
too, experimenting on branches of a living oak, weighed immediately

EXHALATION OF MOISTURE. 75

after being cut from the tree, and again after an exposure after three
minutes, and computing the superficial measure of all the leaves of
the tree, concludes that an oak tree evaporates, during the season of
growth, eight and a-half times the mean amount of rainfall on an
area equal to that shaded by the tree.” Corresponding observations
made by others are not awanting.

Marshal Vaillant writes :—“ Even the most humble plants, such as
chickweeds and meadow grasses, evaporate considerable quantities
of water. Independently of all the other actions, which ought not
to be overlooked, this is the chief cause why the abundant summer
rains make so little impression on our rivers. This is why the
gardener uses the hoe so carefully, and why he removes all weeds
which would exhaust the moisture of the soil.

“ The intelligent gardener is not deceived, he knows that if any
weed has long numerous roots, like the éritiewm repens (couch grass),
they do more harm than others, because by spreading to a distance
they deprive a larger extent of ground of its share of moistnre. This
is why a paillis, although on account of its dark colour it becomes
sooner warm than turf or other grass plants, does so much good to
cultivated vegetables, by not depriving their roots of moisture.

“The quantity of water exuded by rapidly-growing plants is far
greater than could be supposed possible by people who have not made
direct experiments ; it is especially plants of soft texture with hollow
stems that excite our surprise. A branch of helianthns annuus (a
sunflower), placed in a caraffe full of water, and exposed to the sun,
exhausts the water very rapidly; thus this plant, with its far-
spreading roots, is a very dangerons neighbour to others, and we may
be thankful that the passage of water into the roots does not go on so
quickly as the evaporation by its leaves, otherwise the exhaustion
caused would be much greater than it really is. It is this difference
between the quantity of water transmitted from the soil to the roots,
and from the leaves to the air, that causes the latter to wither in warm
weather. Rain does not penetrate the leaves, but only diminishes
their evaporation, so that an equilibrium is re-established.

“Tf from herbaceous plants or modest shrubs we turn to our large
forest trees, we may expect that, compared with the weeds of which
we have just spoken, they will transpire a great quantity of water,
which is probably in proportion to the number of leaves and their
extent of surface ; and it is our belief that this summer function of
the leaves is carried on by the trunk and branches during the whole

76 EFFEOTS OF FORESTS ON MARSHES.

year. Of the energy and rapidity with which water ascends through
the trunk of a tree, the operation called boucherie, for the preservation
of timber, affords a remarkable example. In a very short time a
peisonous liquid is transmitted from the base of the trunk to the ex-
tremity of the branches.

“From whence comes the water so rapidly transpired by the
foliage? Certainly from the soil; and as the roots of these vegetable
giants penetrate far—as some say, in some cases, to the same extent
as the branches—it is easy to understand how the ground becomes
dried up and incapable of supplying nourishment to plants of smaller
growth.

“Tt is therefore impossible for anything to thrive close to, or even
at a considerable distance from, the root of a tree. It is not only the
shade and the want of rain that hinders growth: indeed, plants at
some distance from a large tree are as much shaded as are those
close beside it, and the rain, which seldoms descends vertically,
always moistens such plants more or less, they are also refreshed by
the dew, and, nevertheless, they die or languish. It is because they
grow in a soil which is always dry and deprived of nourishing power.
Certainly the invitation addressed by the oak to the reed in the fable
bespeaks a good disposition ; but had it been accepted the poor reed
would soon have died of thirst. Its tall and powerful protector
would soon have dried up the damp borders of the kingdom of the
wind, which nature has appointed as the habitation of reeds.

“ Whoever has uprooted old trees must have remarked to what a
great depth the earth around the roots is exhausted and dried up.
This state of things can be easily acounted for, after the particulars
of the following experiment may have been read.

“We placed in a large jug of water, as tightly closed up as possible
so as to hinder the effect of natural evaporation, the end of an oak
branch, 1” 40 centimétres [nearly 5 feet] long, and 4 centimétres
[nearly 2 inches] in circumference at its lower extremity. The
branch was cut off from a tree about 25™ [upwards of 80 feet] high,
add 2™ 63 centimetres [about 9 feet] in circumference at 1™ [40 inches]
from the ground

After twenty-four hours’ exposure in the open air at a temperature
of 15° 7” [60° Fahr.] at the minimum, and 25° 7’ [77° Fahr.] at the
maximum, the water in the vase diminished 510 grammes [18 oz. ].
The sun was shining brightly. In forty-eight hours from the be-
ginning of the experiment the water in the jug had again lost 300
grammes [10} 0z.] of its weight, The sun had been very warm, the

EXHALATION FROM LEAVES. 7

thermometer having risen toa maximum of 27° 7” [82° Fahr.], the
minimum having been only 10° 7” [57° Fahr.] ; the wind on this day
and the preceding had been from the north or north-east. Seventy-
two hours after the introduction of the oak branch into the water the
vase had again lost 140 grammes [5 oz.] of its weight. The weather
had been as lovely as the day before, the minimum of the temperature
having been at 12° 5” [54°] and the maximum 25° [77°]. Thus the
weight of water evavorated by the branch was, at the end of the first
day, 510 grammes, at the the end of the second, 810, and at the end of
the third, 950 [30 ounces]. The experiment was not carried further.
In the first place, because several of the leaves were withered and
incapable of performing their functions ; secondly, because the water
in the jug was beginning to be affected by being mixed with the sub-
stances which always are deposited by plants when placed in water.

“Tf we believe that all the leafy parts of a tree will act, as regards
the faculty of transpiration, like the leaves of the above-mentioned
branch : in other words, if we suppose that the quantities of water
expired by the entire tree were in like proportion, we arrive at the
astounding result that an oak like the one described will, in a summer
day, cause the evaporation of more than 2000 killogrammes of water,
more than two cubic métres, [or 440 gallons].

“ We are not decided in regard to the value of our experiment, and
we see very well that our deductions are not free from objections ; but
it must be allowed that supposing that every one-half or one-quarter
of the estimated quantity be omitted, the quantity must greatly
exceed what might have been expected. ‘

“ A forest should produce on the soil which it covers‘the effect of
a large umbrella pierced in many places, it may be, but, nevertheless,
arresting and imbibing a certain quantity of rain, of whieh it deprives
the neighbouring soil, So long as the leaves are imperfectly soaked,
no moisture reaches the ground ; and it can be easily imagined that
a moderate continuous rain would be entirely absorbed by natural
evaporation, and in effect the humidity of the air, even in damp
weather, never reaches the maximum of the hygrometer in the lower
atmospherical strata, and evaporation is never entirely suspended.

“If we further add to these causes of exhaustion that there is little
dew deposited under trees, it can be believed that the ground of a
forest is less favoured as regards the quantity of moisture received
from the heavens than that which is exposed to the open sky.

“ And, nevertheless, it is an accepted fact, and that not without
good reason, that. the neighbourhood of forests is cold and damp.

78 EFFECTS OF FORRESTS ON MARSHES,

This is far from astonishing when one thinks of the enormous volume
of water transformed by forests into vapour, and the quantity of heat,
absorbed in this transformation. This heat must have been obtained
somewhere—perhaps from the soil of the forest and that of the
neighbourhood.

“Tn the same way, there should be great damp in the neighbour-
hood of forests, especially when the temperature is high, and it
cannot be otherwise on account of the enormous amount of water in
the form of vapour which is discharged by forests into the adjacent
atmosphere.

“This vapour is emitted in much greater abundance during the
day than during the night. Towards night, a little after sunset,
when the general temperature begins to fall, the transpiration not
yet having had time to slacken, and ascending into a colder air,
changes into visible fog, like our own breath in like circumstances
and this fog in its turn becomes a cloud on the following morning,
when the sun warms its particles ; but whether clouds or fogs they
will be carried away by the first breeze, to descend in showers far
from the place of their birth.

“Tt is evident that the rain of these showers, pumped up, in the
first place, by the tree-roots from the forest soil, if it be sometimes
restored to this soil it is only in part; so that even in this respect we
can assert that, with regard to water, forests place the soil in a much
worse position than a crop of cereals.

“Tf these details as to the formation of forest-fogs be correct, such
fogs should be more frequent in calm weather, when the air is
naturally more moist, and especially when the contrast is greatest
between the cool of the evening and the heat of the day. The test
of conditions for the formation of thick forest-fogs is especially com-
plete, at least in our climate, towards the end of summer and the
first half of autumn ; and it is during this period that the phenomenon
is most frequent and noticeable.

“Tf the transpiration carried on by the leaves were coloured and
perceptible, it would be a grand sight to see great columns of vapour
ascending majestically into the air, diminishing by their height the
distance between the tops of the trees and the stormy clouds; and as
this vapour facilitates the passage of electricity, by increasing the
moisture of the air with which it mingles, the frequency with which
isolated trees are struck with lightning can be accounted for. Per-
haps, also, if attention were turned to this point, the reason would be
discovered why so many people, taking shelter under trees, are struck

EXHALATION FROM LEAVES. 79

by lightning. It is diffioult to refuse to believe that these people
were not more exposed to danger in such a situation than if they had
remained in the open field.”

These statements I give as the views advanced by Marshal Vaillant.
There are points on which my own views are somewhat different; but
with regard to the grand fact, that the emission of moisture by the
leaves of the forest is very great, we are at one.

With what is known of the affinity of humus and of clay for mois-
ture, it may be considered probable that not a little of the moisture
evaporated by the stomates may be re-absorbed by the soil, though
never precipitated as rain. But even supposing that this should have
happened, not once, but times innumerable in the course of a specified
period—and thus much of the moisture evaporated should be sub-
stantially the same moisture, passing again and again and again
through the circuit, evaporated, passed through the stomates, ab-
sorbed by the air, thence absorbed by the soil, and thence absorbed
by the rootlets to be passed on by endosmosic action again to the
leaves, to go through the same round again and yet again—it is not
unreasonable to suppose that a large portion, a very large portion,
must be taken from the soil.

The experiments founded on by Pfaff, like that of Marshal Vaillant’s,
give the result of evaporation which could not have been sustained in
this way, for the branch was severed from the tree. I have no means
* of verifying his calculation resulting in the conclusion that the quantity
of moisture passing out by the stomates in the time specified must have
been equal in quantity to eight and a-half times the whole quantity of
rain which fell on the spot in the course of the period specified ; but
with what I happen to know of vegetable physiology his conclusion in
no way startles me.

By Dr Asa Gray it is remarked :—“ The quantity of water exhaled
from the leaves during active vegetation is very great. In one of the
well-known experiments of Hales, a sunflower three and a-half feet
high, with a surface of 5,616 square inches exposed to the air, was
found to perspire at the rate of twenty or thirty ounces avordupois
every twelve hours, or seventeen times more than a man. A vine,
with twelve square feet of foliage, exhaled at the rate of five or six
ounces a-lay ; and a seedling apple tree, with eleven square feet of
foliage, lost nine ounces a-day. The amount varies with the degree
of warmth and dryness of the air, and of exposure to light ; and is
also very different in different species, some exhaling more copiously

80 EFFECTS OF FORESTS ON MARSHES.

even than the sunflower. But when we consider the vast perspiring
surface presented by a large tree in full leaf, it is evident that the.
quantity of watery vapour it exhales must be immense.”

Of the moisture thus evaporated and passed into the.atmosphere a
very great quantity must have been withdrawn from the soil and
dissipated, and thus even a marsh might in course of time be dried up.

Of this effect let me give one illustration, one which was communi-
cated to me by a distinguished agriculturist in Berwickshire, not less
distinguished for his knowledge of the science and literature of agricul-
ture than he is for the practical application he has made of the know-
ledge he possesses. On the farm in his possession, and which has been
long in the hands of himself and his family, there is a rising ground
at the base of which there was a piece of waste land, which, though
not a bog, was characterised by its large and luxuriant crop of rushes,
and into which sunk the feet of horses, if not of men, when they got
upon it, leaving footprints wet, if not filled with water, and there was
adjoining this a corner of enclosed cultivated land which it was
attempted to make dry by drains, but the attempt was vain.

Shortly after 1820 the top of the rising ground was planted with
firs and larch. The plantation covered a space of 20 acres. From
this time both the swampy waste land and the enclosed drained but
damp land became more dry, and at length became perfectly so.
Some forty years after the planting of these trees a furious gale pro-
duced great devastation in the plantation, uprooting or breaking over
most of the trees and leaving standing only here and there one. The
scene was unsightly, and ultimately the whole were felled and the
land cleared ; but immediately the low-lying ground became swampy
as before, and this was its condition when I visited the locality some
eight years thereafter.

The phenomena were accounted for by my friend and informant by
the supposition that there must have been a fissure in the rising
ground, from which the water oozed out, formerly and now; but that
the rootlets of the trees, during the growth of these, absorbed the
moisture, and though their doing so may have increased the humidity
of the atmosphere enveloping the trees, it prevented the percolation
of the moisture into the ground below, which was previously so wet ;
but the removal of the trees allowed it, in oozing out, to descend to
the lower-lying soil as before.

To this explanation I offer no objection—an examination of the
rock alone would enable me to test the correctness of it. At the

MARSHES APPEARING IN FORESTS. 81

same time, another explanation of the cause of the phenomena
suggested itself to me when the details were given, namely: that
before the rising ground was planted much of the moisture falling as
rain upon the upper part of it spread under the surface, being pre-
vented by rock or clay from sinking, and oozed out at the lower level;
but after the plantation was formed less of the rain-fall reached this
impervious layer,

But in either case all may be accounted for without prejudice to
the doctrine now under consideration. The planting of the trees was
followed by the desiccation of the swamp ; the destruction of the
trees, by its restoration.

Secr. Il.—On the Occasional Appearance of Marshes on the
Destruction of Forests.

In the case of the disappearance of a swamp on the planting of an
adjacent rising ground with trees, and the reappearance of the swamp
on the destruction of the trees, the one phenomenon may be con-
sidered the counterpart to the other, and both of them in accordance
with the exposition which has been given of the absorption of moisture
from the soil by the roots, and its emission into the atmosphere by
the leaves. Other cases of the destruction of woods having been
followed by the appearance of swamps have been brought under
my notice.

In Russia, some years ago, in the course of conversation on the state
of the forests with an intelligent lady, the niece of a forest official, I
learned that there, as elsewhere, when ground is cleared of firs and
pines, as it often is by extensive fires, it often happens, so often that
in some districts it may be said that generally, there spring up birches
in great abundance ; and, she added, that in some cases the clearing
away of a wood converts the ground on which it grew into a morass,
which, when it is replanted, is commonly replanted with willows.

I accept the statement as made. I pass at present the growth of
birches where previously grew the pine and the fir, but with the
intention of reverting to it afterwards. I call attention to the morass,
and suggest the enquiry, How came it to pass that there was no
morass there before ?

I consider there was none before, most probably because all the
water which went to the subsequent creation and maintenance of the
morass which subsequently appeared was raised by the trees and

passed into the atmosphere, in accordance with what has been
F

82 EFFECT OF FORESTS ON MARSHES.

advanced ; and that this was the case I have no doubt. But along
with this there may have been combined another operation, more
simple, mechanical, and intelligible, which must not be overlooked.

I have never heard particulars of a case which seemed to run
counter to the exposition which I have given, of which I have not
been able to show that it was compatible, or consistent, with the
supposition that the operation was such as I have supposed. But
there is another operation, noticed by Becquerel, to which Marsh
considers that sufficient importance has not, until very recently, been
generally ascribed, namely, the mechanical action of roots as con-
ductors of the superfluous humidity of the superficial earth to lower
strata. “The roots of trees,” says he, “often penetrate through
sub-soil almost impervious to water, and in such cases the moisture,
which would otherwise remain above the sub-soil, and convert the
surface earth into a bog, follows the root downwards and escapes
into more porous strata, or is received by subterranean canals or
reservoirs. When the forest is felled, the roots perish and decay, the
orifices opened by them are soon obstructed, and the water, after
having saturated the vegetable earth, stagnates on the surface and
transforms it into ponds and morasses. Thus, in La Brenne, a tract
of 200,090 acres resting on an impermeable sub-soil of argillaceous
earth, which ten centuries ago was covered with forests, interspersed
with fertile and salubrious meadows, has been converted by the
‘destruction of the woods into a vast expanse of pestilential pools and
marshes. In Sologne the same cause has withdrawn from cultivation
and human habitation not less than 1,100,000 acres of ground, once
well-wooded, well-drained, and productive.”

It is with the fact that such results have followed such proceedings
that we have to do. From the facts alone we may learn wisdom,
though we should be baffled in attempting to trave the process by
which the results have been produced, and explanations offered by
others may appear to us unsatisfactory.

We have learned that food invigorates us and sleep refreshes,
and we act upon the knowledge of the facts, though we may be
unable to explain how it is that these results are produced. And
we find that thus the knowledge of these facts has been utilised in
Russia, where a morass appearing on the destruction of a forest is
replanted with willows. Pines and firs grew there before; but
pines and firs would not grow now, and thus is brought before us
another view of the subject: not only has the destruction of

FORESTS DESTROYED BY MARSHES. 83

forests given rise to the appearance, on the spot or near it, of a
morass, but a morass otherwise produced has brought about a
destruction of forests.

Secr. III.—On the Occasional Destruction of Forests by the Creation of
Marshes.

The cases of forests having been destroyed by the creation of
marshes are numerous. There is nothing in this which is otherwise
than in accordance with the views of the meteorological effects of
forests which have been advanced; but it may be well that this
should be shown, and it may be not improper that in doing so the
phenomena should be brought under consideration in more than
one of the phases which they present.

T have, in the preceding section of this chapter, given my explana-
tion of the fact communicated to me that in some cases in Russia
the clearing of the portion of a forest by a forest fire, or by a hurri-
cane, has been followed by the conversion into a morass of the ground
on which it grew; and I have brought forward other facts suggestive
of how it may be that the results followed. But these exhaust: not
the means by which morasses are produced in forest land.

In forests we meet with swamps which appear to have destroyed
trees growing on the spot, but which may have been themselves pro-
duced by the destruction of other trees through a process in no respect
similar to any which have been noticed.

I submitted the account I have given of the facts communicated to
me by my friend in Russia to an intelligent English engineer who had
resided much in the interior of the country, who was a man of careful
observation, one who reasoned on what he saw, and one from whom
I had received much information in rezard to forests in Russia. He
returned my statement with the following annotation :—“In the
interior there occasionally occur great hurricanes, tearing all before
them and blowing down large spaces of the forests, laying the trees
with their roots attached to them in all directions, and being in many
cases far from towns or villages the blown down trees are never
taken away, but decay where they have fallen, as I have seen. When
the ground is level, the little river is, from the fallen trees, raised in
its bed, or, as is often the case, is changed in its course. There is
thus always more of the space kept longer under water in the spring
than formerly, and during the summer a rank vegetation springs up,

84 EFFECTS OF FORESTS ON MARSHES.

which tends also to keep the ground damp and watery. This, along
with the decaying wood, soon gets into a complete marsh, and will
eventually become what is called in Britain a peat moss.

“Tn cases where these hurricanes have destroyed the forest near to
inhabitated districts, and the land is low-lying, the space is cleared
and turned often into meadow, which is what the Russians like—good
meadow land. ‘Their method of getting the hay from the soft and
marshy land is to put it up into ricks in some raised part of the
meadow, inclose it round with a wicker fence, and when the winter
sets in they take it home in their sledges, in the same way as their
wood is all taken to its destination, advantage being taken then of
sledges on the snow, where there are often no roads in summer ; and
also in the winter time, the peasant farmers having nothing do on
their land are thus able to get their rye, etc., conveyed to the nearest
market ; and having then plenty of time, some of them go to the
large towns and factories, and work there during the winter, returning
home in the spring, generally about the Easter holidays.”

I have given the annotation entire, because to me it speaks
throughout of the abundance of moisture existing when the forests
have been destroyed. The allusions to what is done in leading rye and
leading wood speak of the abundance of water in the ground kept
comparatively dry by the forest, but accumulating when superficial
drainage is prevented.

My correspondent assumes, and not without reason, that in the
cases alleged the water level may have been raised by the damming
up of an outlet; and I accept the explanation as one given by an
intelligent observer, living in the country and familiar with the facts.
His statement is suggestive of much which might illustrate the
operation of trees in drying marshy land, utilizing and dispersing the ~
excess of moisture, and fitting the land, otherwise comparatively use-
less to man, for bringing forth herbs meet for them by whom it is
dressed. But at present we have to do with the one fact that thus
also morasses may be produced, along with the effects referred to ;
and of this other illustrations may be given.

In the Northern States of America, and in the Dominion of
Canada, we meet occasionally with extensive patches of weird-like
trees, standing leafless and dead in a shallow waste of waters, miles
in extent, produced by the accidental or designed damming up of
some streamlet it may be by which it had previously been drained.
It may have occurred through some such accident as my friend in

THE BOIS BRULE. 85

Russia has suggested ; it may have occurred in connection with some
endeavour to divert into another channel the waters of the same or
some other water-course ; it may have occurred in consequence of the
damming up of some outlet from a lake which it was sought to
enlarge as # reservoir for the supply of a canal, or a mill-lade, or some
other purpose; or it may have been the effect of the work of a
beaver, for cases of all such occurrences can be cited. But, however
produced, the consequence to that portion of the forest which is laid
under water, though only to the depth of one or two feet, is the same
—the trees are killed as if girdled by fire, or by the woodman’s axe,
and, most probably, by a similar operation, through the decay and
destruction of the bark and sapwood at the water-line, or between
wind and water, promoted by alternate exposure to each by the
ripple, and the consequent severance of the communication between
rootlet and leaf, or it may be by such a severance being occasioned by
the rupture and decay of vessels through which that communication
was maintained.

A graphic sketch of the destruction thus wrought occurs in
an account given by Gosse of a forenoon’s excursion, which he
made in Canada to the Bois Brule, a large tract of land which lay at no
great distance from his residence, but was so hidden in the recesses of
the woods, and so out of the way of any travelled road, that it was
not often visited except by the trapper. The first quarter of a mile
lay through what he calls a very rough slash. “Such a labyrinth of
fallen timber we had to penetrate,” says he, “climbing over the
trunks, and scrambling through the dry branches of the prostrate
trees, often falling through ; and, to make the matter worse, these
were concealed by the tall Indian wickup, epilobium latefolium, with
which the ground was absolutely covered, ard, as the long seed-pods
were just bursting, our every movement dispersed clouds of the light
downy cotton, which, getting into our mouths and nostrils, caused us
considerable inconvenience. Presently we descended the steep bank,
and walked, or rather scrambled, up the rocky bed of the stream, by
means of the stones which were above water, though, as they were
wet and slimy, we occasionally wetted our feet. Thus we went on,
sometimes in the stream, sometimes among the alders and underwood
of the banks, for about a mile and a-half. We were much surprised
in going up this brook, about a mile up, at coming upon a ruined
building, which had been erected over the stream at a craggy fall, the
timbers of which had fallen down, and some of them had been
carried a considerable distance down by the freshets. I supposed it

86 EFFECTS OF FORESTS ON MARSHES.

must have been a mill, but wondered at its situation, so far from any
road. I have since been informed that it was a saw-mill, and that
there was a good road to it, but this road being now overrun with
bushes and young trees, escaped our notice. The mill has been disused
nearly twenty years. On the borders of the brook I met with seed-
vessels of the touch-me-not, impatiens nolli tangere, the handsome
sub-conic scarlet fruit of the white and the red death, ¢rilliwn
pictum and 7. fetidum, the large umbelled bright blue berries
of smilacina borealis, and many others. In pressing through the
bush we got our clothes bedaubed with a nasty substance, which
we discovered to proceed from thousands of the aphis lanata (?)
which we had crushed; they were so thickly clustered round
the branches of the alders as to make a solid mass half-an-inch
thick, covered with ragged filaments of white down. We were
getting tired of the ruggedness of our path, when we suddenly
came upon a new and very good bridge across the brook, made
of round, that is, unhewn logs, which connected a good broad
path, from which the fallen trees and encumbrances had been cleared
away, and which had evidently been used for drawing out mill-logs in
winter with sleds. This we followed. The sides of the road were
lined with the stumps of large spruces and hemlocks, which had been
felled the previous winter; and the road itself was strewn with the
chips of the axe-men. The course lying through a cedar swamp, the
ground was mossy, and in some places wet; here the scarlet stone-
berry was abundant, as well as the berries mentioned before. The
former, fragaria canadensis, is a low and pretty plant, having a white
flower, resembling that of a strawberry, and four large oval green
leaves on the ground ; at present they were crowned with the little
cluster of bright red berries, which were ripe, and we ate many—
they were farinaceous and agreeable. This plant is common in
Newfoundland. We continued to follow this path till it appeared
almost interminable, though its tedious uniformity made it seem
longer than it really was, as I suppose we did not walk more than a
mile and a-half on it when I perceived by the increasing light among
the trees that we were approaching a large opening.

“ We now pressed eagerly on, and found that we had reached the
borders of the Brule, which was not a clearing, as I had expected, but
was covered with a stunted and ragged growth of moss-grown spruce,
from eight to twelve feet in height, exactly resembling the small
woods of Newfoundland. On the borders of the large marshes I
found algo the same plants that inhabit such situations in that

THE BOIS BRULE. 87

eountry, and which I now saw for the first time in Canada, I also
recognised numbers of another old acquaintance, an exceedingly
curious plant, the Indian cup or pitcher-plant, sarracenia purpurea.”
Some of the plants he describes, and then goes on to say, “ The road
by which we had approached did not enter the Brule, but merely
touching its edge, went straight on, entering the tall woods on the
other side. We penetrated a few roods into the Brule, to see if there
were any clearing, but could perceive no change in the ugly, dead,
half-burnt spruce, and therefore returned. This singular piece of
ground contains some thousands of acres, and is said to owe its origin
to the beavers, which were formerly numerous, damming up the
streams, which, overflowing and spreading over the flat-lands, killed
the growing timber. It is a resort of wolves, bears, and other wild
animals, though we perceived no sign of life in the stillness which
pervaded the solitude; nor, indeed, in the whole journey, with the
exception of one or two little birds, which were not near enough to
be identified, and a few insignificant insects in the forest. Having
satisfied our curiosity we began to return as we came, until we
arrived at the bridge, when, instead of retracing the course of the
stream, we crossed the bridge and continued to pursue the road,
which, for some distance, led us through towering spruces and
hemlocks, as before. On a sudden the character of the woods
changed : we found the sides lined with young maple, birch, beech,
&c., which met overhead at the height of about twelve feet, forming
a very perfect and regular continued Gothic arch, or rather a long
series of arches. This long avenue was the most pleasant part of our
walk, and the more so because it was quite unexpected. We
presently opened into a large field, which had been just mown, and
here we were rather laughably bewildered: the place was a terra
incognita ; we had never before seen it, nor could we recognise any
object, so as to guess at our whereabouts. There appeared to be no
outlet through the woods by which the field was environed. In one
part was the skeleton of an old log-house without a roof, and a
portion of the field was planted with potatoes. We at length saw
a path through to these potatoes, on which we walked till we came to
the brow of a hill from whence we perceived familiar objects. It
commanded an extensive view : the beautiful and winding Coatacook
was at our feet with its bridge, Smith’s mills and all that neighbour-
hood ; beyond a broad belt of the forest was visible Tilden’s Tavern
and the road leadiaz from Hatley to Sterbrooke, and the forest again
behind all, We now left the path, taking a short cut over the hill,

88 EFFECTS OF FORESTS ON MARSHES.

coming down by Bradley’s mill, and so home, much pleased, notwith-
standing the little disagreeables, with our little excursion.”

In regard to the effects of the work of the beaver, it is remarked
by Marsh, “I am disposed to think that more bogs in the Northern
States owe their origin to beavers than to accidental obstructions of
rivulets by wind-fallen or naturally decayed trees; for there are few
swarrps in those States, at the outlets of which we may not, by
careful search, find the remains of a beaver dam. The beaver some-
times inhabits natural lakelets and even large rivers like the
Mississippi, when the current is not too rapid, but he prefers to owe
his pond to his own ingenuity and toil. The reservoir once con-
structed, its inhabitants rapidly multiply so long as the trees, and
the harvests of pond lilies and other aquatic plants, on which this
quadruped feeds in winter, suffices for the supply of the growing
population.

“But the extension of the water causes the death of the neighbouring
trees, and the annual growth of those which could be reached by
canals and floated to the pond soon becomes insufficient for the wants
of the community, and the beaver metropolis now sends out
expeditions of discovery and colonization. The pond gradually fills
up, by the operation of the same causes as when it owes its existence
to an accidental obstruction, and when, at last, the original settle-
ment is converted into a bog by the usual processes of vegetable life,
the remaining inhabitants abandon it and build on some virgin brook-
let a new city of the waters.”

And he adds in a foot note :—“T find confirmation of my own
observation on this point (published in 1863) in the ‘ North West
Passage by Land,’ of Milton and Cheadle, London, 1865. These
travellers observed ‘ A long chain of marshes formed by the damming
up of a stream which had now ceased to exist,’ chap. x. In chap. xii.
they state that ‘ Nearly every stream between the Pembina and the
Attrabasca—except the large river M‘Leod—appeared to have been
destroyed by the agency of the beaver,’ and they question whether
the vast extent of swampy ground in that region ‘Has not been
brought to this condition by the work of beavers, who have thus
destroyed, by their own labour, the streams necessary to their own
existence,

“But even here nature provides a remedy, for when the process of
consolidation shall have been completed, and the forest re-established
upon the marshes, the water now diffused through them will be

MARSHES OCCASIONED BY LEAVES. x9

collected in the lower or more yielding portions, cut new channels for
their flow, become running brooks, and thus restore the ancient
aspect of the surface.

“The authors add the curious observation that the beavers of the
present day seem to be a degenerate race, as they neither fell large
trees nor construct great dams, while their progenitors cut down trees
two feet in diameter and dammed up rivers a hundred feet in width.
The change in the habits of the beaver is probably due to the diminu-
tion of their numbers since the introduction of fire-arms, and to the
fact that their hydraulic operations are more frequently interrupted
by the encroachments of man.

“Tn the valley of the Yellowstone, which has but lately been much
visited by the white man, Hayden saw stumps of trees thirty inches
in diameter which had been cut down by beavers. *

“ The American beaver closely resembles his European congener,
and I believe most naturalists now regard them as identical. A
difference of species had been inferred from a difference in their modes
of life, the European animal being solitary and not a builder, the
American gregarious and constructive. But late careful researches
in Germany have shown the former existence of numerous beaver-
dams in that country, though the animal, having become too rare
to form colonies, has of course ceased to attempt works which require
the co-operation of numerous individuals. T

“On the question of identity, and all others relating to this interest-
ing animal, see L. H. Morgan’s important monograph, ‘“‘ The American
Beaver and his Works,” Philadelphia, 1868. Among the many new
facts observed by the investigator is the construction of canals by the
beaver to float trunks and branches of trees to his pond. These
canals are sometimes 600 or 700 feet long, with a width of two or three
feet, and a depth of one to one and a-half.”

It may be considered by some of my readers that the natural
history of beavers can scarcely be considered the meteorological
effects of forests. The same may be alleged of all that is being
advanced in this chapter relating to the effects of forests on the
humidity of the ground. I deem it proper to treat the subject thus
freely, partly with a view to anticipating and obviating objections
which may suggest themselves to conclusions drawn, and partly

* “ Geological Survey of Wyoming” (p. 135).
t Schleiden: “ Fir Baum und Wald.” Leipzig, 1870 (p. 68).
G

90 EFFECTS OF FORESTS ON MARSHES.

because it is the effect on the soil of the meteorological effects of
forests which chiefly concerns us at present in the discussion of these.

Srcr, I1V.—On the Desiccating Effects produced on Marshes by Forests
in Prolonged Periods.

Reference is made by Marsh to a recuperative operation, whereby
even the bog produced by the destruction of a forest regains, after a
time, its former aspect, and in this the desiccating effect of vegetation
comes again into play, promotes the work, and expedites the result.
In Denmark we see what may thus be accomplished. We there
meet with a land, which, at one or more periods of its existence as
land, must have been over a great extent of its surface covered by
morasses and marshes, and peat bogs, but which is now so dry as to
be habitable, and cultivated by man, giving him in return for his
labours fields of increase; and the peat bogs supply extensive
indications that forests must have played an important part in
producing the change.

From Béigens Indrandring « de Danske Skove, by Chr. Vaupell, we
learn that a careful examination of the peat mosses in North
Sjelland, which are so abundant in fossil wood that within thirty
years they have yielded above a million of trees, shows that these
trees have generally fallen from age and not from wind. They are
found in depressions on the declivities of which they grew, and
they lie with the top lowest, always falling towards the bottom of
the valley. \

The origin of these bogs dates from pre-historic times; but the
origin of other bogs has been studied, and the result has been given
in part in the preceding section. ,

Marsh, in his valuable treatise on “The Earth as Modified by
Human Action,” which I have already cited, says, “Bogs generally
originate in the checking of water-courses by the falling of timber or
of earth and rocks, or by artificial obstructions across their channels.
If the impediment is sufficient to retain a permanent accumulation
of water behind it, the trees whose roots are overflowed soon perish,
and then by their fall increase the obstruction, and, of course,
occasion a still wider spread of the stagnating stream. This process
goes on until the water finds a new outlet, at a higher level, not liable
to similar interruption. The fallen trees not completely covered by
water are soon overgrown with mosses ; aquatic and semi-aquatic
plants propagate themselves and spread till they more or less com-

DRYING UP OF BOGS. 91

pletely fill up the space occupied by the water, and the surface is
gradually converted from a pond to a quaking morass. The morass
is slowly solidified by vegetable production and deposit, then very
often restored to the forest condition by the growth of black ashes,
cedars, or, in southern latitudes, cypresses and other trees suited to
such a soil, and thus the interrupted harmony of Nature is at last
re-established.” .

In continuation of the passage I have cited, Mr Marsh goes on to
say, “In countries somewhat further advanced in civilization than
those occupied by the North American Indians, as in medieval
Ireland, the formation of bogs may be commenced by the neglect
of man to remove from the natural channels of superficial drainage
the tops and branches of trees felled for the various purposes to
which wood is applicable in his rude industry ; and when the flow
of water is then checked, nature goes on with the processes I have
already described. In such half-civilised regions, too, wind-falls are
more frequent than in those where the forest is unbroken, because when
openings have been made in it for agricultural and other purposes
the entrance thus afforded to the wind occasions the sudden over-
throw of hundreds of trees which might otherwise have stood for
generations, and have fallen to the ground only one by one, as
natural decay brought them down. Besides this, the flocks bred by
man in the pastoral state keep down the incipient growth of trees on

the half-dried bogs and prevent them from recovering their primitive
condition.”

Denmark supplies many illustrations of the effect of vegetation,
herbaceous and arborescent, in filling up and drying up marshes in
prolonged periods extending back into pre-historic times.

By numerous successive growths of aquatic and semi-aquatic plants,
herbs, and trees, bogs have there been filled up and dried up in the
course of ages, and at length rendered, as now, so dry as to be fit
habitation for man. And simultaneously with what has been
effected by the aostraction of water by the spongioles, and emission
of it by the stomates, an influence modifying the process of desiccation
otherwise produced, intensifying or mocerating it, may have been
going on.

Marsh, citing as his authority a work by Wilhelm, entitled “ Der
Boden und das Wasser,” a work published in Vienna in 1861, and a
work by Krecke, entitled “ Het Klimat van Nederland,” says :—T he
relative evaporating action of earth and water is a very complicated

92, EFFECTS OF FORESTS ON MARSHES.

problem, and the results of observation on the subject are con-
flicting. Schuebler found that at Geneva, the evaporation from
bare loose earth in the months of December, January and February,
was from two and a-half to nearly six times as great as from a like
surface of water. In the other months, the evaporation from water
was from about one and a-half to six times as great as from the
earth. Taking the whole year together the evaporation from the
two surfaces was 199, lines from earth, and 53675 lines from
water. Experiments by Van der Steer, at the Helder, in the years
1861 and 1862, showed for the former year, an evaporation of 602:9
millimetres from water, 1399°6 millimétres from grounds covered
with clovers and other grasses ; in 1862 the evaporation from water
was 584°5 millimétres; from grass-ground 8755.” It is these latter
observations with which we have to do, and these indicate that from
the bog evaporation would proceed more rapidly than it would from a
lake of the same extent similarly situated.

Such seem, then, the effects of forests on swamps and of swamps on
forests. The moisture withdrawn from the ground and passed into
the atmosphere by the trees, if in excess of what is supplied from
a higher level, and of what also falls on the spot, as rain, snow, or
dew, must render them dry, and to the same extent produce the
meteorological effect of increasing the humidity of the air; but at
the same time, by shade, and by shelter, and by covering the ground
with fallen trees, and broken twigs, and by the humus produced from
the decay of these, the forests prevent extreme desiccation. And the
occasional appearance of marshes on the destruction of forests, even

when attributable to the stoppage of an outlet, may indicate what they
have thus accomplished.

CHAPTER IV.

On tHE ErFects or Forests oN THE MoIsTURE OVER A WIDE
Expanxse or Country.

The observations which we have had under consideration show
that forests, in common with other products of vegetation, withdraw
moisture from the ground, and that they do so to such an extent as
to carry off the water of swamps and to prevent the formation of
these increasing the atmospheric moisture in their immediate vicinity
to such a degree that it may be felt, making houses damp, even in
their innermost chambers, and that it may be seen in clouds and fogs
and drizzling rain; and yet, that they keep the soil moist compared
with the soil beyond their shade and shelter, wherever that shade
and shelter fall; while the ground is at the same time enriched with
vegetable mould, the product of the fallen leaves and other debris.

But when we extend our study to the effects of forests on the
humidity of soil and climate over a wide expanse of country, we find
that observations have been made which seem to show that in some
cases the extensive destruction of forests, over a great expanse of
country has not perceptibly affected the quantity of the rain and
dew, and hail and snow, which has there fallen from heaven ; while,
on the other hand, there are lands which were once populous and
fertile, but are now arid and sterile—the aridity of which is alleged
to be the cause of their sterility, and to be a consequence of the
destruction of forests.

On thus extending our field of observation we meet with additional
facts, which, if all the circumstances and conditions of each were
known, might be easily reconciled, notwithstanding apparently an-
tagonistic conclusions to which they sometimes seem to lead.

I shall cite some of the individual or separate facts which are
known, illustrative of the general facts now stated; and either as I
advance or subsequently, as may appear at the time most important,
I shall advert to the modus operandi of the means whereby the results
observed may have been brought about.

94 EFFECTS OF FORESTS ON MOISTURE

Szor. I.—Cases in which the Extensive Destruction of Forests does not
appear to have Perceptibly Affected the Quantity of the
Rainfall over a Wide Lupanse of Country.

The subject of this chapter is the effect of forests on the moisture
over a wide expanse of country, that of this section is only the
apparently negative effect, in certain cases of the extensive destruc-
tion of forests, on the rainfall. Attention is called to the difference,
that it may be noted. The rainfall is treated neither asithe source
nor as the measure of the moisture, but solely as one of the indications
of the humidity of the atmosphere, it being the indication of this to
which most importance is generally attached, and that which is most
generally referred to in popular discussions on the meteorological
effects of forests.

Both Europe and America supply illustrations of apparently little
effect having been produced upon the deposit of moisture in the form
of rain over a wide expanse of country by the extensive destruction
of forests.

There are many indications of Europe having been formerly
covered much more extensively and densely with forests than now.
In France, the destruction of these forests within the last two
hundred years as well as before has been considerable, yet there does
not appear to have been within that time any very great diminution of
the rainfall over some extensive districts in which observations on the
rainfall have been made. .

This point has been discussed at considerable length by M. Cézanne,
in his Sequel to Ftude sur les Torrents des Hautes Alpes, par Alexandre
Surell. It is mentioned by him that some writers on the subject, to
whom he afterwards refers more particularly, in endeavouring to demon-
strate the action of forests on the rainfall, have adduced as proof that
the destruction of forests, and the extensive plantation of these, have
both of them affected the régime of the rainfall in France; some, that
the rainfall has increased at Viviers contemporaneously with the de-
boisement or destruction of forests on the mountains of the Cevennes ;
others, that it has increased at Bourdeaux contemporaneously
with the vebovsement, or replanting of forests, on the Landes : facts,
if facts they be, which, though not incompatible with each other,
point to different conclusions. In reference to these observations,
M, Cézanne writes :—“If facts of this kind were clearly established,
they would be unanswerable ; but before admitting them we must

OVER A WIDE EXPANSE. 95

betake ourselves to the records of the rainfall and enquire whether
either of these two conflicting assertions have any value.
‘Tn France, the earliest series of pluviometric observations is that
of ?’Observatoire. It was begun in 1689 by Phillippe de la Hire, in
accordance with an express order given by Colbert to the Academy,
in view of the requirements of the hydraulic works at Versailles, to
ascertain what quantity of water the rain falling on the plains around
could supply to the projected reservoirs.
“Tt has been repeatedly interrupted, and again resumed. And
a summary of the record is given in the following table, taken
from a valuable collection of pluviometric observations publi shed
by M. Raulin, Professor of Geology in the Faculty of Sciences at
Bourdeaux :—*

TABLE OF MEAN ANNUAL RAINFALLS IN DECADES, ACCORDING TO THE
PLUVIOMETRE ON THE TERRACE OF THE OBSERVATORY AT PARIS,

Periods. Number of Years, Rainfall. Difference, Names of the Observers.

1688-1700...... LO vcagers 517:
1701-1710...... 10. cg: 480°6-— 36-4 Lahire, 1688 to 1718.
1711-1720...... 10...... 464°9-— 15-7

1721-1730......10......378°3— 86°6
1731-1740,....10.....411- + 39-7 | Maraldi, Grandjean de Fouchy,

1741-1750......10......495-5+ 115 1709 to 1754.

1773-1780..006. 8.004..537°6 +1141

1781-1790......10......506-9— 32: io a a 1773-
]
|

1791-1798...... Boece 413-‘7- 93:2

1804-1810..,.... W scenes 518°3 + 104:
1811-1820...... LOssciaas 496:5- 2
1821-1830... ...10...... 498-6 +

6
18
2°],

1831-1840...... 10 sc oe 509°3+ 10:7
0:
9°

Bouvard, Arago, Le Verrier.

1841-1850...... LO see 6 5293+ 2
1851-1860...... 10 ss.as0 520°3 —

“The column of difference shows that the variation followed no law
of continuity. The long-continued series of observations presents us
with three separate periods, and these give respectively for the annual
mean, during 65 years, 1688 to 1754, 448-6 millimétres; 26 years,
1773 to 1798, 489°6; 57 years, 1803 to 1860, 512°0.

“Many authors have appealed to these numbers to prove that the
rainfall in Paris is now [not less, but] greater than formerly; but this
has been met by the following considerations: In pluviometric obseryva-

* Bourdeaux, Chaumas, 1864,

96 EFFECTS OF FORESTS ON MOISTURE.

tions all errors made are errors of deficiency, arising from the escape
of water by evaporation, by infiltration, by spilling, and from neglect,
etc.; and doubtless the first observers did not attach any great im-
portance to those measures which, in the absence of other correspond-
ing observations made elsewhere, could not lead to any generalization.

“Thus Father Cotte, quoted by M. Raulin, writes in 1804 :—‘I
may observe that the udométre used at the Observatory of Paris has
been found to be so defective that they have been obliged to give up
the use of it for some years; they have now set up a new one, which
is much more exact. The water is received and measured on the
platform of the building, 27 métres [90 feet] above the ground, instead
of measuring it, as formerly, in one of the apartments on the first
storey, so that it ran through a pipe 63 feet long from the platform
where it was received to the reservoir, which necessarily occasioned
a loss.’

“From these different causes it is impossible to compare satis-
factorily the series of observations from 1688 to 1754 with the series
made from 1803 to 1860. It is possible that if the two series of
observations had been made with the same instrument, and with the
same precision, the latter might have shown a diminished instead
of an augmented mean.

“ Arago said, on this subject, in 1853* :—‘ There is no reason to
suppose that the climate of Paris is either more or less rainy than it
was 150 years ago. The small augmentation presented by the
numbers in the later groups do not in fact exceed variations observ-
able in the earlier periods.’

“Tt is known that in 1817 a second udométre was placed on the
ground of the court, and that ever since it has constantly received
quantities of water a little in excess of what was received by that on
the terrace, as may be seen from the following numbers :—~

Measurement of Water Annually

Period. 5 Received Proportion.
On the Terrace. On the Ground.

a 7) a-b,

millimetres. mm, mm,
1821-1830............ 498°6........... PBOD LO iva restau 1:10
1831-1840............ BOOB ssh danse ea: 584°8 0. 114
1841-1850............ D2 Sivas secret Loy Gi ae ae 1:18
1851-1860............ O20 Sis aeeaercrvas DM xistccaeess 1:40

* Arago: ‘ Guvres completes Melanges (p. 420).

OVER A WIDE EXP ANSE IN FRANCE. 97

“Tt was long believed that this difference was owing to this—that
the drops of rain increased in bulk by aggregation during their fall ;
it is agreed now that the relatively lesser amount collected in
the pluviométre on the terrace is attributable to atmospheric eddies.
But, if it be so, the topographical modifications to which the vicinity
and approaches to the Observatoire have been subjected since 1688
may suffice perhaps to explain the augmentation of the actual means.
This idea naturally suggests itself when astronomers are heard com-
plaining that, in consequence of the multiplication of street carriages
and other conveyances, of gas lights and of bells, certain researches
have become impossible in the Observatoire of Paris, so that it is
necessary to remove it to the country, and it is imperatively
necessary to decentralize the study of astronomy.

“In short, it may be admitted in regard to Paris, that if the
rainfall be different from what it was during the last century, the
variation is so inconsiderable that doubts are entertained as to what
the character of the variation is.”

Similar comments are made on observations made at Bourdeaux.

“The observations which we possess for the city of Bourdeaux are
summarised in the following table, the numbers given in which are
taken, in like manner, from the valuable collection of M. Raulin :—

TABLE OF MEAN ANNUAL RAIN-FALLS AT BOURDEAUX, IN DECADES.

Periods. Number of Years. Raiu-fall. Difference. Names of the Observers.

1714-1720...... pes 659°1

1721-1730...... 1O.iccav 7375+ 784
1731-1740...... LO sisi 7T35'L- 24
1741-1750...... LO sess 693°6-— 41:5
1751-1760...... a aren 6700 -— 23°6
1761-1770...... LO brass 647'8 — 22°2

1776—1786...... LO cea 641:°9- 5:9 ~* Guyot and De la Mothe.

1842-1850...... 8.....849'2 + 207°3
1851-1860......10......795°2- 54°8 \ Abris.

1851-1860...... LOS eases 820 Petit-Laffitte.
General average, 719 millimétres.

|
|
| Sarreau, father and gon.
\

«The column of differences here shows still that the variations do
not follow a law of continuity. For the first series of 67 years the
annual mean is 684°7 millimétres, while for the new series,

1842-1860, this mean rises to 820, an augmentation of 20%.
H

98 THE EFFECTS OF FORESTS ON MOISTURE

“And it is remarkable in this table that for the years 1851-
1860, two different observers obtained quantities of water notably
differe nt.”

The work of M. Raulin presents other examples of such anomalies.
To these I shall afterwards have occasion to refer in the further pro-
secution of the study of the subject ; but from the recorded observa-
tions, the destruction of forests in the districts I named does not

appear to have greatly affected the deposit of moisture throughout
the districts referred to.

Corresponding results have been yielded by a study of the records
of observations made in the United States of America.

In North America we have a country which within comparatively
recent times was extensively covered with forests in regions which
have now been in a great measure cleared of them. To observations
which may indicate any changes upon the rainfall over extensive
districts which may thus have been produced attention has been
given, and is being given, by the Smithsonian Institution, under the
direction of the Secretary, Professor Joseph Henry, at Washington.
Under his direction there are being collected, collated, tabulated, and
otherwise utilised, meteorological observations made throughout the
United States, observations made at sea, and collected at the United
States Naval Observatory, observations made by Arctic and Ant-
artic explorers, and observations made at several hundred stations in
other parts of the world.

Observations on the winds of North America have been tabulated
and published, and have been largely made use of by the English
Board of Trade in constructing wind charts of the Northern Ocean.
In 1872 Professor Coffin was engaged in the tabulation of observa-
tions in parallel zones of latitude 5° in breadth, the whole world over,
from the North Pole to the South. And at that time it was reported
by Professor Henry :—

“The temperature observations are still in progress of reduction,
two computers being engaged upon the work. The progress of their
labours has, however, frequently been interrupted by calls from
different portions of the country for reports on the climate of
different districts.

“The following is an account of the present condition of this part
of the general reductions :

“The collection and tabulation, in the form of monthly and
‘annual means, of all accessible observations of the atmospheric tem-

’ OVER A WIDE EXPANSE, 99

perature of the American continent and adjacent islands, have been
completed to the close-of the year 1870, and extensive tables
representing the daily extremes, or the maximum and the minimum
at the regular observing hours, have been prepared.

“ An exhaustive discussion of all the observations available for the
investigation of the daily fluctuations of the temperature has been
made, and this part of the work is now ready for the printer.

“The discussion of the annual fluctuations of the teraperature has
been commenced and carried as far as the present state of other parts
of the discussion would permit.

“The construction of a consolidated table giving the mean results,
from a series of years, for each month, season, and the year, at all
of the stations, which will probably exceed 2,500 in number, has been
begun and completed for that part of the continent lying north of the
United States, and also for several of the States. This is perhaps the
most laborious, as it is one of the most important parts of the dis-
cussion. In many of the large cities there are numerous series, made
by various observers, at different hours, all of which have to be
brought together, corrected for daily variation, and combined to
obtain the final mean. To give some adequate idea of the time and
labour involved in the preparation of these tables, it may be
mentioned that, in the State of New York alone, there are about
three hundred series, which are derived from nearly two million
individual observations.

“The principal sources from which the general collection of
‘results has been derived, may be enumerated as follows :—

“1, The registers of the Smithsonian Institution, embracing
upward of three hundred large folio volumes.

“2, The publications of the Institution, Patent-Office, Department
of Agriculture, and public documents.

“3, All the published and unpublished records of the United
States Army, United States Lake Survey, and United States Coast

Survey.

“4, The large volume compiled by Dr Hough, from the observa-
tions made in connection with the New York University System,
the records made in connection with the Franklin Institute, and
those obtained from numerous observatories and other scientific
institutions.

' 5, The immense collection of printed slips, pamphlets, manu-
scripts, &c., in the possession of the Smithsonian Institution.

“The work has been somewhat retarded by the collection and

100 EFFECTS OF FORESTS ON MOISTURE

tabulation of the rain-fall, to the end of 1870, for the Smithsonian
stations, and to the end of 1871 for the United States military posts.

“ Beside the discussion of the observations on temperature, rain,
and wind, there remain those relative to the pressure of the atmos-
phere, and its humidity ; also those which are classed under the head
of casual phenomena, such as thunder-storms, tornadoes, auroras,
meteors, early and late frosts, progress of vegetation, opening and
closing of rivers, &c. These will be put in hand as soon as the funds
of the Institution which can be devoted to meteorology will permit
the requisite expenditure.”

From this statement some idea may be formed of the magnitude of
the work, of the extent of the resources provided for the prosecution
of-it, and of the energy with which it was being carried out.

The documents by Dr Hough, referred to, were published in two
large volumes, the first entitled ‘ Results of a Series of Meteorological
Observations, made in obedience to instructions from Regents of the
University of the State of New York, from 1826 to 1850 inclusive,”
and the second entitled “ Second Series of Meteorological Observa-
tions, embracing Observations from 1850 to 1863, with Records of
Rainfall, and other Phenomena, to 1867 inclusive.”

In 1872 were published “ Tables and Results of the Precipitation
in Rain and Snow in the United States, and at some Stations in
Adjacent Parts of North America, and in Central and South
America,” collected by the Institution, and discussed under the
direction of Professor Henry by Mr Charles A. Schott. And, in an
examination of these, I fail to discover any intimation of any change
in the quantities of rain falling having followed the clearing of any
district from which observations were collected, and the stations were
790 in number.

Simultaneously with the collecting of these observations by the
agents of the Smithsonian Institution, special attention was being
given by Mr Draper, Director of the Meteorological Observatory in
the Central Park of New York, to the alleged effects of forests and of
the destruction of these on the rain-fall. And in his report to the
Board of Commissioners of the Department of Public Parks for the
same year, 1871, he makes the following statement, in reply to the
question, Does the clearing of land increase or diminish the fall of
rain :—

“Much solicitude is publicly felt as regards the Supposed di-
minished quantity of water which fell last year, a point of the
highest concern, There is a general impression that this alleged

OVER A WIDE EXPANSE IN AMERICA. 101

deficiency was to such an amount as to endanger a due supply to the
city for the current year. And not only this, it has also been
asserted that, for several years past, there has been a steadily
occurring diminution in the rainfall, Whilst the quantity of water
has thus been becoming less and less, the demand has been becoming
greater. Not only has the population of the city increased, but also
that of the suburban districts, which derive their supplies from the
same water-gathering grounds that we do.

“T therefore supposed, since our registering rain-gauge furnishes
very reliable measures, that it would be useful to examine this sub-
ject critically. But since we have had these gauges in operation only
about three years, and as the investigation proved to be full of
interest, I was led to draw upon other additional sources of informa-
tion, selecting such as seemed to be of the most trustworthy kind.
By the aid of these, the examination has been extended as far back
as 1836, and with the following results :—

“Ist. As respects the indications given by our own instruments,
which may be thoroughly relied on for the years 1869, 1870, 1871.

“ For the first of these years, 1869, the total rainfall was 46°82
inches, distributed as follows: During the first quarter, 15-06 inches ;
second quarter, 10°24; third quarter, 7°72; fourth quarter, 13-80—
total, 46-82.

“For 1870, the total rainfall was 42°32 inches, distributed as.
follows: During the first quarter, 12°86 inches; second quarter,
10-29 ; third quarter, 9°39; fourth quarter ; 9-°78—total, 42°32.

For 1871, the total rainfall was 52:06 inches, distributed as
follows: During the first quarter, 10°33 inches; second quarter,
14:12 ; third quarter, 14:21 ; fourth quarter, 13:-40—total, 52-06.

“So far as these years are concerned there does not appear any
evidence of a decrease. On the contrary, in the last there is a very
considerable excess over either of the others.

“ Extending our examination to preceding years as far back as the
beginning of 1836, and grouping those years into three periods each
of ten, and one of six years, the statement comes to this: First
period, from 1835 to 1846, 39°5 inches ; second period, from 1845 to
1856, 47-0; third period, fron 1855 to 1866, 52°0; fourth period,
from 1865 to 1872, 52:0. This would make the annual rainfall
throughout these 36 years, 47°62 inches. That of the last three
years 47:06. .

“These numbers being substantially the same, it may be con-
cluded that, though there are large variations from year to year, ag

102 EFFECTS OF FORESTS ON MOISTURE

shown by a synoptic table, these, on the whole, will neutralize one
another when very long periods of time are considered.

“Tn the foregoing tables the numbers from 1836 to 1854, inclusive,
are derived from the observations made by the Military Officers at
Fort Columbus, New York Harbour ; those for the next twelve years
are from the records of Prof. Morris, in New York City; and the
remainder are from the registers of this observatory. It is of course
assumed that the rainfall at Fort Columbus, that in New York City,
and that in the Central Park are the same, an assumption which is,
I suppose, under the circumstances, admissible.

“The amount of rainfall not only influences in a predominant
manner the growth of plants, and, therefore, agricultural pursuits
determining the profitable cultivation of many different crops, but it
also exerts an influence on several manufacturing operations. If,
therefore, the above statement be correct, no apprehension need be
entertained of a permanent disturbance in these particulars, Al-
though in the last thirty-six years great changes have been made in
all those portions of the United States intervening between the
Mississippi and the Atlantic Ocean, large surfaces having been cleared
of the primeval forests and brought under cultivation, their physical
character and aspect having therefore been essentially altered, no
corresponding diminution can nevertheless be traced in the mean
amount of water that has fallen. On the contrary, as seen in the table
given and in the synoptic chart, there has been an actual increase. It
appears, therefore, that the wide-spread public impression that the
clearing of land diminishes the volume of rain is not founded on fact,
and in truth this is no more than might have been expected from a
correct consideration of the meteorological circumstances under which
rain is produced.

“Tt is the belief of European Meteorologists that the mean rainfall
on the western portion of that continent varies little, if at all, when
periods of many years are considered. In England there are rainfall
records reaching back to 1677. Since 1725 these records are un-
broken ; at present there are more than 1,500 rain-gauge stations in
that country. The Scotch observations extend to 1731, the Irish
to 1791. :

‘A discussion of the observations made at the Royal Observatory
at Greenwich, in 1859, led to the conclusion that the annual fall of
rain, as compared with that previous to 1815, was becoming smaller ;
but more extended observations, taken from gauges at stations widely
separated, led to the opposite conclusion, viz., that there was a per-

OVER A WIDE EXPANSE, 103

fect. compensation, the decrease at one place being compensated by
the increase at another.

“This conclusion was strikingly illustrated by the Continental
observatories. The rainfall at Paris was found not to have altered
in 130 years, and though the observations of fifty years at Marseilles
gave a decrease, those for fifty-four years at Milan gave an increase.

“Even in the same locality this principle of compensation may be
noticed. Thus the rainfall in England, in the ten years from 1850
to 1859, was found by Mr Symons to be five per cent. less than
during the previous forty years, but during the following six years it
was five per cent. above the mean of the preceding ten,

“Tt may, however, be supposed that conclusions which apply to
the old-settled countries of Europe, in which but few important topo-
graphical changes, through agricultural or other operations, have
taken place for many years, will scarcely apply to America, wherein
the clearing of land and agriculture surface-changes have been occur-
ring on a very extensive scale. The foregoing conclusions, however,

show us how insignificant is the meteorological result which these
variations produce.”

The observations are cited as evidence that there are cases in
which the extensive destruction of forests does not appear to have
perceptibly affected the quantity of the rainfall over a wide expanse
of country; and these observations are brought forward as
observations not less necessary to be taken into account, in
considering the effects of forests on the humidity of the climate,
than are those which have previously engaged our attention.

Szor. II.—Cases in which the Extensive Destruction of Forests
appear to have been followed by a marked Desiccation
of Land and Aridity of Climate.

Lawyers have been credited with the bon mot that the case being
altered that alters the case, but the principle holds true in science
as well as in law ; and it seems to be a truth of universal application,
Along with the recorded observatiuns which have been cited as cases
in which the extensive destruction of forests does not appear to have
perceptibly affected the quantity of rain falling over a widely-
extended country, there are other cases in which the extensive
destruction of forests appears to have been followed by a marked
desiccation of land and aridity of climate; and these are so

104 EFFECTS OF FORESTS ON MOISTURE.

numerous as almost to justify the declaration that, in times past,
wherever civilised man has gone, what he found a wilderness he has
left a desert, dried up and desolate, through the reckless destruction
of the forests and the bush.

In treating of the hydrology of South Africa, of the former hydro-
graphic condition of the Cape of Good Hope, and of the causes of its
present aridity, I have given copious details in regard to the destruc-
tion of herbage and trees which has been going on in South Africa
from the time when it was first visited by Europeans to the present
(pp. 167-170), with details of the condition to which forests have been
reduced by reckless felling of timber trees (pp. 171-175), with details
of the extensive destruction of forests by fire (pp. 175-194), and with
details of the consequence of the destruction of herbage and trees on
the desiccation or diminution of the water supply in the basin of the
Orange River, given by Mr J. Fox Wilson in a paper read before the
Royal Geographical Society, with remarks on the same by Dr Living-
stone, Sir Roderick Murchison, Dr Kirk, Mr Galton, Colonel Balfour,
and Lord Stratford de Redcliffe (pp. 197-207), and corresponding
testimony by Dr Rubige, and others, at the Cape of Good Hope.

Of the extreme aridity of South Africa, beyond the colonized
portion of it, I have given illustrations in accounts given by Dr
Livingstone of his experience at Kolobeng, in accounts given of the
great sufferings of Mr Helmore and his family in travelling in the
interior, under which the whole of them succumbed and perished,
and in accounts given by Mr M‘Kenzie of his experience in travelling
to Shooseng (pp. 216-223), and in accounts given by Dr Moffat of
his experience in a journey to Griqua Town (pp. 253-256); and of
the aridity of soil and climate within the colony I have given corre-
sponding illustrations in the same volume (p. 8 and p. 227),

In bringing forward these facts thus detailed I made obvious my
belief that though only the sequence of desiccation to the destruction
of forests and herbage and grass could be proved, they were connected
as cause and effect. Such was also the opinion of, I believe, all
whose testimony I thus adduced. To establish this point was the
object of the paper prepared for the Geographical Society by Mr Fox
Wilson ; and thus has Dr Moffat borne testimony to the fact: he
relates that on his settlement at Latakoo, “The natives were wont
to tell of the floods of ancient times, the incessant showers which
clothed the very rocks with verdure, and the giant trees and forests
which once studded the brows of the Hamhana hills and neighbour-
ing plains. They boasted of the Kuruman and other rivers, with

DESICCATION OF SOUTH AFRICA. 105

their impassable torrents, in which the hippopotami played, while the
lowing herds walked to their necks in grass, filling their makukas
(milk sacks) with milk, making every heart to sing for joy.” And he
mentions that, ‘‘ Independent of this fact being handed down by their
forefathers, they had before their eyes the fragments of more fruitful
years in the immense number of stumps and roats of enormous
trunks of acacia giraffe, where now scarcely one is to be seen raising
its stately head above the shrubs; while the sloping sides of hills
and the ancient beds of rivers, plainly evinced that they were
denuded of the herbage which once clothed their surface. Indeed,
the whole country north of the Orange River lying east of the
Kalagari desert, presented to the eye of a European something like
an old neglected garden or field.” Dr Moffat found no difficulty in
accounting for this, ‘‘ The Bechuanas, especially the Batlapis, and
the neighbouring tribes,” says he, “are a nation of levellers; not
reducing hills to comparative plains, for the sake of building their
towns, but cutting down every species of timber, without regard to
scenery or economy. Houses are chiefly composed of small timber,
and their fences of branches and shrubs. Thus, when they fix on a
site for a town, their first consideration is to be as near a thicket as
possible. The whole is presently levelled, leaving only a few trees,
one in each great man’s fold, to afford shelter from the heat, and
under which the men work and recline.

“The ground to be occupied for cultivation is the next object of
attention. The large trees being too hard for their iron axes, they
burn them down by keeping up a fire at the root. These supply
them with branches for fences, while the sparrows, so destructive to
their grain, are thus deprived of an asylum. These fences, as well
as those in towns, require constant repairs, and, indeed, the former
must be renewed every year; and by this means the country for
many miles around becomes entirely cleared of timber ; while in the
most sequestered spots, where they have their outposts, the same
work of destruction goes on. Thus, of whole forests, where the
giraffe and elephant were wont to seek their daily food, nothing
remains.

“ When the natives remove from that district, which may be after
only a few years, the minor species of the acacia soon grows, but the
acacia giraffe requires an age to become a tree, and many ages must
pass before they attain the dimensions of their predecessors, In the
course of my journeys I have met with trunks of enormous size,

which, if the time were calculated necessary for their growth, as well
I

106 EFFECTS OF FORESTS ON MOISTURE.

ag their decay, one might be led to conclude that they sprung up
immediately after the Flood, if not before it. The natives have also
the yearly custom of burning the dry grass, which on some occasions
destroys shrubs and trees even on the very summit of the mountains.
To this system of extermination may be attributed the long succession
of dry seasons.” “To the same cause,” says he, “ may be traced the
diminution of fountains, and the entire failure of some which formerly
afforded a copious supply, such as Griqua Town, Campbell, and a
great number of others which might be mentioned. It has been
remarked that since the accidental destruction of whole plains of the
Olea similis (wild olive) by fire, near Griqua Town, as well as the
diminishing of large shrubs on the neighbouring heights. a gradual
decrease of rain has succeeded in that region.”

In treating of these, the secondary causes of the desiccation of
South Africa, I had occasion to quote, from Marsh’s treatise on “ The
Earth as Modified by Human Action,” the following statement, which
T followed up with the remarks and quotations from the same and
other authors, which follow :—

« ¢ Whenever a tract of country, once inhabited and cultivated by
man, is abandoned by him and domestic animals, and surrendered to
the undisturbed influences of spontaneous nature, its soil sooner or
later clothes itself with herbaceous and arborescent plants, and at no
long interval with a dense forest growth. Indeed, upon surfaces of a
certain stability, and not absolutely precipitous inclination, the
special conditions required for the spontaneous propagation of trees
may all be negatively expressed, and reduced to these three :-—
exemption from defect or excess of moisture, from perpetual frost,
and from the depredations of men and browsing quadrupeds. When
these requisites are secured, the hardest rock is as certain to be over-
grown with wood as the most fertile plain, though for drier seasons
the process is slower in the former than in the latter case. Lichens
and mosses first prepare the way for a more highly organized vege-
tation. They retain the moisture of rains and dews, and bring it to
act, in combination with the gases evolved by their organic processes,
in decomposing the surface of the rock they cover; they arrest and
confine the dust which the wind scatters over them, and their final
decay adds new material to the soil already half-formed beneath and
upon them, A very thin stratum of mould is sufficient for the
germination of seeds of the hardy evergreens and the birches, the
roots of which are often found in immediate contact with the rock,

EFFECTS OF DESTRUCTION OF FORESTS. 107

supplying their trees with nourishment from a soil deepened and
enriched from the decomposition of their foliage, or sending out long
rootlets into the surrounding earth in search of juices to feed them.’

“But with all the provisions which have been made for the produc-
tion of forests, and for the restoration of small portions which have
been destroyed, it is possible for man to counteract these ; and he
has done so. But what have been some of the consequences which
have followed !

“ According to a summary of some of these given by Marsh, ‘ With
the extirpation of the forest all is changed. At one season the earth
parts with its warmth by radiation to an open sky; receives, at
another, an immoderate heat from the unobstructed rays of the sun.
Hence the climate becomes excessive, and the soil is alternately
parched by the fervours of summer, and seared by the rigours of
winter. Bleak winds sweep unresisted over its surface, drift away
the snow that sheltered it from the frost, and dry up its scanty
moisture. The precipitation becomes as irregular as the tempera-
ture ; the melting snows and varied rains, no longer absorbed by a
loose and bibular vegetable mould, rush over the frozen surface, and
pour down the valleys seawards, instead of filling a retentive bed of
absorbent earth, and storing up a supply of moisture to feed
perennial springs. The soil is bared of its covering of leaves, broken
and loosened by the plough, deprived of the fibrous rootlets which
held it together, dried and pulverized by sun and wind, and at last
exhausted by new combinations. The face of the earth is no longer
a sponge, but a dust heap; and the floods which the waters of the
sky poured over it hurry swiftly along its slopes, carrying in suspen-
sion vast quantities of earthy particles, which increase the abrading
power and mechanical force of the current, and, augmented by the
sand and gravel of falling banks, fill the beds of the streams, divert
them into new channels, and obstruct their outlets. The rivulets,
wanting their former regularity of supply, and deprived of the
protecting shade of the woods, are heated, evaporated, and thus
reduced in their former currents,—but swollen to raging torrents in
autumn and in spring.

«From these causes there is a constant degradation of uplands,
and a consequent elevation of the beds of water-courses, and of lakes,
by the deposition of the mineral and vegetable matter carried down
by the waters. The channels of great rivers become unnavigable,
their estuaries are choked up, and harbours which once sheltered
large navies are shoaled by dangerous sand-bars.’

108 EFFECTS OF FORESTS ON MOISTURE.

“The earth stript of its vegetable glebe grows less and less
productive, and consequently less able to protect itself by weaving: a
new net-work of roots to bind its particles together, a new carpeting
of turf to shield it from wind and sun and scouring rain. Gradually
it becomes altogether barren. The washing of the soil from the
mountains leaves bare ridges of sterile rock, and the rich organic
mould which covered them, now swept down into the dark low
grounds, promotes a luxuriance of aquatic vegetation that breeds
fever and more insidious forms of mortal disease by its decay, and
thus the earth is rendered no longer fit for the habitation of man.. .

'“ The effect of the destruction of forests upon the climate has been
questioned, but the facts remain. And so has it been seen again and
again in the history of the nations. The term savage, from its etymo-
logical derivation, speaks of a sylvan life; and from the sylvan or
savage life to that of the civilized or city life, the progress of man
may be “traced, to some extent, by the destruction of forests. The
one has, until attention was given to consequences which have
followed the destruction of forests, been the accompaniment or com-
plement of the other, operating sometimes as a cause, manifesting
itself sometimes as a consequence—if both be not con-sequences of a
common cause. But it is possible that the destruction of forests may
be carried too far. According to the testimony of Dr Hooker, cited
in the preface, ‘ In the estimation of an average Briton forests are of
infinitely less importance than the game they shelter, and it is not
long since the wanton destruction of a fine young tree was considered
a venial offence compared with the snaring of a pheasant or rabbit.
Wherever the English rule extends, with the single exception of India,
the same apathy or inaction prevails. . . . In Demerara the
useful timber trees have all been removed from accessible regions,
and no care or thought of planting others ; from Trinidad we have
the same story ; in New Zealand there is not now a good Kauri pine
to be found near the coast ; and I believe that the annals of almost
every English colony would repeat the tale of wanton waste and
improvidence.’

“Tn view of this waste, Schleiden, to whom I have already referred,
writes, if not in the words, yet following in the train of thought of
one of the noblest veterans of our science, the venerable Elias Fries,
of Lund: ‘A broad band of waste land follows gradually in the steps
of cultivation. If it expands, its centre and cradle dies, and on the
outer borders only do we find green shoots. But it is not impossible |
it is only difficult, for man, without renouncing the advantage of

SPREAD OF DEVASTATION. 109

culture itself, one day to make reparation for the injury which he has
inflicted : he is appointed lord of creation. True it is that thorns and
thistles, ill-favoured and poisonous plants, well named by botanists
‘rubbish plants,’ mark the tract which man has proudly traversed
through the earth. Before him lay original nature in her wild but
sublime beauty. Behind him he leaves the desert, a deformed and
ruined land; for childish desire of destruction, or thoughtless
squandering of vegetable treasures, have destroyed the character
of nature ; and man himself flies terrified from the arena of his actions,
leaving the impoverished earth to barbarous races or animals, so long
as yet another spot in virgin beauty smiles before him. Here again,
in selfish pursuit of profit, consciously or unconsciously, he begins
anew the work of destruction. Thus did cultivation, driven out,
leave the East, and the deserts perhaps previously robbed of their
coverings ; like the wild hordes of old over beautiful Greece, thus
rolls this conquest with fearful rapidity from east to west through
America, and the planter often now leaves the already cxhausted
land, the eastern climate become infertile through the demolition of
the forests, to introduce a similar revolution into the far west. But
we see, too, that the nobler races, or truly cultivated men, even now
raise their warning voices, put their small hand to the mighty work
of restoring to nature her strength and fulness in yet a higher stage
than that of wild nature; one dependent on the law of purpose
given by man, arranged according to plans which are copied from
the development of manhood itself. All this, indeed, remains at
present but a powerless, and for the whole, an insignificantly small
enterprise, but it preserves the faith in the vocation of man and his
power to fulfil it. In future times he will and must, when he rules,
leads, and protects the whole, free nature from the tyrannous slavery
to which he now abases her, and in which he can only keep her by
restless giant struggles against the eternally resisting. We see in
the gray cloudy distance of the future a realm of peace and beauty
on the earth and in nature, but to reach it must man long study in
the school of nature, and, before all, free himself from the bonds of
that exclusive selfishness by which he is actuated.”’

In 1847 was published Klima und Plantzen Welt in der Zeit, by
C. Fraas. It was published at Landshut. In this work the writer
endeavoured to show, by the history of vegetation in Greece, not merely
that clearing and cultivation have affected the climate, but that change
of climate had essentially modified the character of vegetable life.

110 EFFECTS OF FORESTS ON MARSHES.

In the same year, 1847, Becquerel published a work, entitled
Eléments de Physique Terrestre et de Mineralogie, and six years later,
in 1853, he published another work, entitled Des Climats et de
Vinfluence qu eaercent les sols Boises et non-boissees, and in a paper
addressed to the Academy of Sciences he examines the subject of
forests both as to their commercial importance, and as to their
influence on climate. In this paper he casts a rapid glance at the
effects produced by the destruction of forests from the remotest ages
to our time.

Forests, he shows, existed on the globe long before the appearance
of man, a fact proved by the immense coal deposits which are to be
found in every part of it, even in the polar regions. These deposits
consist of Equisetacea, Sigillaria, &c., particularly also of ferns of the
size of trees, instances of which are now only to be met with under
the tropics. In most parts of the old continent, the primitive life of
man was, as he shows, passed in forests, and increase of population
was the cause of the first attacks upon them ; but the greatest
devastations only date from the period when great conquerors cut
down and burnt the forests in which the peoples they wanted to
subdue had taken refuge. From the Ganges to the Euphrates, from
that to the Mediterranean, an extent of ground 1,000 leagues in
length and several hundred broad, was ravaged by wars during the
lapse of thirty centuries. Nineveh and Babylon, so celebrated for
their civilization, Palmyra and Balbeck, renowned for their opulence,
now offer nothing but ruins to the exploring gaze of the traveller, in
the midst of deserts and swamps, once covered by luxuriant forests.
From the time of Sesostris to that of Mehemet II., Asia Minor was a
constant scene of unrelenting wars leading to similar results. The
land of Canaan, so highly praised in the Bible, is now little more
than a desert, and the whole coast of Africa along the Mediterranean
tells a similar story.

Turning from historical considerations to the present state of forests
in France, he shows that similar operations, though not to the same
extent, were being carried on there, which could only tend to produce
similar effects.

By Mr Marsh, who has himself given much attention to the
subject, it is stated that the subject of climatal change, with and
without reference to human action as a cause, has been much dis-
cussed by Moreau de Jormis, Dureau de la Malle, Arago, Humboldt,
Fuster, Gasparm, Becquerel, and many other writers, in Europe, and

DEVASTATION OF THE EAST. 111

by Noah Webster, Ferry, Drake, and others, in America, and his
work cited is a valuable repository of information, collected by
him from their works and other sources, combined with observations
made by himself, and conclusions at which he has arrived, all of
which are in accordance with those here stated.

Besides the writers now named, Professor Laurent, of Nancy
Forest School, has given attention to the subject, and has traced the
desolation which has been brought on the former homes of teeming
life in the East to the destruction of trees. And a writer in the
Edinburgh Review, for October 1875, on the subject of forest manage-
ment, citing the work of Professor Laurent, says, “ Babylon, Thebes,
Memphis, and Carthage, now waste and even pestilential, were
formerly the very hives of human life. The remains of conduits,
canals, cisterns, and pools, throughout Palestine, and especially
through the now desert country east of the Jordan, are such as to
explain the accounts on record of the former population of these
regions. So thorough has been not only the change of climate, but
the denudation of soil, caused by the cutting down of the olives,
palms, and other trees of Palestine during the Roman war, that it
would be impossible to attach any credit to the most venerable
accounts of the former fertility, beauty, and population of the Holy
- Land—its brooks and fountains gushing out of valley and hills, being
now replaced by bare and solid rock—without the knowledge that we
have acquired of the fatal effect of the destruction of timber.” This
may be considered by others, as it is by me, questionable, but it
may be received as indicative of the conviction of the writer, that
the connection of the destruction of the forests, eighteen hundred
years ago, with the present aridity, as cause and effect, is established
beyond all question.

It is alleged by Mr Draper, while reporting his conclusions from
an extensive collating of meteorological records in America, which
were to the effect that there had been no diminution of the rainfall in
the districts in which these observations had been made, that,—
“ Against this conclusion, which is based essentially on recorded
instrumental observations, I cannot admit the force of any alleged
historical facts ;” and expressing an opinion that the devastation of
ancient empires which is attributable in part to drought, is attribut-
able in a great measure to war, and consequences of war other than
the destruction of forests, he says,—‘“It is useless to draw any

112 EFFECTS OF FORESTS ON MOISTURE

inference from the present desolate condition of the regions of the
Euphrates and Tigris, or of the Holy Land, as contrasted with their
amazing fertility in the olden days;” and, “changes such as these
have nothing to do with changes of climate.” But, with the mass of
testimonies which I have piled around me to effects which have
followed immediately on the destruction of forests, I cannot assent to
the sweeping statement I have quoted. It may be freely admitted
that devastations occasioned by war may be followed by drought,
without compromise to the allegation that the destruction of forests
may be followed by drought. The devastations of war may include the
destruction of forests, and it so happens that facts are not awanting
illustrative of the devastations of war being followed by an opposite
effect, with results corresponding to what might be expected therefrom.

When Humboldt visited South America he was led to consider
what could be the cause or occasion of a process of desiccation which
was brought under his notice. To quote from a statement by Boussin-
gault, which is cited by Mr Marsh :—“ ‘ The rivers which rise within
the valley of the Aragua, having no outlet to the ocean, form, by
their union, the Lake of Tacarigua or Valencia, having a length of
about two leagnes and a-half [or seven English miles].

“<¢ At the time of Humboldt’s visit to the valley of the Aragua, the
inhabitants were struck by the gradual diminution which the lake
had been undergoing for thirty years. In fact, by comparing the
descriptions given by historians with its actual condition, even
making large allowance for exaggeration, it was easy to see that the
level was considerably depressed. The facts spoke for themselves.
Oviedo, who, toward the close of the sixteenth century, had often
traversed the valley of the Aragua, says positively that New Valencia
was founded, in 1555, at half a league from the Lake of Tacarigua ;
in 1800, Humboldt found this city 5,260 métres [or three and a-half
English miles] from the shore.

“<The aspect of the soil furnished new proofs. Many hillocks on
the plain retain the name of islands, which they more justly bore
when they were surrounded by water. The ground laid bare by the
retreat of the lake was converted into admirable plantations ; and
buildings erected near the lake shewed the sinking of the water from
year to year. In 1796, new islands made their appearance. A
fortress built in 1740 on the island of Cabrera, was now on a
peninsula ; and, finally, on two granitic islands, those of Cura and
Cabo Blanco, Humboldt observed among the shrubs, some métreg
above the water, fine sand filled with helicites,

OBSERVATIONS IN SOUTH AMERICA, 113

“ ‘These clear and positive facts suggested numerous explanations,
all assuming a subterranean outlet, which permitted the discharge of
the water to the ocean. Humboldt disposed of these hypotheses,
and did not hesitate to ascribe the diminution of the waters of the
lake to the numerous clearings which had been made in the valley of
Aragua within half a century.’

“ Twenty-two years later, Boussingault explored the valley of Ara-
gua. For some years previous, the inhabitants had observed that the
waters of the lake were no longer retiring, but, on the contrary, were
sensibly rising. Grounds, not long before occupied by plantations,
were submerged. The islands of Nuevas Aparecidas, which appeared
above the surface in 1796, had again become shoals dangerous to
navigation. Cabrera, a tongue of land on the north side of the
valley, was so narrow that the least rise of the water completely
inundated it. A protracted north wind sufficed to flood the road
between Maracay and New Valencia. The fears which the inhabi-
tants of the shores had so long entertained were reversed, Those
who had explained the diminution of the lake by the supposition of
subterranean channels were suspected of blocking them up, to prove
themselves in the right.

“During the twenty-two years that had elapsed, the valley of
Aragua had been the theatre of bloody struggles, and war had
desolated those smiling lands and decimated their population. At
the first cry of independence a great number of slaves found their
liberty by enlisting under the banners of the new republic ; the great
plantations were abandoned, and the forest, which in the tropics so
rapidly encroaches, had soon recovered a large proportion of the soil
which man had wrested from it by more than a century of constant
and painful labour.”

In this case war seems to have produced a contrary effect to that
attributed to it, in other circumstances, by Mr Draper.

Boussingault proceeds to state that two lakes near Ubate, in New
Granada, had formed but one a century before his visit; that the
waters were gradually retiring, and the plantations extending over
the abandoned bed ; that, by inquiry of old hunters, and by examina-
tion of parish records, he found that extensive clearings had been
made and were still going on.

“ He found, also, that the length of the Lake of Fuquené, in the
same valley, had, within two centuries, been reduced from ten

leagues to one and a half, its breadth from three leagues to one. At
K

114 THE EFFECTS OF FORESTS ON MOISTURE.

the former period the neighbouring mountains were well wooded, but
at the time of his visit the mountains had been almost entirely
stripped of their wood, He further adds that other cases, similar to
those alrecdy detailed, might be cited, and he proceeds to show, by
several examples, that the waters of other lakes in the same regions,
where the valleys had always been bare of wood, or where the forests
had not been disturbed, had undergone no change of level.”

The following statement is also made by Boussingault :—“ In the
island of Ascension there was an excellent spring, situated at the foot
of a mountain originally covered with wood. This spring became
geanty, and at last dried up, after the trees which covered the
mountain had been felled. The loss of the spring was ascribed, and
rightly so, to the cutting down of the timber. The mountain was
therefore planted anew, and a few years afterwards the spring re-
uppeared by degrees, and by and by flowed with its former abundance.

‘The metalliferous mountain of Marmato is situated in the province
of Popayan, in the midst of immense forests. The stream along which
the mining works are established is formed by the junction of several
small rivulets, which take their rise in a country thickly wooded.

“In 1826, when I visited the mines fur the first time, Marmato
consisted of a few miserable cabins, inhabited by negro slaves. In
1830, when I quitted the country, Marmato was covered with work-
shops, had a foundry of gold, machinery for grinding and amalga-
mating the ores, and a free population of nearly 3000 inhabitants.
In the course of these four years an immense quantity of timber had
been cut down, for the construction of machinery and of houses, as
well as for fuel and the manufacture of charcoal. But the clearing
had scarcely been two years effected before it was perceived that the
quantity of water for the working of the machinery had notably
diminished. The volume of water was measured by the work done
by the machinery ; and actual gauging at different times showed the
progressive diminution of the water. Now, in the island of Ascension,
and at Marmato, it is improbable that ¢ any merely local and limited
clearing away of the forest should have had such an influence on the
constitution of the atmosphere as to cause a variation in the mean
annual qnantity of rain. Besides, as soon as the diminution of the
stream at Marmato was ascertained, a rain-gauge was set up, and in
the second year of observation showed a larger quantity than in the
first year, though the clearing had been continued, and though there
was no appreciable increase in the size of the running stream.

“Two years’ observations are insufficient to show any definitive

OBSERVATIONS BY BOUSSINGAULT. 115

variation in the annual average quantity of rain. But, so far as they
go, they show that at Marmato the mass of running water had
diminished, in spite of the larger quantity of rain which fell. It ig
therefore probable that local clearings of forest land, even of very
moderate extent, cause springs and rivulets to shrink, and even to
disappear, without the effect being ascribable to any diminution in
the amount of rain that falls.”

These observations are advanced by Boussingualt in connection
with the statement that,—‘ In many localities it has been thought
that, within a certain number of years, a sensible diminution has been
perceived in the volume of water of streams utilized as a motive-
power; at other points, there are grounds for believing that rivers
have become shallower, and the increasing breadth of the belt of
pebbles along their banks seems to prove the loss of a part of their
water ; and, finally, abundant springs have almost dried up. These
observations have been principally made in valleys bounded by high
mountains, and it has been noticed that this dimiaution of the waters
bas immediately followed the epoch when the inhabitants have begun
to destroy, unsparingly, the woods which were spread over the face of
the land.

“ And here lies the practical point of the question ; for if it is once
established that clearing diminishes the volume of streams, it is less
important to know to what special cause this effect is due.”

In a report by Dr Hough, President of the United States Associa-
tion for the Advancement of Science, in 1871, are references to
climatic conditions there, attributed to the destructions of forests ;
and, in this connection, referring to the painful accounts which the
journals were then giving of the distress in India from famine, he
says,—“ From a careful study of this subject, with such data as are
accessible in late reports, we cannot doubt that this calamity is
largely due to the fact that the forests have within recent years been
swept off, by demands for railroad and other uses, much more rapidly
than formerly, and that the exposure to winds and sun, thus
occasioned, may have largely contributed to these painful results.”

Mr Marsh, in a foot-note supplying indications of what may be
called secular desiccation, in regard to which he had said, “ After a
district of country has been completely or even partially cleared ofits
forest growth and brought under cultivation, the drying of the soil
under favourable circumstances, goes on for generations, perhaps for

116 EFFECTS OF FORESTS ON MOISTURE

ages,” says,— ‘In many parts of New England there are tracts,
many square miles in extent, and presenting all varieties of exposure,
which were partiaily cleared sixty or seventy years ago, and where
little or no change in the proportion of cultivated ground, pasturage,
and woodland has taken place since. In some cases, these tracts
compose basins apparently scarcely at all exposed to any local
influence in the way of percolation or infiltration of water towards or
from neighbouring valleys. But in such situations, apart from
accidental disturbances, the ground is growing drier and drier from
year to year, springs are still disappearing, and rivulets still
diminishing in their summer supply of water. A probable explana-
tion of this is to be found in the rapid drainage of the surface of
cleared ground, which prevents the subterranean natural reservoirs,
whether cavities or merely strata of bibulous earth, from filling up,
How long this process is to last before an equilibrium is reached,
none can say. It may be for years ; it may be for centuries.

“Livingstone states facts which strongly favour the supposition
that a secular desiccation is still going on in Central Africa, and
there is reason to suspect a like change is taking place in California.
When the regions where the earth is growing drier were cleared of
wood, or, indeed, whether forests ever grew there, we are unable to
say, but the change appears to have been long in progress. A
similar revolution appears to have occurred in Arabia Petrea. In
many of the wadis, and particularly in the gorges of the Wadi Feiran
and Wadi Esh Sheikh, there are water-worn banks showing that, at
no very remote period, the winter floods must have risen fifty feet in
channels where the growth of acacias and tamarisks and the testi-
mcuy of the Arabs concur to prove that they have not risen six feet
within the memory or tradition of the present inhabitants. Recent
travellers have discovered traces of extensive ancient cultivation, and
of the former existence of large towns in the Tih desert, in localities
where all agriculture is now impossible for want of water. Is this
drought due to the destruction of ancient forests, or to some other
cause 4

“ For important observations on supposed changes of climate in out
Western prairie region, from cultivation of the soil and the introduc-
tion of domestic cattle, see Bryant’s valuable Forest Tiees, 1871,
chapter v., and Hayden, Preliminary Report on Survey of Wyoming,
p. 455.”

Mr Marsh adds :—“ Some physicists believe that the waters of our
earth are, from chemical or other less known causes, diminishing by

REPLANTING FOLLOWED BY HUMIDITY. 117

entering into new and inorganic combinations, and that the element
will finally disappear from the globe.” I do not know anything of
the facts or the reasonings on which this opinion rests.

If it be necessary, in considering the effects of forests on the
humidity of the climate, to take into account cases in which the
extensive destruction of forests does not appear to have powerfully
affected the quantity of the rainfall over a wide expanse of country,
it is no less necessary to take into account other cases in which the
extensive destruction of forests does appear to have been fullowed by
a marked desiccation of land, and aridity of climate. They are facts
perfectly compatible with each other, and the establishment of either
is neither a disproof of the other, nor does it invalidate the testimony
on which it is received, though it may prompt to a more strict
scrutiny of what is said, and of the credibility of this, than might
otherwise have been given to it. Let it suffice here to state that the
objections to which such statements are open are these, first, that
they are vague and general, and, second, that they relate to effects
which may have been otherwise produced than in accordance with the
supposition advanced ; and what is considered the cause may have
been in reality the effect, for anything to the contrary advanced in
the statements made.

Sect. I1].—Cases in which the Destruction of Trees has been followed
by Destecation, and the Replanting of Trees followed by
the Restoration of Humadity.

In treating of the Hydrology of South Africa, in a separate
volume already referred to, I had occasinn to cite St. Helena as a
South African Island supplying illustrations of corresponding effects
produced on the climate both by the destruction of trees and by
extensive sylviculture.

From a note appended by Emsman to his German translation of
a work on meteorology in relation to cosmical phenomena by Foissac,*
it appears that in the beginning of the sixteenth century the forests
of St. Helena must have been extensive, for it is stated by him, on
the authority of the introductory chapters in Beatson’s St. Helena,
that it was the goats which destroyed the beautiful forests which,

* Meteorologie mit Riicksight auf die Lehere vom Kosmos. Deutch von
A. H. Emsman, Leipzig, 1859.

118 EFFECTS OF FORESTS ON MOISTURE.

three hundred and fifty years ago, covered a continuous surface of not
less than two thousand acres in the interior of the island, not to
mention scattered groups of trees.

While I was at the Cape I wrote to St. Helena for information on
the subject, and in reply his Excellency, H. R. Janisch, now Governor
of the island, at once supplied me with the following information,
embodied in notes published on the WVatural History of St. Helena :—
“Viewed from the sea the island offers little or nothing to the eye
but an assemblage of lofty and barren hills, intersected in all
directions with deep and narrow valleys, in many cases little better
than ravines, and generally devoid of vegetation, excepting here and
there patches of prickly pear, samphire, and profitless weeds, the
wooded peaks in the interior being in most positions hidden from
view by the almost perpendicular cliffs running down to the sea,
But when first discovered, in 1502, it was in the valleys almost
covered with trees right down to the water’s edge. These trees
appear to have been principally gum-wood, ebony, and red-wood.”
The gum-wood flourished nearest to the sea; the ebony and red-
wood covered the slopes of the mountain ; while the hill tops appear
to have been covered with the cabbage tree and ferns—the former
(areca oleracea) presenting from a little distance the appearance of a
tree bearing stocks of cabbage, or of brocoli, at the extremities of its
branches. While such was the state of vegetation, it must have been
an island well watered everywhere.

But the earlier governors and settlers made sad havoc among the
trees ; and herds of goats and of swine being allowed to run loose on
the land, young growing trees, which might have supplied the waste,
were destroyed, and the island became almost denuded. All the
ebony trees have long since disappeared : the last, a tree remarkable
for its excessive hardness, size, and density, was found on Deadwood.
The red-wood is now scarce, and, like the ebony, would altogether
have disappeared, had not Governor Byefield caused two young trees
to be set at Plantation House, from which two all at present on the
island have been propagated. Anda comparison of the cabbage trees
of the present with the remains of those of the past tell of a stunted
growth. What was the consequence of this extensive destruction of
trees? “Incidentally we find,” says my correspondent, “in the
records of the last century, accounts of repeated and almost periodical
visitations of very severe drought, occasioning ruinous losses of cattle
and crops.”

Towards the close of the last century, however, the denudation of

RAINFALL IN ST, HELENA. 119

the island had been carried so far that wiser governors saw it to be
necessary to adopt some strenuous measure to restore the vegetation.
Nurseries were made, and experienced gardeners were introduced by
the Company, and trees from all parts of the world were introduced
and flourished. Prizes were given for the number of trees reared,
irrespective of their character. The cluster-pine (pinus pinaster) was
sown very extensively, and several plantations of this tree remain in
a thriving condition. But a variety of other forest trees, greatly pre-
ferred both for beauty and use, were planted about the same period
and have flourished well. In regard to the results, my correspondent
writes :—“ For many years past, since the general growth of our trees,
we have been preserved from this scourge; and droughts, such as
were formerly recorded, are now altogether unknown. We have no
means, however, of otherwise comparing the rainfall of the two periods,
as no tables, or even estimates, of the rainfall can be had for the
earlier dates. Our fall of rain now is equal to that of England, and
is spread almost evenly over the year. The showers fall more heavily
in two or three months of the rear. But this period, though called
on this account the rainy season, is in no way to be compared to
what is understood by an inter-tropical rainy s2ason.”

Meteorological observations are or were kept at Longwood and at
Plantation. I have at command only the record of the rainfall from
1841 to 1848. The amount of rain which fell in these vears was :-—

1: | Ee (cies 19-509
Fs eee 90-458 Es | aera 26-556
1215, navi etl So 137 oo corona 42-441
TOS, oven 20-026 1848)... ..00..00045°630

The communication I have cited not only tells of the former
abundance of vegetation and moisture, and of frequent long-continued
droughts having followed the reckless destruction of forests. but it
tells of the replenishing of the island with trees under the f2stering
care of the East India Company towards the close of the last
century ; and that subsequent to that, droughts such as had been
previously recorded had been for a long time altogether unknown.
But it was further added :—“‘ Since the transfer of the Island from
the Company in 1836 the matier has been much nezlected. The
liberal expenditure and prizes of the East India Company came to an
end. The business men of our population require, whether the profits
be large or small, that the returns shall be quick ; and they have no
idea of casting upon waters seed that cannot be found after so many

120 EFFECTS OF FORESTS ON MOISTURE.

days. The result has been that, for the last thirty years, in place of
every score cut down hardly one tree has been planted beyond the
supply of self-sown plants. Our Governor has, however, given much
attention to this since his arrival ; and he is anxiously endeavouring
¢0 introduce and propagate the best trees he can obtain, and as yet
his experiments have been very successful and encouraging.” This
was written in 1865.

Blanqui in a volume entitled Voyage in Bulgarie, published in 1843,
says that,—“ In the Island of St. Helena, where the wooded surface
has considerably extended within a few years, it has been observed
that the rain has increased in the same proportion. It is now in
quantity double what it was during the residence of Napoleon.” In
this we find a corroboration of what was reported by Mr Janisch in
regard to the consequence of extensive plantings encouraged by the
East India Company previous to 1836,

The Island of St Helena is of volcanic origin. It is said to have been
discovered by the Dutch in 1502. “ Viewed from the sea, as it is
approached, there is nothing inviting in its appearance; one large
mass of rock with deep ravines running down into the sea, divested
apparently of all vegetation, and presenting inaccessible rugged cliffs,
some of great height, is all at first that the eye beholds; but as one
nears the shore in the interior at certain places may be seen, peeping
from out the rock, a few trees to tell that all is not barrenness
within.”

In the “ Notes on the Natural History of the Island of St. Helena ”
sent to me, it is stated.

“The greater part of the Island is now bare of trees and verdure,
many mountains having little upon them beyond samphire and a few
scrubby weeds, which alone save them from absolute sterility,
especially in the dry season, when the shallow soil is utterly parched
up. Other mountains are capable of affording a very limited supply
of food for sheep, which traverse their loftiest peaks and most intricate
paths in search of their scanty fare.

“Some few of the hills are tolerably well wooded, and the loftiest
of the whole, Diana’s Peak, 2700 feet high, is clothed to the very
summit. 2... .

“The cultivated parts of the Island, particularly in the neighbour-
hood of Plantation, as seen from High Knoll, remind the stranger very
much of England, especially of parts of Devonshire.

“ Ilusion or likeness is further carried out by the large quantities

PLANTS ON ST, HELENA, 121

of luxuriant furze and scrambling brambles seen in full bloom down
the slopes of the hill, along the lanes and bye-roads.

“The furze appears to have been introduced into the Island during
the early part of the last century, and has proved very useful to the
inhabitants by furnishing them with a plentiful supply of fire-wood.
It does not appear to be used here as it is in the north of England,
for the purpose of watling in the walls, for making warm and comfort-
able outbuildings for farms and other purposes.

“When used this way, it is merely twisted between the upright
posts supporting the building, and if closely worked it makes a warm
building.

“ There are several plantations in the Island pretty well stocked
with good sized trees, principally pine and fir, which grow very well
here, but for timber purposes the wood is too coarse and open in
texture, resulting most likely from its rapid growth. The wood will
answer for common purposes when protected from the weather, but
otherwise it appears soon to decay and to be subject to rot.

“ These trees, however, are a great ornament to the Island, and
add much to its English appearance, as they are the predominating
ones, and give character to the scenery.

“The Scarlet Geranium grows wild and very luxuriantly among the
rocks, and in some places may be seen whole hedges of it; the
nasturtion also grows wild, and water cresses are found in the valley
streams, as well as many other plants common to England.

“ Barilla, called here samphire, is very abundant in most parts of
the Island ; and the true samphire is found in many places, but does
not appear to be much used. Fruit of many kinds grows very well
here ; the pears are large, plump, hard, and juicy, and are seen on the
tree at the same time as the blossoms. Peaches are good and
plentifal, their beautiful blossoms being often seen in the hedges;
the fig thrives pretty well, as also Oranges and Lemons, and the
useful Plantain. Coffee has been tried and succeeded, it is considered
to be very good in quality and flavour. Cotton grows wild, as well
as the castor-oil plant.

“The Port Jackson Willow thrives exceedingly well, and will ulti-
mately be valuable for supplying firewood, as it grows quickly and
throws up much underwood ; and is a very ornamental tree in all its
aspects, especially pleasing to the eye when full of its yellow catkins.

“The Cape Gooseberry is a useful fruit, and forms an excellent
substitute for the English Gooseberry which it much resembles in

taste when cooked; it is the more useful from the fact that the
L

122 EFFEOTS OF FORESTS ON MOISTURE.

English Gooseberry does not thrive well here, but runs into an un
fruitful shrub.

“The trees most cultivated in Jamestown are the Margossa and
the Banian, neither of which are of any great use except for a little
shelter from the sun; the Banian is more curious than beautiful.
The Date, Cocoa Nut, and Cypress are seen in some of the gardens, and
the long leaf of the Plantain mostly accompanies them wherever
water can be obtained,

“A great variety of plants, the natives of different regions, may
be seen growing equally well on St. Helena, the configuration of which
affords a considerable range of climate. The following list of the
exotic trees and shrubs now growing on the island may prove not
uninteresting :—

“Common Oak, Mosscup Oak, Evergreen Oak, Cork Tree, Abele
Tree, Weeping Willow, Pineaster Fir, Spreading Fir, Dwarf Fir,
Norfolk Island Pine, Chili Fir, Cape Yew, Casuarina, Cypress (two
kinds), Arbor Vite, Eucalyptus, Banian (four kinds), Indian Rubber
Tree, Erythrina Cape Coral Tree (three kinds), Sophora, Margossa,
Gamboge, Terminalia (Bengal Almond), Pittisporum, Wild Olive,
Black Fruited Olive, Magnolia, Liliodendron, Silk-worm Mulberry,
China Weeping Birch, Murraya, Sago Palm, Palmetto, Dragon Palm,
Fan Palm, Iron Wood, Holy Thorn, Myrtle (three kinds), Bauhinia,
Locust, Bois Noir, Teak, Cinnamon, Laurel, Bay, Barberry, Protea,
Gum Benzion, Coffee Shade, Wild Fig, Wattle of New Holland,
Gelega, Althea Frutex, Chinese Rose Hibiscus (Shoe Black), Change-
able Kose (two kinds), Single Red Hibiscus, Single Purple Hibiscus,
White Flowered Hibiscus, Yellow Tahitian Hibiscus, Mimosa
(various,) Acacia (various), Port Jackson Willow, Buddlea, Candle
Nut Tree, Yansheu, China Rose Apple, Spice Tree, Psoralea, English
Privet, Sea Grape, Coral Tree (Jatrapa), Rock Rose, Travellers Joy,
Oleander, Fiddle Wood, Pola Gola, Spanish Broom, Velvet Thorn,
Cassia, Grewia, Datura Arborea, Scarlet Cordea, Soap Berry, Screw
Pine, Date Plum, Sweet Olea, Tea, Coffee, China Privet, Jasmine
(2 kinds), Holly, Banksia, (3 kinds), Elder, Cotton (2 kinds), Cytisus,
Ash, Barbados Pride, Lion’s Tail, Osteospernum, Castor Oil, May,
Azalea, Gardenia (Cape Jasmine), Tutsan, Verbena, Furze, Wild
Bringal, Bamboo (3 kinds), Bamboo Reed, Plumbago, Camellia,
Fuschia, Madagascar Creeper, Passion Flower (5 kinds), Ivy, Wood-
bine, Melostroma.

“ Fruit-bearing Plants :—Peach, Apple, Pear, Cape Plum, Mango,
Chirimoya, Orange (Sweet), Orange (Seville), Lemon, Lime, Shaddock,

RAINFALL ON ST, HELENA, 123

Citron, Quince, Filbert, Grape, Pomegranate, Cocoa Nut, Date,
Water Lemon (purple), Rose Apple, Pine Apple, English and Spanish
Mulberry, Loquat, Banana, Apricot, Guava, Litchi, Melon, Cherry,
Indian Walnut, Chesnut, Fig, Papau Apple, Tamarind, Strawberry,
Wild Raspberry, English Raspberry, Blackberry, Cape Gooseberry
(Tomatita, vulgarly called Bilberry.”

Ships entering the harbour approach it on the eastern side of the
Island, to windward, and may sail with safety close on shore, the
water in the roadstead being deep, and there they may ride at anchor
at all times with perfect safety, there rarely being any wind so strong,
or sea so violent as to endanger their security. Opposite the
anchorage is the town of St. James. At the extreme end of the town
are a few pretty forest and vegetable gardens; and at the termina-
tion of James’ Valley is a waterfall, beneath which is a beautiful
spring whence comes all the water used for the supply of the town
and shipping. The water is clear and good. It is calculated that
seven thousand tons of water are daily discharged into the sea, The
number of springs in the Island are said to exceed two hundred,

I accept with faith the statements made to me, in regard to the
changes remarked at St. Helena as following the destruction and
replenishing of trees, mainly because of their general accordance
with what has been observed elsewhere ; but also in a great measure
from confidence in popular observations in regard to facts even
when I cannot assent to popular expositions of these facts as to
cause and effect.

The following remarks are results obtained from observations
made by rain gauges kept at St Helena :—

The total amount of Rain which fell at Longwood in the year 1848
was 45°630 inches, which appears to be rather more than the average
of eight years previous, which amounts only to 43-8 inches,

The month of October, during 1848, was the driest month of the
"year, being only 0°126 of an inch. January is the next driest month
0°720, and December 0°758 ; the two wettest months being June
7150 and July 9°245 inches,

Upon comparing the Registers kept at Longwood and Plantation
for 1847, it appears that the fall of rain was greatest at Plantation, it
there being 45°892 inches, and at Longwood 42°364 inches; January
and December being the two driest months of the year, June and
September being the two wettest months, when the sum of the two
months are taken, At Plantation the two wettest months were

124 EFFEOTS OF FORESTS ON MOISTURE.

June and July; at Longwood the wettest months being June and

September.

The amount of Rain which fell for the undermentioned years, was :
1841,...... 68925 inches. 1842,...... 90:458 inches.
1843,...... 37189, 1844,...... 20026,
1845,...... 19509 ,, 1846,...... 26:556. ,,
1847,...... 42,411 ,, 1848,...... 45630,

giving the mean annual fall, 43°813 inches.

“ Upon Examining the Monthly Register for these eight years, it
appears that October, November, December, and January, give the
mean driest months. The four wettest being March, May, June,
and July. The December of 1846 being the driest month of the
whole 96 months ; and the February of 1842 being the wettest month
of the whole period.

Professor Playfair states, that when the annual fall exceeds 25
inches, the climate is to be classed as moist: if so, St. Helena must
certainly be classed as a moist climate, because this standard, com-
pared with St. Helena’s average of eight years, is nearly in the pro-
portion of 25 to 43. The Professor also “ supposes” the annual fall
of Rain near London at 24 inches ; if so, St. Helena far exceeds London
in its fall of Rain, this being more than half as much again at St.
Helena as it is at London.

The four following observations, being the quantities of Rain
received at the respective stations for a period of nine months in
1841, are quoted as a confirmation of the theory that woods and
mountains tend to precipitate Rain :—

1, At 2644 feet elevation 22°63 inches.

2, At 1991 4 oil ,
3, At 1782 » 492 ,
4, At 414 ie 763,

The whole four stations being comprehended within a circle of little
more than a mile radius.

These statements I give as I have received them. So much
depends on the locality and circumstances in which observations by
the rain gauge are made that I am unable to say whether they tend
to strengthen or to weaken the conclusion to which I have come.

The Island of Mauritius supplies analogous facts. In a history of
that Island, embodied my informant believes in Thornton’s History
of India, the author observes that when we obtained possession of it
our countrymen thought it absurd that the beautiful land on the

STATE OF MAURITIUS, 125

suzomits and slopes of the mountains should be abandoned to forests
and jungle, and so cut them down, upon which the water supply
began to fail, Reflection soon taught the authorities the cause of
this failure ; upon which the hills were again planted with trees, and
the rivers and streams resumed their former dimensions.

Mr Marsh writes :—“ The Island of Mauritius lying in the Indian
Ocean in about 20° N. L., is less than forty miles long by about
thirty in breadth. Its surface is very irregular, and though it con-
sists, to a considerable extent, of a plateau from 1200 to 1500 feet
high, there are three mountain peaks ranging from 2300 to 2700
feet in height. Hence, though the general climatic influences are
everywhere substantially the same, there is room for a great variety
of exposures and of other purely local conditions. It is said that
the difference of temperature between the highest and lowest stations
does not exceed eight degrees F, while, according to observations at
thirty five stations, the rainfall in 1872 varied from thirty-three
inches at Gros Cailloux to one hundred and forty six inches at Cluny.
Nature, September 24,1874. This enormous difference in measure-
ment is too great to be explained by possible errors of observation or
other accidental circumstances, and we must suppose there are, in
different parts of this small island, great differences in the actual
precipitation, but still much of this variation must be due to causes
whose range of influence is extremely limited.”

Mr Meldrum, Director of the Mauritius Observatory, read a paper
before the Scottish Meteorological Society in July, 1866. In this he
stated that for some years before there had been severe droughts in
the island, and recently there had been severe outbreaks of fever,
which had carried off one-tenth of the population. A careful analysis
of meteorological observations that had been made showed that from
1861 to 1866 there had been a great diminution in the rainfall. So
far as could be discovered, the rainfall was less than during any
similar period since the island was discovered. This could only be
explained by the cutting down of large forests in the interior, no less
than 70,000 acres having been denuded of trees during the ten years
from 1852 to 1862. Mr Meldrum concluded by saying that the
calamities which had so seriously affected the people of the Mauritius
seemed to be self-inflicted; and that the proper remedy was to
restore the forests of which the once salubrious and beautiful island
had been deprived. And in a communication published in the
Journal of the English Meteorological Society for that year there is
given additional information on the subject. In this ho states,

126 EFFECTS OF FORESTS ON MOISTURE.

“That the rainfall in that island during the five years 1862-66 was
considerably less than during any previous five years of the whole
period since 1853 ;”—“ that during the first five years, from 1853-
57, the relative humidity of the air was 72:1, whilst during the last
five years, 1862-66, it was only 68-2 ;”—“ that the vapour pressure,
which in the earlier of these quinquennials was ‘657, had fallen
during the latter given quinquennial to 638.”

Notwithstanding these facts, he says :—“ In no former year of the
period of fourteen years did such floods occur as in 1861 and 1866,
or such severe droughts as in 1865 and 1866.” And to account for
these facts, he says:—“That the decrease of rainfall, humidity,
and vapour pressure, and the occurrence of floods and droughts, may
in some measure be due to the cutting down of the forests, which
commenced on an extensive scale about 1852, was vigorously carried
on till 1862, and is being still prosecuted, though to a smaller
extent.”

One chief cause of the cutting down of the forests in the Mauritius,
Mr Meldrum states thus :—‘“ Proprietors of forests in high and
remote parts of the island, where the climate was as yet too damp
and rainy for the sugar-cane, engaged in the work because they
believed that their land would thereby become more fit for such
crops ; for it was very well known that the climate became drier in
proportion as the forests were cut down. Upon the whole, I think,
at least 70,000 acres, or about one-sixth of the entire area of the
island, have been denuded of forests since 1852, and that, too, on the
central and elevated parts of the island, at or near the sources of the
rivers.”

He points out how, by the lowering of lakes, and the complete
desiccation of others, malatia resulted, and a deadly epidemic. And
the remedy which he suggests is, “to restore, as far as practicable,
certain portions of the forests of which this once salubrious and
beautiful island has been deprived.”

In 1871, a report was issued by Dr H. Rogers, of Mauritius, “On
the Effects of the Cutting down of Forests on the Climate and Health
of Mauritius,” This report I have not seen ; but ina lecture on Forest
Culture in its relation to industrial pursuits, delivered in Melbourne
on the 22d June, of that year, by Baron von Miiller, Government
Botanist in Victoria, there was given the following resumé of its
contents, with the remarks which follow: So late as 1864 the Island
was resorted to by invalids from India, as the “ pearl” of the Indian
Occan—it being then one mass of verdure, But when the forests

PLANTING ON MAURITIUS. 127

were cleared, to gain space for sugar cultivation, the rainfall
diminished ; the rivers dwindled down to muddy streams; the water
became stagnant in cracks, crevices, and natural hollows, while the
equable temperature of the Island entirely changed’; drought was
experienced in the midst of the ocean, and thunder showers were
rarely any longer witnessed. The lagoons, marshes, and swamps,
along the sea-board were no longer filled with water, but gave off
noxious gases; while the river waters became impure from various
refuse. After a violent inundation in February 165, followed by a
period of drought, fever of a low type set in. Against this the
remedies employed in ordinary febrile cases proved utterly valueless.
From the waterless sides of the lagoons pestilential malaria arose.
Exposed to this the labourers fell on the field, and in some instances
died within a few hours. Scarcity of food among the destitute
classes, and inadequate sewage arrangements, predisposed also to the
dreadful effect at the time. It is alleged, and maintained, that
marshes should either be drained out completely, or kept constantly
submerged. And Dr Rogers insists that, for sanitary reasons alone,
the plateaux and high lands of Mauritius must be replanted with
trees.

To what extent this may have been done, and with what results,
remain to be seen.

In Chambers’ Journal it was mentioned in the beginning of 1875,
apparently on the authority of the transactions of the Royal Society
of the Mauritius, that with a view to check the increasing dryness of
the climate 800,000 trees had been planted, and 150,000 seed holes
prepared on barren mountain slopes and other waste places. And
we have the following statement in regard to what appears to have
been a prior application of the remedies proposed :—“ The hills were
again planted with trees, and the rivers and streams resumed their
former dimensions.” *

*A letter from Mr A. St. John, who had given attention to the subject, and had been
asked by Mr Fox Wilson for testimony which he might adduce in his paper “‘ On the
Desiccation of the Basin of the Orange River,” in support of views held by them both,
has been put into my hands. In this it is said:—‘“‘It is Thornton, 1 believe, in his
‘History of India,’ who gives an account of the drying up of the springs in the
Mauritius; and the Journal of the Indian Archipelago, published by Logan at
Singapore, supplies information about the Island of Penang. . . .. - I am
confident of the information retained in my memory, though I may not always be able
to point out the source from which it was obtained ; for example, I am perfectly sure
that the writer, who as I have stated I think is Thoruton, that gave the history of our
conquest of the Mauritius, observes, that, when we obtained possession, our country-
men thought it absurd that the beautiful land on the summits and slopes of the

128 EFFECTS OF FORESTS ON MOISTURE.

Reference is made to the Island of Ascension by Boussingault, in
his work entitled Heonomie Rurale considerée dans ses Rapports avee
la Chimie la Physique et la Mineralogie, in a passage which has been
cited, in which he says :—“ In the Island of Ascension there was an
excellent spring situated at the foot of a mountain originally covered
with wood. This spring became scanty, and at last dried up, after the
trees which covered the mountains had been felled. The loss of this
spring was ascribed, and rightly so, to the cutting down of the timber.
The mountain was therefore replanted, and a few years afterwards
the, spring reappeared by degrees, and by and by flowed with its
former abundance.”

When I was at the Cape of Good Hope, the Hon. Mr Barrington,
of Belvidere, on the Knysna, wrote to me in regard to Ascension, that
on that island, the driest of the dry—spoken of sometimes as a heap of
cinders, which only could be maintained as a naval station by sending
to it water in tanks from England and from the Cape—trees and
culinary vegetables had been planted, and had been grown with
success, through instructions supplied by Sir Wm. Hooker from Kew}
and that, since this had been done, not unfrequently had the island
been seen capped with a cloud, and little runnels of water had been
seen trickling down the sides of the rock. I have always understood

mountains should be abandoned to forests and jungle ; and so cut them down, upon
which the water supply began to fail. Reflection soon taught the authorities the cause
of this failure ; upon which the hills were again planted with trees, and the rivers and
streams resumed their former dimensions,”

In the same letter the writer says :—‘‘ I have deferred answering your letter in the
hope of being able to consult some of the works which supplied a portion of the
material for my article ‘On the Failure of Springs ;’ but I have not been able to do
what I intended. What I say of the drying up of four hundred springs in Persia is on
the authority of Tavernier ; but as the copy I possess of that traveller has no index, I
canuot at once find the passage, though perfectly certain that it occurs in his account
of the Northern Provinces. . . , . Formerly, in my ‘ Manners and Customs of
Ancient Greece,’ (II, 370), I pointed out the disforesting of the mountains as the cause
of the drying up of streams and rivulets in several parts of the country, and of the
diminishing of nearly all the rivers. Democritus, many centuries before Christ, had
made the discovery that woods and forests are necessary to the maintenance of springs ;
and in the last century, Volney contended that the Sahara might be rendered fertile iy
planting it with such firs as would grow in sand, which would attract and retain
moisture. I make not the Icast doubt that in the Transgariep portions of Southern
Africa, to which you refer, the diminution of moisture was occasioned exclusively by
the cause you point out, and not by any cosmical changes, as imagined by Livingstone.
Should the Government, as far as its authority extends, ordain that whenever trees are
cut down others should be planted in their place, aud generally encourage the multi-
plication of woods and forests, I make no doubt that that whole region would be
abundantly supplied with moisture.” ,

STATE OF ASCENSION 129

that the copious supply of water in Capetown was derived, not from
rainfall and surface drainage, but from the percolation, through the
four thousand feet thick filtering stone, of moisture absorbed from
what is called the Tablecloth, often seen on Table Mountain when
the south-east wind blows in the summer months; and there seemed
to me nothing unreasonable in the information supplied by Mr
Barrington. He. derived his information from the late Commodore
Burnet, who had been stationed at the Island, who stated that for a
long time the garrison and the shipping had had a good supply of
water; and he (Mr Barrington) stated that when he himself saw it,
which was in 1861, the summit was enveloped in mist the whole day.

I subsequently obtained through Dr Hooker, who had succeeded
his father as Director of the Royal Gardens at Kew, a copy of the
report made in 1862 by Capt. Barnard when in charge of Ascension,
with a lithographic plan of the Island, illustrative of what had been
then accomplished, which had been published at his suggestion by
the Lords of the Admiralty, that the public might know something
of the altered “ condition of that curious and now important island,
due to the encouragement given by the Admiralty, through the
instrumentality of Commodore Burnet, and more recently by the
intelligence and zeal of Capt. Barnard and his indefatigable assistant,
Mr Bell.” And he goes on to say, in support of his suggestion :—“ J
doubt if there is any spot in the world where a comparatively barren
rock,—destitute of all natural useful vegetation, exposed to the most
terrific and injurious sea breezes,—has been, or could have been,
brought into such a state of useful cultivation.”

The plan shows a great many patches, measured as many of them
by poles as by acres, but measuring in the aggregate twenty-nine
acres, covered with furze and shrubbery, and upwards of twenty-seven
acres of land under cultivation, bearing crops of potatoes, sweet
potatoes, cabbage, carrots, pumpkins, turnips, endive, beans, leeks,
grass, pine apples, bananas, guavas, figs, oranges, shaddocks, mul-
berries, and sugar-cane.

It appears that a number of seeds consisting of acorns, horse
chesnuts, Spanish chesnuts, etc., which had been previonsly sent,
had been spoilt, probably by being stowed away on ship-board in a
damp hold ; but simple measures were adopted to prevent the recur-
rence of this, and by terracing, excavating, and levelling every little
patch capable of cultivation, the most was made of every advantage
which could be commanded on the island.

The whole report by Captain Barnard is full of details illustrative
M

130 EFFECTS OF FORESTS ON MOISTURE,

of that indomitable energy and contrivance which we proudly allege
to be characteristic of our nation. ;

This I shall immediately quote at some length; but what chiefly
concerns us is that, apparently by vegetation, there was secured
sufficient humidity to promote vegetation, and this in such abundance
that a cloud capped the mountain supposed never tv have been seen
so capped before, and rills of water ran down rocks supposed never
to have been bedewed with such tears within the memory of man.
When every allowance has been made for suspected exaggeration of
previous aridity, and of humidity attained, there remains still a fact
to encourage the hope that by the extension of forests an increased
humidity may be secured.

In 1864 there were published by the Government the following
observations on Ascension, by Captain F. L. Barnard, R.N. :—

“ Ascension is in latitude 7° 56'S. and longitude 14° 24’ W. It
ig about 74 miles in length and 6 miles in breadth, and is within the
immediate influence of the S.E. trade wind. The island is entirely
volcanic, the surface being broken into mountains, hills, and ravines.
It was discovered by the Portugese in 1501, but remained uninhabited
until after the arrival of Napoleon at St, Helena, when it was
occupied as a post by Sir George Cockburn, and placed on the
establishment of a sloop of war, under a lieutenant. In 1822 the
naval garrison was relieved by a detachment of marines under Major
John Campbell; since which it has gradually been increasing in
importance, and I propose tracing its rise, progress, and present
capabilities from valuable notes left by my predecessor Captain W. F,
Burnett, C.B., and the records in office.

“ But little information remains.on record between 1815 and 1824,
in which latter year Lieut.-Col. Nicolls arrived to take command. The
number then victualled was 59. Mules and donkeys were the only
draught animals, and sheep and bullocks were then first applied for.

“The supply of water was scanty and precarious, and even in 1829
it depended on drips in the banks, and the rain that was collected in
casks and a few old tanks. Three carts, six oxen, and three drivers
were employed daily in transporting about 360 gallons a distance of
six miles, and even this quantity was liable to a considerable
diminution after long droughts. When Dampier’s vessel, the
‘Roebuck,’ foundered near Ascension in 1701, he discovered springs
or drips by watching where the goats went to drink; and in 182
attention was called to three of these, viz., Middleton’s, the Mountain

WATER ON ASCENSION. 131

or Breakneck, and Dampier’s. Iron water pipes were applied for to
lay down between the Mountain and garrison, where there were tanks
capable of containing 40 tons only.

“In July 1825 a boring machine arrived, and tanks and reservoirs
were commenced on a large scale; but the latter, from subsequent
accounts, seem to have been mere excavations, from which the water
soaked away in a few days.

“ Boring was first commenced in 1826 above Middleton’s springs,
by Colonel Nicolls, without any important results. In 1829, Captain
Bate reported the possibility of supplying the African squadron with
water, proposing certain measures, and Captain Brandreth, R.E.,
was instructed by the Admiralty to make a survey and report of the
island. He found that the auger of the boring machine had been
introduced nearly horizontally in the direction of the substratum,
which would merely have the effect of causing the stream to flow
more freely without arriving at the source of the spring. Captain
Bate had also bored near high-water mark by the advice of a foreign
naturalist, and from the wells then made the present supply of salt
water is derived. Unsuccessful borings were made in the low lands,
and others were recommended in the Mountain district. Captain
Brandreth reported favourably on Captain Bate’s propositions, and
returned to Ascension in 1830. Finding that the stock of water was
reduced to 40 tons in consequence of a drought during twelve or
fourteen months, he pressed for further experiments in boring, and
fixed on a spot high up in the Mountain district, on the weather side,
at the bottom of a ravine, the sides of which were 80 feet in height.
The strata consist of volcanic matter on beds of clay. The
experiment succeeded, and at the depth of 25 feet from the surface
a spring was found ; the shaft was sunk 60 feet, and still yields (in
1864) from three to four tons daily, even after a long drought. A
second shaft was subsequently sunk about 100 yards from the first,
and produces an occasional supply only. In the latter end of 1830
the main water pipes were partly laid down.

“ Palmer’s springs were discovered 500 feet below the drips in
Breakneck, and were said to produce 2,000 gallons in24hours Two
large reservoirs were constructed by building up a deep gorge in
terraces, which receive the water from an extensive rocky valley, but
there is no spring in my opinion. Drinking troughs have been con-
structed here and at Middleton’s ; they supply the island-bred cattle,
and wild animals with water, which at the latter is brackish, and
does not agree with imported beasts, The marines used to take it

132 EFFECTS OF FORESTS ON MOISTURE.

medicinally in cases of dysentery. There is a neat cottage at
Palmer's, in which a man and his wife reside, and take care of a
garden producing chilies and pumpkins.

“In December 1831 the main pipes were finished, being led from
Bate’s tank at Dampier’s, 5 miles distant from the garrison, and 1000
feet above its level, and the same depth below the Mountain tank.

“Tn January 1832 an octagon iron tank, capable of containing 20
tons, was placed under the drip in Breakneck Valley, and in the same
year a tnnnel was cut through the mountain about 930 feet long, for
pipes to convey the water, which was pumped by horse power, and
forced up 140 feet into an iron tank above the level of the reservoir
on the other side of the mountain. The tunnel is sufficiently wide
and high to admit of people walking through with ease, and is a
wonderful proof of the perseverance and skill of the marines, who,
under Captain Payne, executed it in the short period between 19th
May and 3rd October of the same year. The principal and only
certain supply of water is obtained through this.

“InFebruary 1847 there was a great scarcity of water, and distilling
was first commenced with Clark’s apparatus, but as salt water was
obtained from a well sunk in the square, affected by the ebb and flow
of tide, the supply was limited and uncertain.

“T found the drips in 1861 much in the same state as they appear
to have been in 1832, and shall describe the present water resources
of the island, the steps that have been taken to improve them, and
the planus I would suggest to ensure an adequate supply.

“The drips and wells in Breakneck Valley are the only sources that
never entirely fail, although the yield is considerably less after a long
drought ; the drips are caused by the rain and wet fogs, arrested by
the steep sides of the ravine, and percolating through the cinder to
strata of rock, which crop out and form ledges. Under these, lengths
of zinc and iron sheeting were placed, conducting the water in driblets
to'a small cemented trough over the octagon tank, which occasionally
overflowed after heavy rains, and at all times the labour of forcing a
column of 140 feet of water was very distressing to animals, and
absorbed much labour.

“In the latter end of 1863, a wind engine of 14 horse power, by
Bury and Pollard, was erected near the octagon tank ; the pipes were
connected throughout their whole extent, as they were fonnd to be
too much on a dead level to carry off the water forced up, and we had
the satisfaction of finding that it worked admirably, and was capable
of doing much more when required,

SUPPLY OF WATER ON ASCENSION. 133:

“ Extensive troughs lined with Roman cement have replaced the
odds and ends of old sheeting, preventing waste and increasing the
yield of water, —

“The wells which were sunk in the spots selected by Captain
Brandreth are worked by hand pumps daily, and produce sufficient
water for the consumption of the Mountain after many months of
drought. Iam, therefore, of opinion that the upper one is supplied
by a bona fide spring, and without it much inconvenience would be
frequently experienced.

“The roofing surface has of late been greatly increased, and iron
tanks have been placed in convenient places for the supply of the cow-
house and stables, by which both manual and horse labour are saved.

“ Finding that a considerable rush of water from the mountain roads
found its way into Dampier’s tank in a very muddy state, large
cisterns have been constructed, with underground drains between
them, the last being connected with the main pipes just below the
Mountain reservoir. A great mass of mud and cinder is deposited by
these means, and the water eventually reaches its destination in a
comparatively clean state. In connection with this arrangement all
the upper roads, which were composed of soft light cinder, liable to
be washed away, are being paved with durable stone.

“The drip at Dampier’s is scarely worth taking into account, as it
dries up soon after the rain ceases, and produces nothing when most
required.

“To prevent the waste necessarily caused by frequently running
down small quantities of water from the main tank at Dampier’s
(Bate’s), drinking troughs have been sunk on the spot and are supplied
by means of a small fire engine.

“The cattle that are not being stall-fed are driven in every morn-
ing for food and water ; and there have been no losses amongst the
imported cattle since this system has been adopted.

“Tn 1861 Dr. Normanby’s distilling apparatus arrived in H.MLS.
‘Isis,’ and in the beginning of 1863 pipes were laid down to it from
the sea, affording an ample supply of salt water, which is pumped up
a heigat of 25 feet by means of a simple and ingenious contrivance
of Mr Smith, the superintending engineer. A small eccentric on the
shaft of the donkey engine works a number of levers which pump the
salt. water into a tank, and the fresh water into a reservoir when the
receiver is full, By attaching a strap to the fly-wheel a chaff cutter
is also worked in an adjacent building. The produce of water is
about one gallon per minute.

134 EFFECTS OF FORESTS ON MOISTURE.

“Such are the water resources of the island, which have not more
than kept pace with the increase of the population, from 59 in 1854 ;
to an average of 550 in 1863 ; and after three years’ experience and
much painful anxiety, with the necessity of reducing the allowance
to a gallon for each person during upwards of six months, I would
urge the paramount necessity of ensuring an aduquate supply.”

The details of hydraulic works proposed by Captain Barnard I do
not deem it necessary to quote. After giving them, he proceeds :—
“IT have found but little reliable information respecting the former
cultivation of the island; but with the assistance of memoranda left
by Captain Burnett, records, and my own experience, I shall describe
its present state and capabilities of improvement.

“ Like Captain Brandreth, I shall divide the island into four parts,
with reference to its agricultural capabilities.

“ The first, consisting of about 200 acres, on the highest lands round
the Peak.

“ The second, of about 800 acres, lying below the Peak, from 2,200
feet to 1,400 feet above the level of the sea.

“The third part, comprising tracts of cinder and ashes, with inter-
vening watercourses about the lower lands,

“The fourth takes in extensive beds of lava and cinder, not likely to
undergo any change, but which produce purslane and other food, on
which herds of wild goats feed and keep in good condition.

“This part comprises the Peak of Green Mountain, with all it
surrounding ravines and hollows, from a height of 2,820 feet to Elliot’s
Pass, about 2,200 feet above the level of the sea. At the summit is
a small piece of table land, on which the Bermudian cedar, guava,
hibiscus, and other shrubs flourish ; it is frequently enveloped in mist,
and with the exception of a running grass gathered by the Africans
for the cows, it is covered with a long wiry sedge used for stable
bedding only. Orange trees brought with great care from Rio and
the Cape of Good Hope, have been tried on the N.E, side, where the
soil is deep and good, but without success ; they appeared to flourish
for a season, but soon began to droop and wither away ; consequently
all that retained any signs of life were transplanted into a nursery,
where they must remain until the weather is favourable for putting
them into sheltered spots in the ravines where lime trees flourish.
Numbers of trees and shrubs have been planted by the sides of the
path leading to the Peak since Mr Bell’s arrival in 1857. They look
healthy and strong, and the more tender ones are protected by tree

PLANTING ON ASCENSION 135

guards. A list of them is annexed. . . . . A tin trough
placed under one of the wattles for the pheasants to drink from, has
water in it during the driest seasons, affording a proof of how much
moisture is attracted by planting. The above is enclosed on the
sides accessible to cattle by a fence of cask staves.

“We now come to a second enclosure planted with a double row
of pinus excelsa, which are growing well. Buddlea, vitex trifolia,
gorse, broom, and brambles, border the path in one thick mass, with
the beautiful crimson flower of the hibiscus peeping through the
foliage. Between the base of the High Peak and the Little Peak is
a bare ridge exposed to the strong trade wind, producing sedge and a
few stunted shrubs. The Little Peak is enclosed by a bank and
ditch, and is cultivated all over, producing light and uncertain crops
of English or sweet potato. To leeward of and below it, shrubs grow
luxuriantly, and an excavation has been converted into a nursery, but
the soil is dry and porous, and tender plants do not survive even a
short drought in it. Pine apples have been planted, and will probably
succeed here. There is also a fine lime tree, whose roots have found
their way into a fissure in the cinder; it consequently flourishes,
whilst every attempt to grow others near it has failed.

“ All the first division is planted sufficiently, and nothing is
required but attention to the growing trees and shrubs, and keeping
the fences in repair. It is surrounded by Elliot’s Pass, a road cut
out of the solid cinder, and passing horizontally quite round the
Mountain, which at several points is tunnelled through. It affords
great facilities for planting the sides of the mountain and ravines—is
a convenient path for the shepherds, and a pleasant walk of about
three miles, lined with blackberry bushes bearing plenty of fruit, and
numbers of trees and shrubs.

“‘ The ravines present the appearance of dense thickets, bramble,
buddlea, vitex, etc., having completely clothed them. Thousands of
small birds flock about the bushes, and are increasing wonderfully ;
they consist almost exclusively of avadavats introduced by Captain
Burnett. This pass was commenced in 1339 by Lieutenant Wade,
Royal Marines, and completed in January 1810. In 1861 about 600
yards of the path on the weather side were considerably widened by
Captain Barnard.

“The second and most important division commences below
Elliot’s Pass, adjoining which are the farm buildings, consisting of a
a cow-house, fodder store, and stock yards, witL slaughtering triangle,

and every convenience for stall-feeding oxen, penning sheep, and

136 EFFECTS OF FORESTS ON MOISTURE.

‘gaving- manure for the cultivated lands, a great part.of which in 1861
had been constantly cropped with sweet potatoes and its fertilizing
powers extracted. The farm buildings were so scattered and ill
arranged that no great body of manure could be collected. All the
slaughtering was carried on in the garrison, and the offal thrown into
the sea. I made a completé change in the system ; built a fodder store,
demanded chaff cutters and oil-cake crushers, formed large yards,
‘adjoining the cow-house by excavating, did away with detached sheds,
and connected a sufficient number of iron tanks to ensure a constant
supply of water on the spot.

* All crops are most uncertain excepting sweet potatoes, which,
unfortunately, are not generally liked as a vegetable, and cannot be
used in soup. Regular and large sowings of English potatoes are
now made, and several good crops have been obtained ; the arrange-
ment for thoroughly manuring the ground once in two years evidently
‘tending to restore fertility to the soil, for the sweet potatoes even
come to perfection in less time than they did before. Great losses
must be expected from the ravages of caterpillars and long droughts,
but the system should be persevered in, if only for the purpose of
introducing something like rotation of crops, not hitherto much
studied. The best seed potatoes have been obtained from the Cape
of Good Hope; they are red, and about the size of walnuts. Some
from Loanda have also turned out very well. Supplies according to
demand are sent by the contractors for cattle from Table Bay every
two months. The seed saved on the spot is worthless. Pumpkins
grow to a large size in the weather gardens, weighing upwards of
‘80 lbs. ; they are propagated from cuttings. Great efforts have been
‘made to grow cabbages in large numbers, but the caterpillars destroy
nearly all the seedlings, and there are never sufficient for a general
issue. French beans succeed better than any other vegetables when-
ever the droughts do not last long ; about two out of three sowings
fail. Now and then a fair crop of turnips may be got, but carrots
are a long time in growing, and never attain even a moderate size.
The New Zealand spinach grows wild amongst the other crops, and at
times is gathered in large quantities. No other vegetables are grown
in the sheep walk or weather gardens.

“Guano has been twice obtained from Boatswain Bird Island, and
seemed to produce good crops of sweet potatoes, but stable and farm
manure is better, and more easily obtained.

“Tn the Home gardens about the Mountain cottage, leeks are pro-
duced plentifully, as well as French beans, lettuce, endive, and herbs,

PLANTING ON ASCENSION. 137

Pine apples have been propagated successfully of late years, and are
well flavoured.

“ All the ground available for planting is in detached patches, and I
find, on searching the records, that detailed descriptions of that under’
cultivation, up to the end of 1859, have been forwarded to the Secretary
of the Admiralty. Since I took charge in July 1861, I have turned
my attention to the possibility of breaking up new ground and culti-
vating English potatoes, cabbages, and the vegetables usually issued
with fresh meat. The difficulty of finding any sufficiently level and
sheltered is great, and I have had recourse to excavating on the side
of the mountain, One piece now in progress, on the same level with
the home gardens, will have a back of 44 feet. I have also converted
what was formerly a stock yard into a garden, and have a very
promising crop of Jersey potatoes well up. As we can find labour, I
purpose terracing a very promising piece of ground under the weather
gardens, above a patch on which cabbages have been successfully
raised. My predecessor enclosed a space on a rather steep slope,
containing about an acre, which will be broken up, if the dry weather
lasts ; it will be fit only for the sweet potato, which is the staple
produce of the island, and flourishes even in the driest seasons, but it
is not prized by the men. . . . . . There is no limit to
the broken ground available for the planting of shrubs, and during
the dry season a party is constantly employed digging holes four feet
wide, three deep; there are upwards of 1,000 now open for the
reception of the Australian wattle, to be planted between Michaelmas
and Lady-day. This shrub has been most successful at Ascension,
and in a few years will change the aspect, and probably the climate,
of the island, from its rapid growth and facility of propagation. I
lately measured one that was planted last November twelvemonths,
in the shape of a small layer, and it is now from six to seven feet
high, covering a circle with a circumference of 36 feet ; about 1,000
of these have been planted within the last three years.

“‘Mr Bell fortunately hit upon the simple plan of laying the small
branches into preserved meat tins, butter firkins, and boxes, in which
they can be carried to any distance ; they already flourish much lower
than any other tree or shrub, and had we not lost our last season
from an unusual drought, many more would have been planted lower
still; there are upwards of 1,000 now ready. I have entered into
the above details to show that the wattle has greatly reduced our
requirements, and I constantly receive, from private sources,

loquats, guava, orange, lime, and wild fruit trees, from the Cape of
N

138 EFFECTS OF FORESTS ON MOISTURE.

Good Hope and the coast. The date palm, coffee bush, and custard
apple look healthy and strong in their seed beds, and thousands of
young shrubs and trees, from the Peak down to the level of the home
gardens, are making rapid growth, whilst the furze, bramble, and
other shrubs fill the deep ravines and fissures with a luxuriant foliage,
affording good cover for game. Pine apples have arrived to great
perfection under Mr Bell’s treatment, and we are making fresh
plantations from time to time.

“Of all things we most require conifers, and find that various
attempts have been made by my predecessor to obtain seeds. The
following advice in a letter from Dr Lindley to the Comptroller of
Victualling, dated Acton Green, August 20, 1860, if acted upon would
be of great service to the island :—‘ Mr Bell finds by experience that
of all trees the most useful to plant on the mountain slopes are
conifers. In this I concur, and I would advise their Lordships to
send out a supply of Chilian Araucarian and Norfolk Island pines,
most especially the former, which form forests on the southern face
of the Chilian Andes in precipitous places, where they bid defiance to
storms. Any quantity of the seeds (Chilian Araucarian Pine) could
be procured through the English Consul at Valparaiso, Mr Rouse,
who, however, should be instructed to take care that the seeds are
fresh. The Indians bring them to market, but sometimes so old
that they will not grow.’ :

“Thope to be able to get Norfolk Island pine cones, and Australian
trees and plants through my predecessor, Commodore Burnett ; they
all do well at Ascension.

“The Bermudean cedar grows most luxuriantly at the Peak, and
a parcel of the seed would be most acceptable. Scarcely any trees
or shrubs bear seed here.

“ As Sir William Hooker takes a lively interest in the cultivation
of the island, he may like to know what steps have been taken to
carry out his valuable suggestions, as well as those of Dr Lindley
and Dr J. D. Hooker, which I have found amongst the Records.

“ Finding a great scarcity of manure, and no facilities for carting
it up from the garrison, I shortly after my arrival commenced stall
feeding, and slaughtering the oxen at the Mountain, and have now a
most valuable heap of manure ready for our worn land.

“T next procured a quantity of guano from Boatswain Bird Island ;
this, from its great portability, will be a great boon to usif it succeeds,
which I have every hope of its doing from the healthy green and
luxuriant foliage of a large breadth of sweet potatoes manured with it.

PARA GRASS ON ASCENSION. 139

“Mr Bell frequently accompanies me in searching for eligible spots
for establishing fresh patches of vegetable ground, and by the aid of
terracing, as we can command labour, I feel confident that an ample
supply of cabbages, leeks, and at times potatoes, can be commanded.

“Mr Bell having represented to me that numbers of young shrubs
and trees required protection when first planted out, I have caused a
large number of guards to be constructed from firewood and the hoops
that come off the trusses of hay ; they answer most admirably.

“These plans, combined with the system of layering adopted by
Mr Bell, and the breaking up of new ground, will, I feel convinced,
do all that is possible for the cultivation of the Mountain, which is
capable of spade labour only.

“The cones of the pitch pine from the Bahamas ordered by their
Lordships to be forwarded to Ascension, upon Sir William Hooker’s
recommendation, will, in all probability, succeed, and I shall be glad
to get them,

“ Having described our requirements and plans for the cultivation
of the mountain, I think an account of an experiment on a large
scale, which we are making on the north-east plains, may be
interesting to Sir William Hooker.

“In a document from Mr Bell to Captain Burnett, dated October
1859, I find these plains described as having been cleared and culti-
vated twenty years before, but in consequence of the loss of horses,
and frequent failures of the crops, they were abandoned and con-
sidered barren and useless.

“However, on searching the records last year, a letter was dis-
covered bearing’ date 31st August 1849, from the Secretary of the
Admiralty, acquainting the captain in charge that Sir William Hooker
intended to forward a case of most excellent grass for fodder, known
by the name of ‘ Para;’ accompanying this letter was a description
of the grass and its habits,

“At Ascension it is doing wonders, increasing in the most
astonishing manner, and growing down all weeds and inferior grasses
wherever it is once established. Patches of it were tried on the No. 2
plains, and made not only rapid growth but resisted a drought of
several months, though exposed to a tropical sun and the full force
of the south-east Trade.

“Ploughs and harrows having been promptly supplied at my
request, we took advantage of a spare team, and a colt that required
breaking in, to plough and harrow these plains, and, much to our

atisfaction, fourd them to be covered with a rich friable loam.

140 EFFECTS OF FORESTS ON HUMIDITY.

With protection, crops of every description might be grown here,
but, in the absence of horse and manual labour, to collect the rocks
and boulders which abound on the surrounding hills, and would form
excellent dry walls and well-sheltered enclosures, we are planting
from six to eight acres with Para grass in fine showery weather. If
it succeeds, we could have fine pasture lands for cattle in a short
time, and there is every facility at hand for constructing drinking
troughs. I am also trying a small patch with English potatoes,
fenced for the purpose. The method Mr Bell is adopting for planting
this grass is by cutting turf into junks, which are carried to the spot
in bread bags, on the heads of Africans, and trod in at equal distances ;
the runners grow by inches in one week after rain, and form a perfect
mat which no animal can root up. Men are daily employed collecting
Para grass for the beasts and cattle, both at the mountain and at the
garrison, and it materially saves the expensive oat straw sent from
the Cape. If Sir William Hooker could obtain a bag of the seed it
would help us greatly. Should it at any time be thought advisable
to bring a much larger breadth into cultivation for vegetables than
can be obtained at the Mountain, I could fence in many acres on the
weather slope of a valley formed by two ridges of these plains for the
expense of about four additional rations for donkeys to draw the
stones on sleighs, but with our present command of labour I could
not attempt it. If the Para grass succeeds, there are other large
plains, containing hundreds of acres, capable of being converted into
pasture land.

“Tn conclusion, I think it due to Mr Bell to state that the whole
of the farming and gardening operations under his care are carried
on in a most systematic and skilful manner. He combines the
experience of three years with considerable tact in managing the
Africans.

“T dwell upon this rore particularly, as there appears to be a
growing interest in the cultivation and general improvement of
the establishment at Ascension, and operations might be more
readily and economically undertaken at present than with a new
gardener, who would have everything to learn ; and, on my part, I
am quite willing to devote as much attention to this branch of my
duties as I can possibly spare.”

There was appended the following Table, showing the quantity of
cultivated ground on the island of Ascension, in what way laid out,
and present crop :—

LAND UNDER CULTURE ON ASCENSION. 141

In what way laid out.
Furze and
Cultivated,
Shrubbery. ‘s .
Name of garden and En- | Present Crop in the Caltivated
closure. i stl ae Land,
ABBR
S/F |S) 2/2) e
ee | f

The HighPeak . .| 6, 3/29;—]—)/—|—\—

Little Peak . «|| 3/88/15 |—] 3! 8]— | Enelish potatoes; seed obtained
from Jersey.

Weather Gardens. .| 1] 3| 9;20) 7|—/!10]— | Sweetand English potatoes, Cab-
bage, carrots, a and
turnips; three acres fallow.

Sheep Walk “ —{—|—|— }12! 2|21)— | Sweet potatoes, and two =

agooks, pine apples,
bana, &., endive, Freneh
beans, and carrots.

Home Gardens all ed — |} 1]/—{|12}|— | Leeks, herbs, seedling date palm
and coffee, &., &c. ; one acre
fallow.

Outer boundary of uae

Home Garden . —!| 1})16!17) 1] 1) 9! 8 | Turnips and d English potatoes.

Hospital Garden . —| 2) 4)— |—]j—] 24| — | Cuttings of shrubs.

Sugar Cane Patches . | —/—/]—j|— | —|—| 29/12 | Sugar cane.

Caldwell's Fruit Ravine } —|—|—j;— | 1] 2] 1/18 | Guavas.

Jumper’s Ravine - | —}—}]—{}—}—|—] 13 }18 | Bananas.

Broad Ravine i ame i ome mee nd i cc alt

locks.

Narrow Ravine . —{-|-j- == 20| 5 | Bananas, shaddocks, and large
_, pandanus.

Black Rock Ravine -}]—,;—|—|] 1) 216,10 s (the principal
ravine).

Tobacco Garden Ravine | —}—|—|— |—| -| 3}— Peneme ead ilg, DaEnes

ita] Ravine —}|-J]-—|-—|-—|]-—!-] 3

‘Weather Patches —j-f—j—|]—-]-—; 44;19 Facauae sbnanitiondiel

Mulberry Run —{—|{—'—|—|—| 3/16 | Bananas and sugar cane.

Cane Ravine % —!—j;/—|]—]—|—| 38|— | Bananas and sugar cane.

Palmer's Springs . 2} 3] 3112 |—|—)/ 34] 8 | Bananas and pumpkin.

Detached patches ‘and
Elliot's Pass. . 15{ 2/19 |—{|—|—j 9|— | Bananas.
Totals .|29)/— | —| 4)27] 1] 0/25
June 16th 1862, (Signed) F. L, BARNARD, Captain in charge of Ascension.

In the observations published in 1864, it is stated, “ Much might

be done to improve and add to the area of the cultivated land,

. I consider that the cultivation of the mountain has reached

a new stage ; the buddlea, vitex, and quick-growing underwood have

done their work as pioneers, and made good soil where coffee and the

various ornamental and useful trees and shrubs that are ready for
transplanting should be put.

“ Already a large piece of ground adjoining the cattle yards is
being enclosed with a strong fence formed of branches of Ascension
treesand underwood. It is planted with Para grass, and will be most
valuable for sick cattle, as well as the sheep, at the half-yearly
musters, when they invariably suffer greatly from running at their

EFFECTS OF FORESTS ON MOISTURE,

142

noses, after being kept a day or two on dry food. The yearly saving

fodder will be at least £50.”

There

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TREES GROWN ON ASCENSION. 143

There is appended also the following list of botanical names of
trees and shrubs growing on the Peak :—Juniperus Bermudiana,
Podocarpus sp., Brugmansia suaveolens, Brugmansia sanguinea,
Ficus (four species), Casuarina (two species), Acacia, four species,
including the Wattle, Tlex sp., Alpinia nutans, Pinus excelsa, Pinus
pinea, Vitex trifolia, Bignonia (Stoniby sp.), Hibiscus (five varieties),
Clerodendron fragrans, Coffea Arabica, Buddlea (Ascension gum
bush), Eriobotrya Japonica (the loquat), Quercus robur (English
oak), Cedrus Deodara (one plant), Cupressus torulosa, Widdringtonia
juniperoides, Fourcroya gigantea, Hakea sp., Virgilia Capensis,
Eucalyptus (four species), Nerium oleander, splendens, Phytolacca
decandra, Myrica cordifolia, Leucodendron argenteum, Melaleuca
hypericifolia, Rhus levigata, Schottia latifolia, Pandanus odoratis-
simus. Fruits—The banana, peach, lime, orange, fig, loquat, and
guavas, the latter being the only kind that produces fruit. Respect-
ing the natural grasses on the Peak, it is said,—‘“‘ What appears to be
grass is in reality not grass at all, being only sedges, near relations
to the English rush.”

I consider that the preservation of the water under the wattle, to
which reference is made, may be accounted for otherwise than by
supposing that the moisture is attracted by vegetation ; but the fact
of the connection between plantations and moisture, resulting in an
increase of the former being accompanied by an increase of the latter,
remains the same whatever theory or hypothesis may be entertained
in regard to the modus operandi.

In the Report of Kew Garden, for 1864, it is stated, “that from
Ascension there continued to be received encouraging accounts of the
increased fertility and moisture of the island, consequent on the
extension of the plantations.” And in the Report for 1865, it is
stated,—‘“ Of once sterile Ascension Island, which we continue to
supply with plants, Captain Barnard reports that it now possesses
thickets of upwards of forty kinds of trees, besides numerous
shrubs and fruit trees, of which, however, only the guava ripens.
These already afford timber for fencing cattle-yards. When Mr
Hooker visited the island in 1843, owing to want of water, but
one tree existed on it, and there were not enough vegetables
produced to supply the Commandant’s table ; whereas now, through
the introduction of vegetation, the water supply is excellent, and the
garrison and ships visiting the island are supplied with abundance of
vegetables of various kinds.” Later reports I have not seen.

144 EFFECTS OF FORESTS ON MOISTURE.

It is remarked by Marsh, that “it has long been a popularly settled
belief that vegetation and the condensation and fall of atmospheric
moisture are reciprocally necessary to each other, and even the poet
sings of

Afric’s barren sand,
Where nought can grow, because it raineth not,
And where no rain can fall to bless the land,
Because nought grows there.” *

Here we have an illustration of the converse fact : one measure of
humidity promoting vegetation, and vegetation not only arresting the
desiccation but so reversing the process that an increased humidity

is the consequence.

Sucr I1V.—Cases, Illustrative of Effects of Forests on Humidity,
correspondinng to such as have been adduced.

Besides the cases which have been brought forward as indicative of
the effects of forests upon the humidity of a country, there are others
which point to the same conclusion, which may be adduced, not as
corroborative testimony, but as independent facts, which are in
accordance with what has been alleged. Continuing observations
made on the Islands and Continent of Africa, I cite first the case of
Madeira.

Madeira does not, like St. Helena and Ascension, supply evidence
of a restored or newly produced humidity following the planting of
trees; but it supplies testimony to the effects of trees on the humidity
of the atmosphere and soil, which is of importance.

Washington Irving, in his “ History of Columbus,” refers to an
ancient document which is believed to have been drawn up by one of
the first discoverers of Madeira, about the year 1378. According to
this document,—“ The country was delightful. The forests were
stately and magnificent. There were trees laden with excellent
fruits. The waters were cool and limpid. On penetrating a. little
distance they found a beautiful sheltered meadow, the green bosom
of which was bordered by laurels and refreshed by a mountain stream,
whieh ran sparkling over pebbles.”

In accordance with this statement is the following glowing descrip-

Be

Det golde Strég i Afrika,
Der Intet voxe kan, da ei det regner,
Og, omvendt, ingen Regn kan falde, da
Der Intet voxer,”
PaLuDAN-MURLLER, Adam Homi, ii, 408.

FORMER CONDITION OF MADEIRA. 145

tion of wood and waters, given in an unpublished ancient manuscript,
cited by Dr Graham in a work entitled “Climate and Resources of
Madeira,” published in 1870 :—* The island of Madeira at the period
of its discovery presented a most lovely picture of nature : a vegeta-
tion truly astonishing covered it with trees, reaching to a prodigious
height,—the majestic cedar, laurel, til, besides others, forming one
continuous and impenetrable forest. Evergreens and creeping plants
wove their festoons from branch to branch, giving new shade to a
land all clothed with vegetation, and new force to znumerable springs
of pure and salubrious water.” But tradition tells of a great forest
fire having swept over a great extent of the island; and after that,
it was alleged, all was changed.

Mr Milne Home, Chairman of the Council of the Scottish
Meteorological Society, in a paper submitted to this Society, entitled
“ Suggestions for Increasing the Supply of Spring Water at Malta,
and Improving the Climate of the Island,” says,—‘Some valuable
facts are supplied from the island of Madeira. It has been shown that
the annual fall of rain there is, on an average, thirty or thirty-two
inches, being about thirteen inches more than at Malta. Can one
reason be that, whilst Malta is treeless, Madeira is still partially
wooded? Dr Graham says,—‘ The north side of Madeira is still well
clothed ; and, although there are perhaps few trees which can aspire
to the dimensions handed down to us in the relics of former days, the
dark and ancient foliage still covers both hill and valley.’

“Dr Graham refers to the dimensions of the trees of a bygone
age in Madeira. There can be no doubt that when first colonized
the island had been completely covered with wood. Its name, as
given by the Portuguese, was originally Materia, in allusion to the
inexhaustible materials it supplied for ship-building and the con-
struction of houses.”

Dr Graham quotes from an unpublished ancient manuscript the
glowing description of its woods and waters, which has been given
above ; and referring to those statements of an old date, he goes on
to say,—It seems evident, from these descriptions, that Madeira
when first colonized was much better supplied with both wood and
water than at present ; and the conclusion seems not unreasonable,
that the better supply of water was in consequence of the larger
extent of wood.” Citing these passages, Mr Milne Home goes on to
say,—“ Dr Graham expresses a decided opinion to that effect. He
condemns unsparingly the selfishness and folly of the first colonizers,

who, in order to get land for the culture of the sugar-cane and vine,
0

146 EFFEOTS OF FORESTS ON MOISTURE.

set fire to the woods, and produced a conflagration which lasted seven
days.”

Dr Graham says,— The forests of Madeira have been continually
receding with the increase of fuel requirement, and the replanting of
the land thus laid waste has been long and culpably neglected.
Recently, however, the introduction of the pine tree has to a very
great extent stemmed the progress of reckless destruction. The pine
grows easily and rapidly, occupying lands ill-suited to other kinds of
cultivation.” And in another connection he says,—“ The recession
of nature’s woods has been in late years compensated by the advance
of the introduced species.”

He reports his observations on the arrest of the water of fogs and
clouds by the leaves of the coniferz, and other trees, which act almost
like a sieve, draining it out ; and he remarks, “ when the hills were
completely wooded, at the time of the colonization, it is quite
probable that the humid mists, continually passing over the moun-
tains, were intercepted, and that the rivers which now, soon after
rain, dwindle down to tiny streams were then more constantly full.”
And he further remarks :—“ On the eastern side of the basin of
Funchal, the upper lands have been almost entirely cleared of trees.
The rain water descends impetuously in a torrent, leaving a tiny
stream, which flows steadily so long as the sky is overcast, but
ceases altogether after one day of sunshine. I do not think the rains
are now heavier or more fitful than in former times; but there are
now no woods on the south side to restrain the drops, which unite to
denude the rocks of their soil, and to form the mighty torrents
witnessed every wiuter. I do not doubt that the planting of trees in
the villages at the head of the main ravines would lead rapidly to a
neatly constant supply of water in a region where it would be useful.’

The facts reported and the conclusions drawn from them are all in

accordance with what has been reported in regard to St Helena and
Ascension.

By Blanqui, in his Voyage en Bulgarie, already cited, it is alleged
that “the terrible droughts which desolate the Cape Verd Islands
must be attributed to the destruction of the forests.” And he says
that, “in Egypt, recent plantations have caused rains which hitherto
were almost unknown.”

I have repeatedly met with a reference in different forms to
observations which have been made, or are alleged to have been
made, in Alexandria and Egypt, in accordance with those which have

THE CONDITION OF EGYPT. 147

been brought forward in this and in the preceding section of this
chapter ; but I consider them open to question.

A writer in the “‘ Edinburgh Review” whom I have already cited,
after making some remarks on the desiccation of Palestine, as a con-
sequence of the destruction of the olives, palms, and other trees,
during the Roman war, goes on to say :—‘ Even as to that country,
of which it was said, two thousand four hundred years ago, that the
family of Egypt have no rain, the United States Commission of
Agriculture, for 1871, reports:—‘In Upper Egypt, the rains which
eighty years ago were abundant, have ceased since the Arabs cut
down the trees along the valley of the Nile towards Lybia and Arabia.
A contrary effect has been produced in Lower Egypt, from the
planting of the Pacha. In Alexandria and Cairo, where rain was
formerly a rarity, it has since that time become more frequent.” But
this statement appears to be open to question.

It is stated by Cézanne that Clot Bey has, in his work entitled
Apergu géneral sur U Egypte (vol. i. p. 22), shown that the plantations
in Egypt have not rendered rains more frequent. And he states that
at Cairo, the mean number of days on which it rains in the course of
the year is twelve, and the rain-fall 34 millimétres.

On this subject Mr Marsh remarks :—“ The alleged augmentation
of rain-fall in Lower Egypt, in consequence of large plantations by
Mehemet Ali, is very frequently appealed to as a proof of this in-
flaence of the forests, and this case has become a regular common-
place in all discussions of the question. It is, however, open to the
same objection as the alleged instances of the diminution of precipi-
tation in consequence of the felling of the forest.

‘This supposed increase in the frequency and quantity of rain in
Lower Ezypt is, I think, an error, or at least not an established fact
I have heard it disputed on the spot by intelligent Franks, whose
residence in that country began before the plantations of Mehemet
Ali and Ibrahim Pacha, and I have been assured by them that
meteorological observations, made at Alexandria about the beginning
of this century, show an annual fall of rain as great as is usual at this
day. The mere fact that it did not rain during the French occupation
is not conclusive. Having experievc2d a gentle shower of nearly
twenty-four hours’ duration in Upper Ezypt, I inquired of the local
governor in relation to the frequency of this phenomenon, and was
told by him that not a drop of rain had fallen at that point for more
than two years previous.

** The belief in the increase of rain in Egypt rests almost entirely on

148 EFFECTS OF DESTRUCTION OF FORESTS

the observations of Marshal Marmont, and the evidence collected by
him in 1836. His conclusions have been disputed, if not confuted,
by Jomard and others, and are probably erroneous. See Forssao,
Météorologie, German translation, pp. 634-639.”

The Imperial Academy of Science has expressed a wish that the
Government of Austria would apply to the Viceroy of Egypt for ex-
tracts from the observations which have been made on the rise of the
Nile gauge above Cairo for 3000 years and more, especially for ex-
tracts from the records of the last 200 years. Should these be
supplied, we may hope that some light may be incidentally cast upon
some of the questions at issue.

South Africa has also its tale to tell. Mr Tuck, superintendent of
the Botanic Garden at Grahamstown, in writing to me before I left
the colony, communicated the following notice of what he had observed
in the course of the summer, that of 1864-1865 :—“ This season has
been unusually hot and dry along the coast ; and all arouud Grahams
town we have been unable to grow anything all this summer for
want of rain, The springs are all failing.

“You may perhaps know the place of Mr J. J. Stone, on the top of
the hiJl on the Cowie road, towards the sea, marked out by a
quantity of Gum trees, on the ridge of the high hills to the south-
east of Grahamstown ; well, all through the summer we have had
only light misty rain, just enough to damp the grass, and not enough
to wet the ground, but these trees of Mr Stone’s have there converted
the mist into rain. They have scarcely felt any effects of the dry
weather ; the vegetables and flowers have there grown all the summer
without watering ; there the tanks have always been full: and that
is the only place of which J have heard that it has been so within
five and twenty or thirty miles of Grahamstown.”

T have had occasion to cite the statements made by Boussingault
(ante p. 113) in regard to changes in the Lake of Tavarigua, in the
vicinity of New Valencia, in South America, otherwise they also might
have found a place here, as they show that a destruction of forests
had been followed by a lowering of the waters of the lake, and the
reproduction of the forests, consequent on the abandonment of culti-
vation, had been followed by a replenishing of the lake.

By Dr Hough, who has given much attention to the subject in
America, it is stated, that ‘“‘some twenty-five years ago the Danish
sland of Santa Cruz was a garden of freshness, beauty, and fertility.

IN VARIOUS COUNTRIES. 149

Woods covered the hills, trees were everywhere abundant, and the
rains profuse apd frequent. A recent visitor who sought the Island,
with which he had been familiar in the time of its greatest beauty,
for the sake of botanical study, a year or two since, found a third
part of it reduced to a desert. The short copious showers had
ceased, and the process of desiccation was gradually extending over
the island. An attempt to restore the former fertility, by means of
planting, was made too late. One planter had set a thousand trees,
but every one of them failed.”

“ The island of Curacoa,” again says he, “ was, within the memory
of living persons, a garden of fertility. But now whole plantations,
with their once beautiful villas and terraced gardens, are nothing but
an arid waste ; and yet, sixty miles away, along the’ Spanish Main,
the rankest vegetation covers the hills, and the burdened clouds
shower down abundant blessings.”

A writer in the Edinburgh Review, whom I have already had
occasion to quote, citing as his authority, I presume, Dr Robert
Brown, says, “‘By the destruction in France of a great extent of
forest,’ writes Dr Brown, ‘in order to replace them by cultivated
fields, the temperature has become very irregular ; heavy rains,
storms, and dryuess, have each done their work upon the soil, and
made crops every year more and more uncertain.’ In the Vosges,
the destruction of forests has gone so far that agriculture has suffered,
the soil has become arid, and inundations are frequent. In the
Department of the Gard, in 1837, no rain fell for nine months.

“ Nismes, named from the forests which once surrounded it, is now
amid an arid waste. At Beziers, the Agricultural Society réported in
1797 that the forest which once sheltered the plaee having been
destroyed, the loss of the olive crop was the consequence. The
authorities of the Izere reported, in 1793, that the destruction of the
forests had altered the temperature, augmented dryness, and seriously
affegted the crops. From Provence, from the valley of the Moselle,
from that of the Haute Garonne, from the Hérault, and from the
Eastern Pysenees, come complaints of the same nature, The regular
rain-fall has been diminished, the temperature has changed and
become uncertain, and partial and irregular storms have proved
curses rather than blessings wherever the forests have been ruthlessly
swept awWay.”

These statements also are all of them in accordance with what
has been reported with greater detail in regard to St. Helena and
Ascension.

CHAPTER V.
Locat Errsects oF Forests oN THE RAINFALL.

In preceding chapters the principal subject has been the effect of
forests on humidity, and any mention made of rain has been only in-
cidental. In this chapter that prominence is given to this; and it is
the local effects in contradistinction to the effects of furests, or of the
destruction of these over a wide expanse of country, which is brought
under consideration.

In these preceding chapters oftener than once mention has been
made of the rainfall as supplying indications of humidity, or of com-
parative aridity ; and looking at these we have found that though the
desiccation of some countries has followed the destruction of forests,
in others no appreciable effect has been produced on the quantity of
rainfall over a wide expanse of country. But we have found marked
effects on the humidity of both soil and climate produced over a more
limited range, both by the destruction of forests and by the planting
of trees where they were not before, or where they had been destroyed.
And by further limiting and localising our observations we may be
able, with advantage, to follow up the observations which have been
made, and ascertain more satisfactorily the meteorological effects of
forests in relation to moisture. As a preliminary to the consideration
of the effect of forests on the rainfall, it may be well to consider how
rain and rivers are produced.

It may be hundreds are prepared, if asked, Whence comes the rain ?
and, Whence come the rivers? to tell that the rain comes from the
clouds, and the rivers, from springs among the hills. But we require
to go a little further in our consideration of the matter before we can
determine the effects of forests and of the destruction of forests on
the rainfall and on rivers. Whence come the clouds? Oh, from the sea.
And how do they spring from the sea —And how are they formed 1—
And how can the formation of them be affected by forests, or by land
denuded of forests, as in some cases buth the rainfall and the rivers
appear to be {—And why is it so in these cases and not in others ?

These and a hundred other questions suggest themselves on our

ON THE PRODUCTION OF RAIN. 151

entering on this new phase of enquiry. And in view of these, it
seems expedient to begin at the beginning; and by anticipating,
prevent the questionings which might have no end if a different
course were followed.

Sect. 1.—On the Production of Rain.

In consequence of the comparative heat in the tropics the air there
expands, and colder air of greater density flowing in over the surface
of the earth or sea, the expanded air is borne upwards from below,
till, cooled at a higher elevation, it begins to descend, to the north
and to the south of the equatorial region; but, excepting in excep-
tional circumstances, it reaches not the earth again until it has been
cooled down to the temperature of the air at that lower level. This
process going on continuously, there are produced two sets of currents
in the atmosphere: one from the Northern Artic regions, sweeping
along, over earth and sea, towards the equator, occasioning the north-
east Trade Winds, and the north winds and east winds so dreaded by
the sufferers from rheumatism in the northern hemisphere; and
another from the Sonthern Antartic regions, sweeping along in like
manner, on or near the surface of the globe, towards the equator,
occasioning the south-east Trade’s and the famous South-easter of the
Cape of Good Hope. But though these two sets of currents inter-
mingle, it may be, at the equator, they can scarcely be said to combine;
for, ascending there in a conjoined mass, each portion curves over
almost in its entirety towards the region whence it comes, but with a
tendency from west to east, instead of that from east to west with
which it came. This is accounted for thus: the earth rotates from
west to east, carrying with it not only the water of the sea but the
air of the atmosphere ; being a sphere, or spheroid, each spot in the
polar regions is carried through a more limited space in the twenty-
four hours than is any spot nearer to the equator ; its motion per
hour, minute, or second, is less rapid than is that of any spot over
which the air may pass in its course to the equator ; and at this spot,
the wind, moving onward, without diminishing its velocity, may be
dragged forward a little; but at last it will be left behind; and thus
an apparent current from some easterly point to some westerly point
is given to the current flowing from the pole towards the equator.
And the returning currents from the equator, carrying with them the
velocity from east to west, there acquired when they impinge upon
the surface of the globe, having a greater velocity in that direction

152 EFFECTS OF FORESTS ON RAINFALL.

than that of the spot on which they strike, they seem to come from
some westerly point nearer to the equator.

Water in contact with air appears to be absorbed by it in a state
of vapour up to a point of saturation, varying with temperature,
beyond which it cannot either absorb or retain more. As the air
advances from the polar regions towards the equator, its temperature
and consequent capacity of absorption are raised, and ere it reaches
the equatorial region it may have absorbed a quantity it could retain
where it is, but could not retain either at a greater height or in the
polar region whence it had come. Accordingly we find that in the
equatorial regions, when it is raised to a great elevation, and is thus
cooled, the air can no longer retain it all dissolved, and the surplas is
deposited in clouds, The moisture thus deposited, attracted by
gravitation, passing through lower strata of a higher temperature,
not saturated, may be again absorbed ; and thus may be explained
the phenomenon of a continuously clouded sky unaccompanied by
rain, which is seen so frequently at sea, within the tropics, as almost
to be the characteristic of the sky in these regions.

The current returning to the polar regions from the equator, in
passing over mountains on the summits of which a polar temperature
prevails, being thus cooled down, and unable to retain more than a
little of the moisture with which they are charged, the surplus is
there deposited in the form of rain, or snow, or sleet, or hail.

To this also is attributable the humidity of the climate of England.
It may be traced to the prevalence of southerly and westerly winds,
which come to us laden, not only with moisture which they may have
absorbed in passing over the Atlantic in their passage thither, but
with moisture previously absorbed in their passage from the polar
towards the equatorial regions.

In England, the southerly and westerly wirds are to northerly and
easterly winds in the proportion of 196°4 to 135.

There are waves of wind which come sweeping over the Atlantic
from the north-west, but these are comparatively rare. Those which
come blowing from the south and the west, and more especially those
which creme blowing from the south-west, have come at a higher
level, with an under current, between them and the ocean, flowing in
an opposite direction ; and these are the most prevalent winds in
England. The following are given by Steinmitz, in his little popular
work, entitled ‘‘Sunshines and Showers,” as the mean of several
years as the number of days on which the following winds were
observed :—

PRECIPITATION OF MOISTURE. 153

North,......... days, 40°7. South,......... days, 34:2.
North-east,... ,, 47°6. South-west,... 4, 104°0:
East,........... oy 286, West,.......... 5, 38°0.
South-east,... ,, 19-9. North-west,... ,, 24.1.

The east wind, cooling down the atmosphere, may occasion rain ;
but all our deluges come from the south aud west.

The air, when it reaches the polar regions, being greatly cooled
down, deposits its moisture in the form of snow; and_of this are
formed the fields of ice which are churacteristic of the Arctic and
Antartic regions alike.

By Dr Scoresby, it is reported that in the Arctic regions it snows
nine days out of ten in the months of April, May and June. With
southerly winds near the borders of the ice, where moist air, blowing
from the sea, meets with the cold breeze from the ice, the heaviest
falls of snow occur. In this case a depth of two or three inches falls
in an hour.

In crossing and recrossing the Atlantic, in certain latitudes,
frequently are fogs encountered : the cause and occasion is the same,
Fragments of Arctic glaciers broken off and floated away by oceanic
currents, as icebergs, cool down the ocean and the atmosphere nearer
to the tropics, and that to such an extent as to occasion a deposition
of moisture wherever they go, and it may be for a hundred miles
around them.

As some indication of the immensity of the quantity of moisture
brought back to high latitudes by the return currents in the upper
regions of the atmosphere, I would remind my reader of the immense
body of water composing Lake Superior, Lake Michgan, Lake Erie,
and Lake Ontario, in America, pouring over the Falls of Niagara
unceasingly, and flowing through the Thousand Isles into the St.
Lawrence ; and of the waters poured into the ocean by all the rivers
of the world, great and small alike: these are but the drainage of
the water precipitated by the way on the valleys through which they
flow ; I would remind him of glaciers of the Alps, the product of the
comparatively trifling portion arrested by the higher part of that
mountain range as it was being borne onwards to the north ; and I
would remind him of the immensity of the deposits near to the
pole, not frozen sea, but frozen rain.

In a volume lately published, entitled “Under the Northern

Lights,” by Mr MacGraham,—a correspondent of the “ New York
: ?

154 EFFEOTS OF FORESTS ON RAINFALL.

Herald,” sent by the spirited proprietor of that paper on a voyage
of discovery, made by the Pandora, last year to the Arctic regions,
the expense being shared with him by the late Lady Franklin, and by
Captain Allen Young, who went in command of the vessel,—there is
given the following account of Greenland. Speaking of the interior
of the continent of Greenland as an icy solitude,— a secret unknown
to man, and likely ever to remain such,—he goes on to say :—“ Its
surface is 4,000 feet above the sea, and when you ascend to it you
will probably perceive somewhere on the plain which rises before you
in a slight ascent till it touches the sky two or three little sharp
conical hills, a few feet high, that pierce through the ice, and you
will be astonished to learn that these insignificant mole-hills are in
reality the tops of lofty mountains, that have been submerged
beneath the mighty inundation of ice. Somebody has said of
Switzerland that if it were ironed out it would be a very large
country. If Switzerland were about ten thousand times larger than
it is, and ice were then poured into it until it should be full up
nearly to a level with the highest mountain peaks, it would present
just the appearance of the interior of Greenland. And yet the
whole of this vast continent was at one period of the earth’s history
green and fertile. There have been fuund here forests of carbonised
trees and plants, and the fossil remains of many animals that could
only have existed in a warm climate. Fossil corals and sponges are
often picked up now in Lancaster Sound and on the shore of Beechy
Island. It is certain that the climate was soft and mild, and that
the country was covered with trees and verdure, and it is equally
certain that this terrible inundation of ice came and buried every
vestige of it, as Herculanzeum and Pompeii were buried beneath the
ashes of Vesuvius. But, instead of the two poor little villages, and
perhaps a few square miles of the adjacent country, that Vesuvius
covered with its fine ashes as with a soft warm blanket, here is a
continent larger than the whole of Europe, buried beneath a massive
sea of ice. It is as though the waters of the flood had suddenly
frozen to the very bottom, and had never thawed.”

Such are “the treasures of the snow,” and “the treasures of the
hail,” to be found in the Arctic and Antartic regions of the earth,
borne thither from the equator and the tropics, ever in a state of
flux, but ever renewed by fresh accessions. Of the evaporation by
which this is maintained, the quantity of moisture taken up by the
air in its passage over earth and sea to the equator from the poles,

T cannot hope to convey either an adequate or a definite idea. It is
%

EVAPORATION FROM THE SEA. 155

proportionate to the area, the temperature, the time, the tension, and
much besides.

Even from the land the evaporation is great. Maury, in his
treatise on the “ Physical Geography of the Sea,” (p. 274), estimates
the anoual amount of precipitation in the valley of the Mississippi at
620 cubic miles of water, and the discharge of that river into the sea
at 107 cubic miles; and he concludes that “this would leave 513
cubic miles of water to be evaporated from the river basin annually.”
This is but one basin—a furrow on the dry land; and then there is
the sea !

The evaporation from the Mediterranean, the Black Sea, and the
Sea of Azov, is reckoned at 50 inches on the whole extent of their
surface ; this is about 1,500,000 square miles, and a simple calcula-
tion shows that from these seas alone must be evaporated upwards
of 500 (508) cubic miles of fresh water.

A corresponding estimate and calculation shows that the annual
evaporation from the Red Sea must amount to 165 cubic miles of
water.

Such are the quantities with which we have to deal in speaking of
evaporation from inland seas alone.

Of the whole surface of the earth, three-fourths are covered by
sea; that surface measures in round numbers 196 millions of square
miles, of which nearly 150 millions are covered by water. What
startles me is the consideration of the quantity of water which this im-
plies, and the question arises, What can have been its source? But it is
the evaporation from it with which alone we have at present to do.
We should probably err were we to reckon the evaporation, over the
whole area of the ocean, at the ratio of the evaporation which takes
place from the surface of the Red Sea and the Mediterranean. But
it is going on everywhere—in an increasing ratio, probably, towards:
the equator, in a decreasing, towards the poles ; and apparently it is
not confined there to what is called the open sea. I have already
had occasion to refer to the statement by M. Hayes, in a work entitled
La mer liber du Pole, published in 1868, that thin wet linen exposed
to the air dries at the lowest temperature, and that a sheet of ice
suspended by a cord evaporates by degrees. He adds, “ that evapora-
tion is more restricted near the coast than in the interior districts of
a country, and more restricted under an equatorial wind from the
south-west, than under a polar wind from the north-east, the former
being saturated with moisture, while the latter has been deprived of
its humidity.”

156 EFFECTS OF FORESTS ON RAINFALL.

Of the moisture thus absorbed by the air from the wide ocean
and the inland sea, and borne onwards to the tropics, no trace is
seen in the atmosphere till the air is cooled below the temperature
at which it can keep it so sustained. This happens when it is first
raised aloft, and when, on its return towards the poles, it impinges
on some mountain range or solitary peak.

But while the course detailed may be considered the normal
course of the air in its current to and from the equator, it is liable
to many disturbances.

It is not usual for two currents of water flowing in different, and
to some extent contrary directions, to glide past each other, each
pursuing its own way ; there is friction, and as a result of this friction
there are eddies and whirlpools. It is so when they flow side by side ;
it is so when they flow the one over the other; and it is so with
these aerial currents : the upper current coming completely through
the lower, and producing those westerly winds, of which, otherwise,
we should have none in medium latitudes; and it is reasonable to
conclude by inference that there may be eddies of the lower current
passing into the upper. Every one of these disturbances must
affect the temperature, and consequent capacity of a great mass of
air to retain the moisture with which it is charged, and that in
different ways: for instance, the eddy of the warm upper current
may ‘be so cooled down that it must deposit a great quantity of the
moisture which it held, or the eddy of the lower current cooling
down: portion of the upper current penetrated by it may render it
incapable of retaining all the moisture with which it was charged ;
and in each of these cases rain or snow, or hail, according to circum-
stances, may be the consequence. The eddy moreover may take a
wide sweep, developing into a whirlwind or cyclone, with a radius of
a hundred miles or more, and advancing onwards thousands of miles,
carrying disturbance of temperature, and of hydrometric conditions
wherever it goes. Similar whirlwinds I have seen produced upon a
smaller scale, with all the indications of capability of being in like
manner developed on a scale as gigantic, simply by the sun beating
on arid ground, or on ground from which water has evaporated.

In the centre of such a whirlwind the air of the district over which
it passes may be raised to such a height as to be cooled so low that
much of its moisture is precipitated, and falls in two parallel lines
of rain, or hail, marking the lateral limits of its course; and over the
whole area of the ground traversed by it, embracing hundreds of
thousands of square miles, and over all the area of the ground

FORMATION OF CLOUDS. 157

traversed by eddies thrown off by it, rain may be a consequence of
disturbances of the hygrometric equilibrium beyond what was com-
patible with the retention of the moisture by the air. A current of
cold air so brought into a body of warm air may cool this toa tempera-
ture at which it is saturated with a much less quantity than it con-
tains, and the excess will be precipitated as rain; or a current of
warm uir brought into a body of cold air may be so cooled down that
ats surplus moisture is deposited in the form of rain.

Thus are clouds produced ; and a change of wind occasioning a
slight rise of temperature may cause the cloud to melt away into
transparent air, by the re-absorption of the vapour of which the cloud
was formed. The phenomena I have seen at the Cape of Good Hope
a hundred times. They are there of constant occurrence.

A correspondent from Sea Point writes :—“ On Thursday evening,
during the hard south-east gale, some very remarkable and beautiful
cloud effects were witnessed. Dark masses of cloud came driving
across the Lion’s Back at a furious rate, obscuring the brilliant moon-
light. But in a few seconds after passing the zenith, their speed
became checked, and, at the same time, they began rapidly to
dissolve. Some of the cloud masses hung for a few seconds
apparently motionless between the opposing currents of wind.
Others again yielded to the counter current, and rushed back
furiously from the north, meeting the driving masses from the
south, and, almost in the moment of apparent meeting, dissolving
utterly away. It was like the unavailable charge of a gallant
body of light cavalry against a masked battery of artillery,—swept
away before the cruel storm. The sudden alternations of clear blue
sky, with black thunderous-looking masses of light fleecy clouds, and
the changing iridescent hues of the vapours as they drifted across
the moon, were very striking, and produced a scenic effect which
those who witnessed it will not soon forget.”

By the clouds may be traced the aerial currents. Writing on this
subject, in connection with the distribution of rain, it is remarked by
Cézanne that, “ From the elevated summit of a mountain above
which sbines the sun in a cloudless sky, one may see under his feet
a tide of clouds rising up the slopes on one side of the range. It
impels its mobile billows into all the anfractuosities of the gorges,
lashes and surmounts the buttresses which stop it, in every respect
as does the ocean covered with foam the black head of the reef of
rock, By all the rocks, by all the depressions of the chasm, the
cloudy wave presses on, and pours itself over on the slope on the

158 EFFECTS OF FORESTS ON RAINFALS.

opposite side: the highest summits alone emerge above the inunda-
tion; but down the stream the clouds seem to be falling into an un-
fathomable void ; they are seen to be disappearing, and the slope on
this side, lit up with sunshine, offers a smiling contrast to the other,
which, immersed in the storm, is shrouded in a thick veil. The rain
in such circumstances is invisible to the observer, but he makes its
acquaintance a little later, when in his descent he passes through the
clouds, or, if the storm have then passed away, when he finds all the
streamlets on his road overflowing their banks.”

When one is enabled thus to look down upon the clouds he may
see the atmospheric current in obedience to the laws of hydraulics,
It has its rapids, and its eddies, it strikes with fury against jutting
obstacles, and when it is contained between regular sloping hills it
abandons the convex mound, and presses itself out against the
concave bank, Thus is the aerial current made manifest.

Thus far we have had to do with the production of clouds; the
transition to the consideration of the production of rain is easy.
This is thus detailed by Sir John Herschel*: “ When the sun
shines on a cloud which absorbs its Leat, the cloud itself is neces-
sarily evaporated, and the vapour by its levity tends to produce an
upward current, and thus to counteract the effects of gravity on
the globules of which it consists. A globule of water z,5jths of
an inch in diameter, in air of 5-6ths the density on the surface, or
at the height of about 5000 feet, would have its gravity counter-
acted by resistance, with a velocity of descent of one foot per second
(supposing no friction and no drag); and even if the terminal
velocity were reduced to half that quantity by these causes, would
still require some upward action to enable it to maintain its level,—
a circumstance which sufficiently accounts for the lower level gene-
rally observed of cloud during the night. It is more probable,
however, that when not actually raining, a cloud is always in process
of generation from below and dissolution from above, and that the
moment this process ceases, rain in the form of ‘ mizzle’ commences.
In a word, a cloud would seem to be merely the visible form of an
aerial space in which certain processes are at the moment in
equilibrio, and all the particles in a state of upward movement.

In whatever part of a cloud the original ascensional movement of
the vapour ceases, the elementary globules of which it consists,

* “ Meteorology :” a volume reprinted from the Encyclopedia Britannica.

EFFECTS OF FORESTS ON LOCAL RAINFALL. 159

being abandoned to the action of gravity, begin to fall. By the
theory of the resistance of fluids, the velocity of descent in air of a
given density is as the square root of the diameter of the globule.
The larger globules therefore fall fastest, and if (as must happen)
they overtake the slower ones, they incorporate, and the diameter
being thereby increased, the descent grows more rapid and the
encounters more frequent, till at length the globule emerges from the
lower surface of the cloud, at the vapour plane, as a drop of rain ;
the size of the drop depending on the thickness of the cloud-stratum
and its density.”

From what has been advanced it appears that rain is simply the
precipitation from the air of moisture which happened to be held by
it in excess of the quantity which it could, at its reduced tempera-
ture, hold in solution. It differs from the cloud or fog only in being
formed of drops produced by the mutual attraction of smaller drops
which are rapidly drawn by gravitation to the ground, instead of
floating long suspended, as the constituent lesser drops had been, in
the air. And this it may be well to bear in mind in proceeding to
the consideration of the local effects of forests on the rainfall.

Section I].—The Effects of Forests on the Quantity of the Local
Rainfall,

T have had occasion in a previous chapter to refer to the existence
of an opinion held by many, and widely-diffused, that forests and
mountains attract rain. I have otherwise explained the phenomena
which have been attributed to some attraction exercised by them
upon clouds, alleging and maintaining that the clouds seen in such
situations must have been produced there; and I am disposed to
allege and maintain something similar in regard to rain.

The effects of trees on the humidity of the earth and atmosphere
has received the attention of several men of science and observation
in Britain, some of whom—Sir John Herschel and others—have
spoken out very decidedly on the subject. But in Britain it has
been less of a practical question, demanding attention as a means of
avoiding threatening calamities, than it has been in other lands; and
while many of those who have given their attention more especially to
this subject speak decidedly, they speak with the caution which science
demands. Boussingault says: ‘My opinion is that the felling of
trees over a /arge extent of country has always the effect of lessening

160 EFFECTS OF FORESTS ON RAINFALL.

the mean annual quantity of rain.” The deliverance of Becquerel is
in accordance with this. He says: “Great clearings diminish the
quantity of spring water in a country.” But he says, “It has not
been. ascertained whether this effect should be ascribed to a less
quantity of rain which falls annually, or to a greater evaporation
from the soil of rain water, or to a new distribution of showers of
rain.”

The opinions thus expressed are based on observations of facts.
But along with these facts there are other facts which have already
been referred to, and which require to be taken into consideration,
if we would learn the whole truth on the whole of the subject. It
has been stated that in the annual report of the Director of the
Meteorological Observatury in the Central Park of New York, for
1871, Mr Draper addresses himself to the question—Does the clear-
ing of land increase or diminsh the fall of rain? and in a preceding
chapter I have given his answer.

He gives summaries of observations made in each year, and in
each quarter of the years 1869, ’70, 71; he states that the indica-
tions given by the instruments of the observations under his direc-
tion may be thoroughly relied on, and he concludes, “so far as these
years are concerned there does not appear any evidence of a decrease,
on the contrary, in the last, there is a very considerable excess on
either of the others.”

Citing, then, observations made in England since 1677, and in
unbroken continuance since 1725, in Scotland since 1731, in Ireland
since 1791, he shows that where a lengthened period and an
extensive area are embraced by the observation, there is a perfect
compensation, the decrease at one place being compensated by the
increase at another, and that even in the same locality this principle
of compensation might be seen.

When these facts are taken into consideration along with the
other facts which have been cited, the two classes of facts may at
first appear to the inconsiderate to be inconsistent and incompatible
with each other; but if all be facts they must be compatible and
consistent, and a little consideration may suffice to show that they
are 80.

Harland Coultas, in a work entitled “(What may be learned from a
Tree,” published in New York in 1860, in a passage cited by Marsh
says, “ The ocean, winds, and woods, may be regarded as the several
parts of a great distillatory apparatus, The sea is the boiler, in

VARYING QUANTITIES OF RAIN. 161

which the vapour is raised by the solar heat. The winds are the
guiding tubes, which carry the vapour to the forests, where lower
temperature prevails. This naturally condenses the vapour; and
showers of rain are thus distilled from the cloud masses, which float
in the atmosphere, by the wouds beneath them.” All which is true.

By Marsh it is said:—‘‘ We cannot positively affirm that the
total annual quantity of rain is even locally diminished or increased
by the destruction of the wools, thouzh both theoretical considera-
tions, ani the balance of testimony, strongly favour the opinion that
more rain falls in wooded than iu open countries. An important
conclusion, at least, upon the meteorological influence of forests, is
certain and undisputed: the proposition namely, that within their
own limits, and near their own borders, they maintain a more
uniform degree of humidity in the atmosphere than is observed in
cleared grounds: scarcely can it be questioned that they tend to
promote the frequency of showers, anl, if they do not augment the
amount of precipitation they probably equalize its distribution
through the different seasons.”

“The strongest direct evidence which I am able to refer to in
support of the proposition that the woods produce even a local
augmentation of precipitation, is furnished by the observations of
Mathieu, sub-director of the Ferest School at Nancy. His pluvio-
metrical measurements, continued for three years, 1366-18638, show
that during that period the annual mean of rainfall in the centre of
the wooded district of Cing-Franché2s, at Belle Fontaine on the
borders of the forest, and at Amance, in an open cultivated
territory in the same vicinity, was respectively as the numbers 1000,
957,and 853.” In an appendix, Mr Marsh inserted a statement that
*« Fautrat and Sartiaut placed at an elevation of six métres above a
grove of oaks and elms, of twenty years growth and eight or nine
métres height, in the forest domin of Halatte, pluviom>:res and
other meteorological instruments, and like instruments at the same
elevation in the open ground three hundred métres from the forest.
In the months February to July inclusive, the rainfall above the trees
was found to be 192. 50™™ and during the same period 177™™ in the
open ground, Comptes-Rendus, t. LXXTX, 409.

The observations made by Mr Mathieu are thus summed up by
himself, in his report to the Director-General of the Forest Adminis-
tration :—

“In 1868 there fell on cleared spaces within the forest region more

rain than beyond the borders of this; on agricultural land the fall was
a

\

162

least of all.

EFFECTS OF FORESTS ON RAINFALL.

This result agrees entirely with those obtained in pre-

vious years, and tends more and more to present itself as a law.
The following table has been prepared to make this apparent :--

Depth of Sheet of Water Received by the Ground.
Cing-Franches, Belle-Fontaine, Ammence,
Centre of Border of Agricuitural
Forest Region. Forest Region. Region.
Mil imetres. Millimetres. Millimetres,
9 Last Months of 1866, 691 No observation.| 591
11 Do. 1867, 762 716 695
12 Months of 186, 749 738 631

“Tf we represent by 1000 the quantity of water which fell each
year at the Cing-Franchées, we obtain for the three years during
which the observations were made, the following as the proportions
thus indicated :—

1866, 1000 — 855
1867, 1000 930 913
1868, 1000 985 791

The mean of these gives the proportion noted by M. Marsh.

The difference is probably not greater, but less, than is the popular
belief ; and it is possible it may be represented thus as being greater
than it actually is,

M. Cézanne remarks on this report :—‘ After what we have seen of
the so-called caprices of rain, and the variations which they present
in one quarter, and in another of the same city, we mast
acknowledge that the experiments of M. Mathieu, while furnishing
on the whole an argument in favour of the supposition of an action
of forests on the phenomenon of the rain, are not absolutely
demonstrative. How can we satisfy ourselves that the forests have
not acted simply asan obstacle to the pluvial wind? If, for example,
the agricultural region spread itself out on a level plateau, while the
forest region rose on a slope up which crept the pluvial wind, the
pluviométres placed in these two regions are in no way comparable
together.

“Tn order that the experiments might have been conclusive it would
have been necessary that, viewed in regard to a great number of
points, they should have been always accordant. But of this accord-
ance in condition we have no evidence,

“M. Belgrand, comparing the region of the rainfall in the basin of
the Grenetién, which is wooded, with that of the Bouchat, which is
not wooded, has ascertained and established that the former

EFFECTS OF INCIDENCE. 163

received less water than the latter, and further, that in this case the
arrangement of the sides of the mouutains exercised a prepon-
derating influence, and one which masked that of the forests.”

M. Cézanne has given attention to the effect of the configuration
of the land upon the quantity of the rainfall. He has shown that this
is determined, not only by altitude, but by the incidence with which a
pluvial wind may strike upon any precipice or slope which opposes it,
the rainfall being greater in proportion as the atmospheric current
arrested by an obstacle is compelled to rise more rapidly. Hence
the objection stated by him.

Some, if not all, of the so-called caprices, to which M. Cézanne refers
(while I consider the designation, which originated not with him, not
altogether appropriate), I shall afterwards have occasion to cite, and
also the experiments made by M. Belgrand. Here it is enough to
have established that the popular opinion in regard to the effect of
forests on the rainfall has received support from scientific observa-
tions, but that it may require considerable modification to bring it
into perfect accordance with the matter of fact.

It is with this as it is with many other popular observations on
the weather, which may be said to embody correct observations, but
which have this solid substratum of truth overlaid with much which
is not entitled to be considered such—the confiding trust with which
they are received and propounded may be attributable to the
confident and explicit expression in which they are couched. The
uneducated are often impatient of dubiety, or want of explicitness of
thought ; and they are ready to impose this upon a vague or ambiguous
statement with which they are not satisfied; and the half-
educated, again, are prone to generalise rashly, and go far beyond
what strict induction would warrant. Education by philosophy may
regulate this tendency and make it productive of good; and the
study of science may train the educated man to suspend his
judgment in regard to the absolute, while resting with full confidence
on ascertained facts. The generally received opinions in regard to
the effect of trees on humidity, to the extent to which they have
been confirmed by observations, are accepted aud issued recoined,
with a new impress, by such men of science ; but the impress on the
coin, limits, while it defines its value, and to pass them as equivalent
to more than their determined value; were to mislead, though there
might be no intention to deceive. The statement made by Mr
Marab, and the testimony of M. Mathieu, seem then to confirm and
limit, the popular opinion in regard to the effect of forests upon the

164 EFFECTS OF FORESTS ON RAINFALL.

rainfall, and what is thus certified is in accordance with all that has
been advanced in preceding chapters.

Rain has been spoken of as the precipitation from the air of
moisture in excess of what could be sustained in solution at the
temperature at the time. The increased moisture passed into the
atmosphere by evaporation through the stomates of the leaves must
render the air surmounting and surrounding a forest more liable to
be affected by any change of wind than air in the open field. This
it will do irrespective of any other means whereby the quantity of
moisture in the air there may be increased; and thus may the increase
of rainfall in question be accounted for.

There may also be an increase of rainfall occasioned by the repeated
evaporation and precipitation of the same moisture: it is not the
source of the moisture but the measure of the precipitation occurring
in the locality which is alone in question here,

Besides this, it is alleged, and I believe correctly, that the heated
air passing over a forest becomes cooled, and may thus be led to
deposit the moisture with which it is charged.

While it is thus that trees generally act in maintaining the
humidity of the district in which they grow, it isnot impossible that
they may act also in a way much more like what may be called
attracting rain, by their acting as lightning conductors.

If a small pan with a perforated bottom be filled with water, and
suspended from the prime conductor of an electrical machine, on the
cylinder being put in motion, the water, instead of slowly dropping
as it did before, pours in torrents through the perforations in the
bottom of the pan, an electric attraction as well as an attraction of
gravitation drawing it downwards. And this experiment has been
employed to illustrate the thunder shower. Tapering points are
found to have the effect of drawing off a surcharge of electricity from
a body towards which they are directed; and thus, it may be, do
trees occasionally avt as lightning conductors, attracting the electric
fluid, and thus bringing the water charged with it.

Observations have been reported to me which are in accordance
with this supposition.

The Rev. J. Thomas, of Capetown, writes to me that when occupy-
ing a station of the Wesleyan Missionary Society on the West Coast
of Africa, on one occasion when on a journey from the interior in
1848, he and his fellow-travellers came one evening to a forest where

EFFECT OF FORESTS ON RIVERS. 165

they spent the night under the shelter of some large and lofty trees.
About two a.m. it began to rain, and it rained about three hours,
when it poured in torrents, and continued to do so till they left the
place. On mentioning the circumstance they were informed that
just in that place it frequently rained in the manner they had de-
scribed.

I accept the statement because I have no reason to question the
correctness of the observation. I suspend my judgment, and lie open
to light, as our fathers were wont to say, in regard to the occasion of
the down-pour. My prejudices are in favour of the supposition that
it was a passing thunder-shower, unaffected by the trees one way or
another toa perceptible extent ; but it isin accordance with views such
I have stated, and which I know to be held by others; and I cite it
as a case which, having been communicated to me, I ought not to
ignore because it is at variance with more general views which I
entertain.

Secr. [l].—Efects of Forests and of the Destruction of these on
Rivers, and Streams, and Springs.

It is a somewhat prevalent opinion that as rain proceeds from the
clouds, rivers have their primary source in springs; and along with
this opinion it is held by many that the primary function of rivers is
to carry raoisture to lands which otherwise would be barren, and
there to diffuse fertility. But, in point of fact, no water springs from
the ground which has not previously been deposited from the atmos-
phere ; and the primary fuuction of streams, brooklets, and rivers is
simply to carry off surplus moisture in excess of what the soil can
retain.

As rain is produced by the gravitation to the earth of surplus
moisture in the atmosphere in excess of what the air can contain
suspended in a state of invisible vapour at the temperature to which
it has been reduced, rivers are produced by the gravitation to a lower
level of the surplus water so precipitated in excess of what is absorbed
by the earth or evaporated again into the atmosphere.

The popular phraseology in regard to many things is far from
being in exact accordance with scientific conceptions, We speak of
catching cold, of the rising sun, and of the new moon. And so we
speak of the little spring of water at the greatest distance or the
highest elevation from the mouth of a river as its source ; but no
one supposes that the whole of the waters of the river come from this.

166 EFFEOTS OF FORESTS ON RIVERS.

It may be that there is not an inch of its course, or of the courses
of its numerous tributaries and affluents, which does not pass
many of its sources, channels of capillary dimensions, through
which, from time to time, such excess of rainfall has drained off, or
may drain off, into its beds by which the accumulated drainings are
drained off into the sea, if they be not absorbed or evaporated by the
way.

It is under this aspect of springs, and streamletss, and rivers, we
should look at them while considering the local effect upon them of
forests, or of the destruction of these.

Ata conference which I attended in Swartland, at the Cape of
Good Hope, after I had given expression to my views on this subject, one
gentleman who was present stated that a neighbour of his had
planted on his place twelve trees twenty years before, or twenty trees
twelve years before, I do not remember which, and that he did not
believe one drop more rain had fallen in the district since these trees
had been planted than usually fell before! And I think it not im-
possible that this may have been the case; but there are other ways
besides increasing the quautity of the rainfall ia which trees may act
upon the humidity of a country, and even on the rainfall in a way
beneficial to man and beast.

It has frequently been remarked that springs, and streamlets, and
rivers, which have flowed permanently in the vicinity of forests have
ceased to flow when these forests have been destroyed ; nor are cases
awantiog of their flow having been resumed when, by plantations or
natural reproductions, the destroyed trees have been replaced by
others; cases have been cited; and, while apparently in certain
circumstances even the extensive destruction of forests has not
perceptibly affected the deposit of moisture over a widely extended
region, facts are not awanting illustrative of what has been
referred to occuring on an extended, as well as on a limited, scale.

The observations made by Mr Draper in regard to undiminished
rainfall in America must command acceptance. But along with
these we must attend also to the following,

In the Report of the Commissioners of Agriculture, for 1869, it is
stated :—“ From all parts of the State of Maine come up the same
complaint of the diminished volume of water in the streams,
occasioned by clearing off the forests and denuding the hills of trees,
The snows are not so heavy, nor so frequent, as they were twenty or

EFFECTS OF FORESTS ON RIVERS IN AMERICA. 167

thirty years ago; and there is less rain in the summer. Many of
the old trout streams of twenty years ago are now completely dry,
and several parts of the State suffer mvre than formerly from
droughts. Snow covers and protects the ground with less
regularity.”

There is thus brought before us also another of the effects of forests,
or rather of the destruction of forests, but the discussion of this
cannot be prosecuted here without distracting attention from what
more immediately .concerns us.

Mr Marsh in his treatise on “The Earth as Modified by Human
Action,” in writing of the Influences of the Forest on the flow of
springs, says :—“ It is an almost universal and, I believe, well-founded
opinion, that the protection afforded by the forest against the escape
of moisture from its soil by superficial flow and evaporation insures
the permanence and regularity of natural springs, not only within
the limits of the woods, but at some distance beyond its borders, and
thus contributes to the supply of an element essential to both
vegetable and animal life. As the forests are destroyed, the springs
which flowed from the woods, and, consequently, the greater water-
courses fed by them, diminish both in number and volume. This
fact is so familiar in the American States and the British Provinces,
that there are few old residents of the interior of those districts who
are not able to testify to its truth as a matter of personal observation.
My own recollection suggests to me many instances of this sort, and
I remember one case where a small mountain spring. which dis-
appeared soon after the clearing of the ground where it rose, was
recovered about twenty years ago, by simply allowing the bushes and
young trees to giow up on a rocky knoll, not more than half an acre
in extent, immediately above the spring. The ground was hardly
shaded before the water reappeared, and it has ever since continued
to flow without interruption. The hills in the Atlantic States
formerly abounded in springs and brooks, but in many parts of these
States which were cleared a generation or two ago, the hill-pastures
now suffer severely from drought, and in dry seasons furnish to
cattle neither grass nor water.”

And in regard to the effect of the destruction of forests on the
diminution of springs, he subsequently says there is no want of
positive evidence on the subject.

Marchand cites the following instances :—

“Before the felling of the woods, within the last few years,
in the valley of the Soulce, the Combe-s-Mounin and the Little

168 EFFECTS OF FORESTS ON SPRINGS.

Valley, the Sorne furnished a regular and sufficient supply of water
for the ironworks of Unterwyl, which was almost unaffected by
drought or by heavy rains. The Sorne has now become a torrent,
every shower occasions a flood, and after a few days of fine weather
the current falls so low that it has been necessary to change the
water-wheels, because those of the old construction are no longer
able to drive the machinery, and at last to introduce a steam-engine
to prevent the stopage of the works for want of water.

“When the factory of St. Ursannue was established, the river that
furnished its power was abundant, and had, from time immemorial
sufficed for the machinery of a previous factory. Afterwards, the
woods near its sources were cut. The supply of water fell off in con-
sequence, the factory wanted water for half the year, and was at last
obliged to stop altogether.

“The spring of Combefoulat, in the commune of Seleate, was well
known as one of the best in the country; it was remarkably abundant,
and snfficient, in the severest droughts, to supply all the fountains of
the town; but since considerable forests were felled in Combe-de-
pré Martin and in the valley of Combefoulat, the famous spring,
which lies below these woods, has become a mere thread of water, and
disappears altogether in times of drought.

“The spring of Varieux, which formerly supplied the castle of
Pruntrut, lost more than half its water after the clearing of Varieux
and Rougeols. These woods have been replanted, the young trees
are growing well, and, with the woods, the waters of the spring are
increasing.

“The Dog Spring between Pruntrut and Bressancourt has entirely
vanished since the surrounded forest-grounds were brought under
cultivation.

“The Wolf Spring, in the Commune of Soubey, furnishes a remark-
able example of the influence of the woods upon fountains. A few
years ago this spring did not exist. At the place where it now rises,
a small thread of water was observed after very lonz rains, but the
stream disappeared with the rain. The spot is in the middle of a
very steep pasture inclinins to the south. Eighty years ago the
owner of the land, perceiving that young firs were shootinz up in the
upper part of it, determined to let them grow, and they soon formed
a flourishing grove. As soon as they were well grown, a fine spring
appeared in place of the occasional rill, ani furnished abuntant
water in the lungest droughts. For forty or fifty years this spring
was considered the best in the Clos du Doubs. A few years since,

EFFECTS OF FORESTS ON SPRINGS. 169

the grove was felled, and the ground turned again to a pasture.
The spring disappeared with the wood, and is now as dry as it was
ninety years ago.”

“‘Siemoni gives the following remarkable facts from his own
personal observation :

“Tn a rocky nook near the crest of a mountain in the Tuscan
Appennines, there flowed a clear, cool, and perennial fountain,
uniting three distinct springs in a single current. The ancient
beeches around and particularly above the springs were felled.
On the disappearance of the wood, the springs ceased to flow, except
in a thread of water in rainy weather, greatly inferior in quality to
that of the old fountain. The beeches were succeeded by firs, and as
soon as they had grown sufficiently to shade the soil, the springs
began again to flow, and they gradually returned to their former
abundance and quality.

“ This and the next preceding case are of great importance both as
to the action of the wood in maintaining springs, and particularly as
tending to prove that evergreens do not exercise the desiccative
influence ascribed to them in France. The latter instance, shows,
too, that the protective influence of the wood extends far below the
surface, for the quality of the water was determined, no doubt, by
the depth from which it was drawn. The slender occasional supply
after the beeches were cut was rain-water which soaked through the
superficial humus and oozed out at the old orifices, carrying the taste
and temperature of the vegetable soil with it ; the more abundant and
grateful water which flowed before the beeches were cut, and after
the firs were well grown, came from a deeper source and had been
purified, and cooled to the mean temperature of the locality, by
filtering through strata of mineral earth.”

“The influence of the forest on springs,” says Hummel, “is
strikingly shown by an instance at Heilbronn. The woods on the
hills surrounding the town are cut in regular succession every
twentieth year. As the annual cuttings approach a certain point,
the springs yield less water, some of them none at all; but as the
young growth shoots up, they flow more freely, and at length bubble
up again in all their original abundance.”

“Dr Piper states the following case : ‘ Within about half a mile of
my residence there is a pond upon which mills have been standing
for a long time, dating back, I believe, to the first settlement of the
town, These have been kept in constant operation until within some
twenty or thirty years, when the supply of water began to fail. The

R

170 EFFECTS OF FORESTS ON SPRINGS.

pond owes its existence to a stream that has its source in the hills
which stretch some miles to the south. Within the time mentioned,
these hills, which were clothed with a dense forest, have been almost
entirely stripped of trees ; and to the wonder and loss of the mill-
owners, the water in the pool has failed, except in the season of
freshets ; and, what was never heard of before, the stream itself has
been entirely dry. Within the last ten years a new growth of wood
has sprung up on most of the land formerly occupied by the old
forest ; and now the water runs through the year, notwithstanding
the great droughts of the last few years, going back from 1856.’

“Dr Piper quotes from a letter of William C. Bryant the following
remarks: ‘It is 2 common observation that our summers are be-
coming drier and our streams smaller. Take the Cuyahoga as an
illustration,. Fifty years ago large barges loaded with goods went up
and down that river, and one of the vessels engaged in the battle of
Lake Erie, in which the gallant Perry was victorious, was built at
Old Portage, six miles north of Albion, and floated down to the lake.
Now, in an ordinary stage of the water, a canoe or skiff can hardly
pass down the stream. Many a boat of fifty tons burden has been
built and loaded in the Tuscarawas, at New Portage, and sailed to
New Orleans without breaking bulk. Now the river hardly affords a
supply of water at New Portage for the canal. The same may be
said of other streams—they are drying up. And from the same cause
—the destruction of our forests—our summers are growing drier and
our winters colder.’

“ Becquerel and other European writers adduce numerous other
cases where the destruction of forests has caused the disappearance of
springs, a diminution in the volume of rivers, and a lowering of the
level of lakes, and in fact, the evidence in suppprt of the doctrine I
have been maintaining on this subject seems to be as conclusive as
the nature of the case admits. We cannot, it is true, arrive at the
same certainty and precision of result in these inquiries as in those
branches of physical research where exact quantitative appreciation
is possible, and we must content ourselves with probabilities and
approximations. We cannot possibly affirm that the precipitation in
a given locality is increased by the presence, or lessened by the
destruction, of the forest, and from our ignorance of the subterranean
circulation of the waters, we cannot predict, with certainty, the dry-
ing up of a particular spring as a consequence of the felling of the
wood which shelters it; but the general trnth, that the flow of
springs and the normal volume of rivers rise and fall with the exten-

EFFECTS OF FORESTS ON SPRINGS. 171

sion and the diminution of the woods where they originate and
through which they run, is as well established as any proposition is
in the science of physical geography.

“Of the converse proposition, namely, that the planting of new
forests gives rise to new springs, and restores the regular flow of
rivers, I find less of positive proof, however probable it may be, that
such effects would follow. A reason for the want of evidence on the
subject may be, that, under ordinary circumstances, the process of
conversion of bare ground to soil with a well-wooded surface is so
gradual and slow, and the time required for a fair experiment is con-
sequently so long, that many changes produced by the action of the
new geographical element escape the notice and the memory of
ordinary observers. The growth of a forest, including the formation
of a thick stratum of vegetable mould beneath it, is the work of a
generation, its destruction may be accomplished in a day ; and hence,
while the results of one process may, for a considerable time, be
doubtful, if not imperceptible, those of the other are immediately
and readily appreciable. Fortunately, the plantation of a wood pro-
duces other beneficial consequences, which are both sooner realised
and more easily estimated ; and though he who drops the seed is
sowing for a future generation as well as for his own, the planter ofa
grove may hope himself to reap a fair return for his expenditure and
his labour.”

We do not always find all facts in manifest accordance with con-
clusions towards which we may be advancing, or to which we may
previously have come ; and though every fact must necessarily be in
accordance with every other fact we may often find it necessary to
take into account conflicting influences, the effect of which must be
determined ; and to the preceding statement Mr Marsh has appended
the following note :—

“ Some years ago it was popularly believed that the volume of the
Mississippi, like that of the Volga and other rivers of the Eastern
Hemisphere, was diminished by the increased evaporation from its
basin and the drying up of the springs in consequence of the felling of
the forests in the vicinity of the sources of its eastern affluents. The
boatmen of this great river and other intelligent observers now assure
us, however, that the mean and normal level of the Mississippi has
risen within a few years, and that in consequence the river is navi-
gable at low water for boats of greater draught and at higher points
in its course than was the case twenty-five years ago.

“ This supposed increase of volume has been attributed by some to

172 EFFECTS OF FORESTS ON SPRINGS.

the recent re-wooding of the prairies, but the plantations thus far made
are not yet sufficiently extensive to produce an appreciable effect of
this nature ; and besides, while young trees have covered some of the
prairies, the destruction of the forest has been continued perhaps in a
greater proportion in other parts of the basin of the river. A more
plausible opinion is that the substitution of ground that is cultivated,
and consequently spongy and absorbent, for the natural soil of
the prairies, has furnished a veservoir for the rains which are
absorbed by the earth and carried gradually to the river by sub-
terranean flow, instead of running off rapidly from the surface, or, as
is more probable, instead of evaporating or being taken up by the .
vigorous herbaceous vegetation which covers the natural prairie,

“ A phenomenon go contrary to common experience, as would be a
permanent increase in the waters of a great river, will not be
accepted without the most convincing proofs. The present greater
facility of navigation may be attributed to improvements in the
model of the boats, to the removing of sand-banks and other impedi-
ments to the flow of the waters, or to the confining of these waters in
a narrower channel, by extending the embankments of the river, or
to yet other causes.”

A case similar to that occurring on the Wolfspring was reported
to me by Mr 8. Van Reenan, of Constantia. The site of the cele-
brated vineyard so long in possession of his family, measuring some
45 acres, or 224 Morgens, was when granted to his forefather a
forest. There was then onit an abundance of water, such abundance
that though there was no spring on the property there was a large
reservoir and large pond in front of the house, supplied and main-
tained by a stream of water, at least four inches in diameter. But
when the forest was felled, and the vineyard planted in its place, the
supply of water gradually diminished till it was reduced to a supply
one inch in diameter, and ultimately to a supply measuring only a
quarter of an inch.

On the same ground he afterwards formed a plantation, to the
destruction of which by fire I have elsewhere had occasion to refer.

In regard to this he informed me that on the abolition of slavery,
probably about 1838, he feared he should not be able to keep so
much vineyard under cultivation as he had previously done, and he
employed several of his slaves in sowing seeds of the Cluster pine and
of the Stone pine (Pinus pinaster, and Pinus pinea). In one night,
specified by him to me as the night on which the “ Vulcan” entered

EFFECTS OF FORESTS ON SPRINGS. 173

Table Bay with the German Legion, the wood thus formed was con-
sumed by a fire, occasioned by one of his neighbours burning the
bush on his farm, and I understood him to say that the effects were
again the same: a somewhat copious flow of water, which had been
re-established during the growth of the trees, was suddenly stopped
by the denudation of the soil.

In a preceding chapter I have stated that Dr Moffat follows up the
details given by him of the destruction of trees by Bechuanas, which
I have cited, with the remark, “ To this system of extermination may
be attributed the long succession of dry seasons.” ‘To the the same
cause,” says he, “ may be traced the diminution of fountains, and the
entire failure of some which formerly afforded a copious supply, such
as Griqua Town, Campbell, and a great number of others which might
be mentioned. It has been remarked that since the accidental
destruction of whole plains of the Olea similis (wild olive) by fire, near
Griqua Town, as well as the diminishing of large shrubs on the
neighbouring heights a gradual decrease of rain has succeeded in that
region.” And Chapman accompanied information which he gave to me
in regard to the destruction of forests in the interior with a similar
observation. Moffat relates that on his settlement at Latakoo “the
natives were wont to tell of the floods of ancient times, the incessant
showers which clothed the very rocks with verdure, and the giant trees
and forests which once studded the brows of the Mamhana hills and
neighbouring plains. They boasted of the Kururaan and other rivers,
with their impassable torrents, in which the hippopotami played, while
the lowing herds walked to their necks in grass, filling their makukas
(milk sacks) with milk, making every heart to sing for joy.”

He speaks of that river as issuing from caverns in lime stone hills,
full formed, like Minerva fully equipped from the head of Jove ; he
writes in 1842 ‘that it no longer continued to send forth the torrents
it once did :” he speaks of it as “ once a large river emptying itself
into the Gariep, or Orange River, at a distance below the water-fall;”
but as then by absorption lost in its bed about ten miles to the north-
west of its source.

In my own tours thfoughout the Colony I found everywhere in the
superficial aspect of the country indications that, at a period not very
remote, it must have been a land well-watered everywhere. I found
that within the memory of the present occupants of the land there
has been a remarkable change in the aridity, both of limited and of
extensive districts. And I found that in not a few places the change
was observed to follow immediately the destruction of bush. Details

174 EFFECTS OF FORESTS ON SPRINGS.

I have given in a separate volume on the “Hydrology of South
Africa,” :

By Surell it is mentioned, in a note appended to his Hiude sur les
Torrents des Hautes Alpes, “‘ There has been discovered the existence,
in the time of the Romans, of a great corporation of watermen
established on the Durance, which proves that there was then a
considerable flottage, or transport, of timber in rafts, which has been
for along time given up entirely, and which proves also that this
department was then covered with abounding forests, of which there
exist now only but meagre shreds.” But now, that river has
made for itself a bed. which in some places exceeds a mile and a
quarter in breadth, while the ordinary flow of the river is confined to
a current little more than thirty feet in width; and from Young’s
travels in France it appears that so early as 1789 it was computed to
have covered, with gravel and pebbles not less than 130,000 acres,
“which, but for its inundations, would have been the forest land in
the province.” Thus have we there land undermined and washed
away,—fertile land covered with the debris, and the fertilizing
material carried away to the sea.

The fact in regard to the former state of the Durance is mentioned
also by Ladoucette in his Histoire, &c , des Hautes Alpes.

In the Ami des Sciences, of December 11, 1873, there is given
the following statement by M. Cantegril, sub-inspector of forests.
In explanation of one of the statements in this I may state that,
with a view to the conservation and improvement of the forests of
France, certain regulations had been laid down for the re-arrangement
of the forests of the States, and liberal arrangements made for the
extension of these regulations, to the management of forests belong-
ing to communes, where this could be done with their consent.

“Upon the territory of the commune of Labruguiére (Tarn) there
is a forest of 1,834 hectares, (4,524 acres,) known as the forest of
Montant, and owned by the commune. It extends northward on the
Montagne-Noire, and the soil is granitic, with a maximum altitude of
1,243 meters, and a slope of from 15 to 60 in 100. A little water-
course, the Caunan brook, rises in this forest and drains the waters
of two-thirds of its surface. At the entrance of the forest, and along
this brook, are located several fulling mills, each requiring eight
horse-power, and moved by water-wheels which work the beaters of
the machines. ;

“The commune of Labruguiére had long been noted for its

EFFECTS OF FORESTS ON SPRINGS. 175

opposition to the forest regulations; and the cutting of wood, together
with the abuse of pasturage, had converted the forest into an immense
waste, so that this great property would hardly pay the cost of
guarding it and afford a meagre supply of wood for its inhabitants.

“While the forest was thus ruined and the soil denuded, the waters
after each heavy rain swept down through the valley, bringing with
them great quantities of gravel, the debris of which still encumbers
the channel of this stream. The violence of these floods was some-
times so great that they were compelled to stop the machines for
some time. But in the summer time another inconvenience made its
appearance. Little by little the drought extended, the flow of waters
became insignificant, the mills stood idle, or could be run only
occasionally for a short time.

“ About 1840 the municipal authorities began to give information to
the population relative to their true interests, and under the protection
of a better supervision the work of replanting has been well managed,
and the forest is to-day in successful growth.

“In proportion as the replanting progressed, the precarious use of
the mills ceased, and the regime of the water-courses was greatly
modified. They now no longer swelled into sudden and violent floods,
compelling the machines to stop, but the rise did not begin until six
or eight hours after the rains began. They rose steadily to their
maximum, and then subsided in the same manner. In short, the mills
were no longer obliged to stop work, and the water was always enough
to run two fulling machines, and sometimes three.

“ This example is remarkable in this, that all the other circumstances
had remained the same, and therefore we can only attribute to the
reforesting the changes that occurred, namely, diminution of the flood
at the time of rain, and an increase in its flow during other times.”

From a report made by Henry J. Wisner, United States Consul at
Sonneberg, in the Department of State, in November, 1873, the river
Elbe between the years 1787 and 1837, a period of half a century,
diminished at Attenbruecke, in Hanover, ten feet in depth, as a direct
result of the cutting off of forests in the region where the tributaries
have their origin.

In 1873, there appeared in the Zeitschrift des dsterr. Ingenieur
und Architecten Vereins, a paper by Herr Gustav Wex, Counsellor
of State, and Director-in-Chief of works undertaken for the regu-
lating of the flow of the Danube, “On the Diminution of Water in
Streams and Rivers, accompanied by Occasional Inundations in

176 EFFECRS OF FORESTS ON SPRINGS.

Agricultural: districts.” In this the author, after having in an Intro-
duction shown the great importance of the subject, invites his
colleagues as well as other naturalists to examine his book, and
appeals for the support of the Government in favour of his pro-
positions, especially those departments of the Government which are
more specially occupied with the care and defence of the economical
interests of the public; after which he treats, in the first place, of the
diminution of water in the rivers and streams, and consequently the
diminution in the out-flow. He proceeds upon personal observations
during a period of forty years, made on the Austro-Hungarian great
rivers and streams, with relation to the conditions of their out-flow,
and he comes to the conclusion that the volume of water at present
discharged has decreased considerably during a series of years.

Corresponding facts have been attested also by others, and judging
from these they have given their opinion that the volume of water
discharged by many streams appears to be diminishing. But the
correctness of this conclusion has been disputed, and the author
discusses the observations which have been adduced against the views
adopted by him, as well as those upon which his conclusions were
based.

The author proceeds on data supplied in the Second Part of the
Allegmeine Linder und Volkerkunde, by Berghaus, in regard to the
depth of water in the Rhine at Emmerich, of the Elbe at Magdeburg,
and of the Oder at Kiistrain, according to which the average and
lower depths of water have experienced a diminution by no means
inconsiderable, while the floods of greatest depth present, on the
other hand, apparently an increase both in frequency of occurrence
and in magnitude.

Dr Berghaus became convinced through an examination of the
tables of the depth of water in the Elbe and the Oder that on the
main streams of both the flow or delivery have been considerably
diminished ; and he expressed a fear that these two rivers of Germany
were threatening to disappear from the number of navigable rivers,
which would be the case if the reduction in the depth of water should
go on at the same rate at which it had proved to be diminishing since
the year 1781.

Herr Wex, by long-continued observations and studies, had come to
the same conclusion as Berghaus, and he maintains against objections
brought forward on different sides the opinion that there has been a
progressive diminution in the quantity of water in these rivers, and
not less really so in the Vistula and the Danube.

TREATISE BY HERR WEX. VW

Amongst the objections referred to:—1. Herr F. Hagen, Royal
Prussian Geheime Obverbaurath, and Ober-Landes-Bau-Director, found
by actual measurement of the Rhine, at Dusseldorf, that the
diminution of the highest and of the medium floods was but incon-
siderable—on an average, the one 2-9 and the other 1-6 lines per
annum, about one-fourth and one-eighth cf an inch. And he alleges
that this may be accounted for by the modifications which have
been made in the river’s bed, whereby the supplies from the
melting of ice have been retarded, and the flowing away of floods
promoted.

2. Herr Maass, Prussian Royal Hydraulic Inspector, has found by
examination of the observations on the height of the Elbe, made for
143 years in the Pegel at Magdeburg, a considerable diminution
in the greatest, medium, and lowest heights of the river, amounting
to 17, to 354, and to 34 z/l/, or inches ; but he alleges this reduction
to be the consequence of the modification of the bed of the river
occasioning a deepening of the bed, and an increased rapidity of
flow.

3. A conjecture, which has been expressed, that such considerable
quantities of water may be carried away in the more frequent and
higher floods of later times as to compensate for the diminution in
the medium and lower heights of the flow at other times.

The author shows—1. By the measurements made by the late Herr
Grebenau, Bavarian Royal Bau-[nspector, at Germersheim, on the
pegel at Sondersheim, throughout a period of twenty-eight years,
which gave not only information in regard to the depth of the river,
as ascertained by the said gauge, but also in regard to the delivery
or quantity of the flow, that the diminution of the average depth
and a diminution in the delivery or flow go together.

2, According to observations made by the £lbe-Stromschau-Com-
mission, it appears that there has been indeed a deepening of the
bed of the river in its upper part; but, on the other hand, an eleva-
tion of the river bed by the silting of sand in the middle and the lower
portion of it. So that the diminution in the height of the water at
the gauge at Magdeburg cannot be attributed to a deepening of the
bed of the stream.

3. That the high floods are no compensation for the diminution of
the delivery by the low and medium flow is proved by the author—
first, by the before-mentioned measurements by the gauge at Sonders-
heim, according to which differences in the delivery are found to be
nearly proportionate to the depth of the flow; and, further, by

8

178 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

measurements made for thirty-two years on the Danube gauge at
Alt-Orsova, according to which is established not only a lowering in
the medium and the lowest flows, but also in those of greatest height,
which phenomenon, different from what has been seen in other rivers,
the author attributes to the circumstance that the floods in each of
the large tributaries occur at different times.

“On the occasion of a Commission to prepare a scheme or project
for the regulation of the flow of the latger streams and rivers of
Austria being entrusted to me by the Government,” writes Herr
Wex, “I set about, as a preliminary measure, the study of the
delivery of water by these rivers, and in doing so I have invariably
found that the delivery, measured by such appliances and means of
ascertaining this, has of late years greatly diminished.

“ Although a corresponding fact had been previously observed by
scientific students of natural history, and the phenomenon of a
diminution in the delivery of different rivers had been ascertained,
the correctness of the conclusion arrived at had been called in question
by other scientific men, and more especially by Hydrotechnikern
[hydrologists and students of hydraulic-engineering ?] I shall there-
fore state the views advanced by them, and thereafter meet them by
observations made during protracted periods on some of the principal
rivers of Central Europe.

“Herr F. Hagen, Royal Prussian Gehewme Oberbaurath and Ober-
Landes-Bau-Director, has in the last (the third) edition of his Hand-
buches der Wasserbau Kunst, for the year 1871, called in question the
correctness of observations hitherto made on the height of water in
streams and rivers, and of deductions drawn from these in regard to
a diminished flow of water in them, and he bases his opposing views
on observations made with the Rhine pegel at Dusseldorf since the
year 1800, and on the recorded observations on the height of the
level of the river for seventy-one years.

“Herr Hagen has calculated for every separate year the arithmetical
mean yielded by the daily observed height of the water, and also’ the
average annual height of the water, he has also noted the highest and
lowest heights of the water in each year; and he has represented
these three conditions of the water in a diagram, by which he makes
apparent that no very considerable diminution of the waters has
occurred.

“In consequence of the great importance of the matter, Herr Hagen
has submitted the former selected observations on the state of the
river to a calculation founded on the least common multiple, and

STATEMENTS BY HERR HAGEN. 179

thus found that in the course of the last 71 years, on the Rhone at
Dusseldorf, there has been a reduction of the highest floods to the
extent of 2-9 lines, of the mean to the extent of 1:6 lines, while there
has been a rise in the lowest of 0-2 lines per annum. But on these
calculations Herr Hagen himself does not lay particular stress, as
there may be errors, he says, in the results obtained to the extent
of 2-2’, 0-9", and 0-7" respectively.

“ Herr Hagen says further: ‘It may well be imagined that in the
course of time a diminution in the highest and the mean levels has
taken place ; and that for the reason that in later years, through the
modifications of the water-course which have occurred, the flotation
of ice has been impeded, the flow of water from the higher-lying
districts of the river's basin has been promoted ; whence the small
annual reduction of the calculated mean river-height may have
followed.’

“Subsequently, Herr Hagen having expressed doubts in regard to
the statements of certain _Hydrotechnikern, relative to a great
diminution in the level and delivery of the Weser, from a comparison
of the observations made by the pegel at Minden and at Schliissel-
burg, comes to the following conclusion: ‘It thence appears that,
in so far as observations made up to this time can show, it is as
impossible to give with certainty a verdict in regard to any general
diminution of its waters in regard to the Weser as in regard to the
Rhone.’

‘“‘ Although the observations made on three gauges on two rivers
lead Herr Hagen to express himself thus guardedly on the subject of
a lowering of the water-level, yet the greater number of Hydrotechni-
kern—because observations continued through many years, and com-
parison of the water-levels at distant periods of other rivers are not
at their command, and because they consider Herr Hagen an
infallible authority on all that relates to hydraulic engineering—have
come to the conclusion that in general there has not taken place any
great diminution in the flow and delivery of streams and rivers.

“Herr Maass, the Prussian Royal Wasserbau-Inspector, has
published, in the Zettschrift fiir Bauwesen von Erbkam, for the year
1870, observations of the height of the river Elbe for the period of
143 years, extending from 1727 to 1369, with a diagram represen-
tative of these observations ; and from these he has drawn the con-
clusions that within this period the waters of the Elbe have gradually
diminished in the following arithmetical means: a. In the highest
levels reached, 17 inches ; 6. In the lowest level observed, 34 inches ;

180 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

c. In the mean of the whole of the observations made in the several
years, 354 inches.

“ According to the views of Herr Maass the lowering of the heights
of the water level is not a consequence of any diminution of the
quantity of water now flowing into the Elbe, but the result of the
rectification of the river bed, an extensive deepening of this as a
consequence of that modification, and an increase of the rapidity of
the flow or delivery ‘of the river. Herr Maass attaches importance to
the effects of these in lowering the level of the streams, and remarks
that no further lowering of that level is to be expected, because there
are no additional works of modification in contemplation.

“Ag the observations and views of Herr Hagen and of Herr Maass
are diametrically opposed to observations which I have myself made
on several rivers during the last 40 years, I have brought together the
observations I have made on several rivers and streams, and the con-
clusions I have drawn from them, for publication as measurements of
the water level for many years, upon which reliance may be placed,
as it is only in being in possession of these data that I could have
been so bold as to come forward with any confidence as the opponent
of an authority so distinguished throughout the whole of Germany as
is Herr Hagen in matters pertaining to Hydrotechnics.

“Tn the course of my observations on the subject in question there
came into my hands the remarkable work, Allgemeine Lénder-und
Volkerkunde, by Dr Heinrich Bergman,—volume second, Umrises der
Hydrographie, for the year 1837,—and I found in this work, and in
that issued by the same author and by J. Perthes, Hydro-hystorischen
Uebersichten der deutschen Stréme, for the year 1838, collected to-
gether much valuable material relative to the height of the water
and to the floating of the ice in the rivers.

“From the observations on the river level made with the pegel at
Emmerich, on the frontier of Holland, for the period of 66 years,
from 1770 to 1835, and with these the observations made with the
pegel at Cologne for the period of 54 years, from 1782 to 1835, and
in addition to these the observations made on the Elbe with the
pegel at Magdeburg, for the period of 108 years, from 1728 to 1835,
and on the Oder with the pegel at Kiistrin, for the period of 58 years,
from 1778 to 1835, has the distinguished hydrographer Berghaus
determined the measurements of the highest and of the lowest levels
of these rivers, and from them calculated arithmetically the annual
mean levels. He has represented these by diagrams, and given
diagrams representative of the average height of the rivers in the

STATEMENTS BY DR BERGHAUS. 181

different months of the year, and of the movement of the ice and of
floods ; and finally, he has in addition to these tabulated statements
given others illustrative of the influence of the rainfall on the
quantity of water carried off by the rivers, and has exhibited this in a
way so thorough and efficient as is not equalled in any other work on
Hydrotechnics. By which means Berghaus as a precursor has shown
to Hydrotechnikern in what way observations on the ever-varying
levels of rivers should be brought together and compared, in order to
present a distinct picture of the hydrographic phenomena, or of the
river life of the stream, and from this correctly to draw inferences
and final conclusions.

“From these extremely detailed and deeply interesting investiga-
tions by Berghaus I make, amongst others, the following ting
deductions :—

“From the ‘Hydrographie’ of Dr Berghaus I have prepared a
diagram, which I have appended to this treatise, in which I have
represented what were the highest, and the lowest, and the calculated
mean annual water-levels of the Rhone, observed by the pegel at
Emmerich, from the year 1770 to 1835. From this diagram it
appears at a glance that the water-level of the several years is very
far indeed from being regular, but in successive years they rise and
fall; and it is consequently difficult to represent by a continuous
line, or to calculate a mean representative of the diminution or
increase of the water-level for a period of some length, as Herr Hagen
also states to be the case. I therefore hold to the opinion that the
method adopted by Dr Berghaus, comparing the arithmetical mean of
the water-level during a more lengthened period than two years, is
more easy and supplies data upon which more reliance can be placed ;
and from the data thus procured, inferring or deducing whether there
has been any rise or fall in the river-level. If, then, we divide the
observations made during the period of 66 years into those made in
the first period of 33 years, from 1770 to 1802, and those made in
the second period of 33 years, from 1803 and 1835 ; and if from these
two equal periods of 33 years each we calculate and compare theannual
average levels of the river in each, the result will be, we shall find
that in the second period the average height of that level was 10 in
excess of the first; but on the contrary, the annual water-level has
fallen 1’ 42” 5” cand the lowest 1’ 1” 3”, when compared with the
corresponding ee period from 1779 to 1802.

‘As the arithmetically determined mean of the river-level in the
first period, from 1770 to 1802, was only taken incidentally for com-

182 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

parison, without reference to the fact whether in the course of these
33 years any rise or fall of the water-level had taken place, it is clear
that the above numbers represent the reduction which had taken
place in the lowest levels and in the annual mean levels of the river
in the second period of 33 years—that is, for the half of the whole
period embraced by the observations made.

“And the same remark will falso apply to all subsequent com-
parisons of the water-level in two periods.

“Tf we consider further the observations made of the pegel on the
Rhone at Cologne, from 1782 to 1835 [which was also appended to
the treatise], and again divide the period embraced of 54 years into
two consecutive periods of 27 years each, and by calculation deter-
mine the mean annual levels, we find that in the second of these
periods, that from 1809 to 1835, the mean height of highest floods
has risen about 0’ 1” 66”; while, on the contrary, the mean annual
height has fallen about 4:27’, and that of the lowest levels about
7°21”, as compared with those of the first half of the period, that
from 1782 to 1808.

“From the foregoing deductions it is apparent that in the two
principal pegels on the Rhine at Emmerich and Cologne—during
the periods of 66 and of 54 years, embraced by them respectively
from 1770, and from 1782 to 1835—there has taken place a not
inconsiderable fall both in the lowest levels and in the mean annual
levels ; and that only the mean of the highest levels is found to be
somewhat higher in the second as compared with the earlier halves
of the periods embraced by the observations,

“ As during the period of observation extending from 1770 to 1835,
no such works of modification of the river's course as could have
produced any deepening of the bed of the stream at Cologne and at
Emmerich, or any increase of the rapidity of water-flow, and con-
sequent lowering of the water-level, had been carried on, the fall of
that level in the case of the lowest and the mean states of the river,
during the later halves of the periods embraced by the observations
in question, can only be attributed to a diminished quantity of water
passing down the Rhine ; while the small rise in the annual mean of
the highest point reached, has to be ascribed to more frequent and
higher floods. ;

“That the fall in the low and mean annual proves to be less than
it has been in some other rivers is accounted for, by Berghaus, by a
reference to the fact that the Rhine is fed, in a great measure, by the
confluence of numerous currents from the ice and snow on the Alps ;

EXAMINATION OF STATEMENT BY HERR HAGEN. 183

which explanation I would follow up with the remark that by the
Lake of Constance, which receives the waters of the Upper Rhine
and afterwards emits them gradually, this river regulates its delivery
at lower-lying points; and that, as a consequence of this, the reduc-
tion in its delivery at lowest, and in mean annual levels, can show
itself in but very minute measurements.

“ The circumstance that the fall, in these levels, shows itself much
more considerable at the pegel at Emmerich than at the pegel at
Cologne, is explained, by Berghaus, by the fact that between Cologne
and Emmerich there flow into the Rhine the Wupper, the Ruhr, the
Emtsche, and the Lippe, which are less uniform in their flow than is
the Rhine which is thus fed.

“ Adverting now to the diagram and tabulated statement of the
level of the Rhine, as indicated by the pegel at Dusseldorf, situated
between Cologne and Emmerich, for the period from 1800 to 1871,
published by Herr Hagen, let us examine it with some care.

“Herr Hagen found by his method of investigation that the
annual mean level had fallen upon an average about 1°6 line, which
for a period of 50 years gives a fall of 6°66 inches.

“ As according to the observations tabulated by Berghaus the fall
in the mean annual level given above reduced to a like period of 50
years gives at the pegel at Emmerich 24°88 inches, and at the pegel
at Cologne 7°91 inches; from this it appears that Herr Hagen’s
calculation of the fall of the water level at Dusseldorf, amounting to
6°66 inches, although founded on observations embracing a different
period of time, comes very near to the calculation made of the fall at
the comparatively proximate pegel at Cologne, from which it follows
that the calculated fall must be regarded as an actual fact, and not
an error in calculation, as Herr Hagen had intimated that it not
improbably might be.

“ Although according to the older tabulated observations of
Berghaus for the period from 1770 to 1835, there appears a some-
what higher rise in the highest floods of the Rhine, amounting to
from 10 to 18 lines,—still the calculation of Herr Hagen that the
level reached by the high floods had fallen 2:9’ per annum, and
consequently 12” 1” in fifty years, may possibly be correct ; and are
probably so, since in consequence of the extensive rectification of the
river bed between Basle and Manheim since 1830, the rapid flow of
the high floods must have been accelerated.

“Herr Hagen has found a very slight rise in the level of the
lowest observations at Dusseldorf, about 0°2’” per annum, consequently

184 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

only about 10 lines, or five-sixths of an inch, for 50 years, And this
is explicable in that the bed of the stream has been at that place
reduced in breadth within later decades; and also in that the extensive
rectifications of the course of the Rhine, by cuttings above Manheim,
has made it possible that by means of sand and fine silt, transported
to the lower reaches of the river, the bed of the stream at Dusseldorf
may have become somewhat silted up and elevated in a way similar
to what has occurred to a still greater degree in the middle and lower
sections of the Elbe. '

“ From the foregoing references it is evident that the conclusions
drawn by Herr Hagen, that the observations made up to this time on
the Rhine do not indicate any general lowering of the water level, are
erroneous. And if he had been acquainted with the older observa-
tions at Emmerich and Cologne, published by Berghaus, or if he had
more skilfully compared the observations, extending over a period of
71 years, at Dusseldorf, he would probably have come to a conclu-
sion the very contrary to that to which he has come.

“Tn order to obtain data on which reliance might be placed in regard
to the flow of the Rhine above Dusseldorf and Cologne, I addressed
myself to the distinguished hydrographer Herr Grebenau, Bavarian
Royal Bau-Inspector at Gemersheim, who was for many years engaged
in the rectification of the new bed of the Rhine, and from him I re-
ceived not only the details of observations on the river-level at the
pegel at Sondersheim for the period of 28 years from 1840 to 1867,
but also the results of investigations on the delivery or quantity of
water passing each year through the cuttings of the Rhine bed at
Gemersheim, which Herr Grebenau had obtained with great care and
precision, partly by means of numerous special measurements of
vertical sections of the current and the rapidity of the flow, and
partly by means of calculations according to the latest formulas of
experimentally-obtained co-efficients.

“ When these tabulated observations on the water level, and the
diagram representative of the quantity of water delivered for the
period of 28 years, are divided into two successive periods of 14 years
each; and when for each of these there is calculated the means both of
the levels and of the delivery, there are obtained from these the
following results: the mean annual water level in the latter period of
14 years is about 432 métres, or 17°63 inches lower, and the delivery
is about 6966 cubic feet per second less, than in the former.

“ Along with this it must be admitted that, to a great extent, the
lowering of the mean annual level of the river is to be ascribed to a

STATEMENT BY HERR WEX. 185

considerable deepening of the bed of the stream, consequent upon
extensive rectifications of the river by cuttings.

“Further, although it must not be concealed that the different
water-levels measured, and deliveries calculated, cannot be relied on
as absolutely correct, and it is unquestionably the case that the
deepening of the bed of the stream had a great effect upon the
lowering of the level and the reduction of the delivery, still it must
be noted that the fall and diminution in the one and the other, which
have been determined, have been brought to light by the same
method, and are in any case approximately correct ; from which it
follows as a consequence, that in the latter period (embracing 28
years), at the pegel at Germersheim, the body of water delivered by
the Rhine has considerably diminished.

“ Along with this must be noted the very remarkable fact, that
the beautifully rectified course of the Rhine from Manheim upwards
toward Basle, converting it almost into a regular canal, has now become
in a great measure unnavigable: in consequence—first, of the
numerous persistent and extending beds of silt in the bed of the

-Yiver, and resting in the concave sweep; and next, of the con-
tinually increasing serpentine character of the course of the stream; and
finally, of the low depth of water in the many crossings of the stream
from one concave bay to another, all which can now be accounted
for by the fact that the normal breadth of the river-bed was originally
taken to be greater than it actually is, from which it follows that the
current, in consequence of the diminished water-flow, has not now
the force necessary to remove these masses of silt, and to lodge
them only on the convex or projecting shores of the river-bed.

“ The foregoing results of observations made on four gauges on the
Rhine, serve to strengthen my allegations in regard to this river ;
and I proceed to the consideration of the information obtained in
regard to the other rivers of Central Europe.”

There are given in an appendix the several tabulated observations
and diagrams referred to. There follow discussions similar to those
which have been quoted in detail: 1. Of observations made on the
Elbe, with a tabulated statement of observations of the highest, mean,
and lowest levels of the river at Magdeburg, with the calculated means,
and a diagram representative of the same, from the year 1728 to 1869,
a division of the former of these being made into periods of 50 years; a
diagram representative of the calculated delivery of the Elbe in the
several months of the year during the two periods from 1731 to 1780,
and from 1781 to1830 ; and a diagram representative of the depth in

Tt

186 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

métres at twenty-five different stations on the river on several occasions
of very low water.

2, Of observations on the Vistula, with a tabulated statement of the
highest and lowest levels, observed at Weichsel near Kurzebrack in
each year from 1809 to 1871, with calculated mean annual depth of
the river, and a diagram representative of these. It had been alleged
that a greater quantity of water was being delivered by the Vistula
than previously, and reference is made to these tables as proof that
this was unwarranted, and as supplying evidence that the delivery
was being diminished.

3. In regard to the Danube at Vienna, with a tabulated statement
of the highest and lowest water levels, observed at Vienna in each
year from 1826 to 1871, with the calculated mean level; a tabulated
statement of similar observations at Orsova, for the years from 1840 to
1871; and a tabulated statement for comparison of the height of the
Danube at ten other stations on the river ; a diagram representative
of the observations at Vienna, in the period 1849-1871; a diagram
representative of the delivery or flow in the several months of the
year in the two periods 1826-1848, 1849-1871; and a diagram
representative of the comparative water levels at the several stations
on the Danube mentioned in the tabulated statement.

There ‘is given a similar tabulated statement of observations made
at the pegel on the Oder at Kiistrin, from 1778 to 1835. And in
regard to all of these he writes: “To facilitate the comparison the
fall in the level in the five rivers named, I have reduced the
recorded observations to their equivalents for a period of 50 years,
and I have thus obtained the results embodied in the following
table. The measurements are given in Rhenish inches :—

187

TABLE OF OBSERVATIONS.

Fall in the mean level

Rise or fall of mean in

Lowering of mean level

Names of Rivers and location Periods : :

we pega tenia, = | BMT | ee | ee
Lowest. Mean, Lowest. Mean,

Rhine, at Emmerich,...........]1770-1835, 66 years,....| 13°25 16°42 + 0°83 20°06 24°88

» at Dusseldorf,.........../ 1800-1870, 71 years,....) —*60 4°73 + 8°58 — 0°83 6°66

» at Cologne,............../ 1782-1835, 54 years...) 7°21 4:27 +1:5 13°33 791

» at Germersheim,,...,..| 1840-1867, 28 years,....junknown| 16°63 unknown unknown} 59°39

for 29 years,

Elbe, at Magdeburg,...........] 1728-1869, 142 years,...] 29° 31° -9: 15:76 16:85

‘Oder, at Kiistrin,...............{ 1778-1835, 58 years,....) 9°45 10:18 x 1:56 16:27 17:45
Vistula, at Marienwerder,.....| 1809-1871, 63 years,....| 27°66 16°50 - 158 43°90 26°2

Danube, at Vienna,............ 1826-1871, 46 years,....) 5°04 8:46 - 10:07 11:39 18°39

» at Orsova,..............| 1840-1871, 32 years,....| 14°76 17°62 — 11:08 46:12 55:06

188 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

“If we omit from this table the observations made with the pegel
on the Rhine at Germersheim,—as the lowering of the water level
there, together with the deepening of the river bed, is mainly attri-
butable to the extensive rectifications of the river by cuttings, and only
in a comparatively small degree to a diminution of the delivery,—we
find that the greatest lowering of the water level is on the Danube at
Orsova, amounting to from 46 to 55 inches; on the Vistula at Marien-
werder from 26 to 43°9 inches; and on the Rhine at Emmerich from
20 to 24:8 inches ; and on the other pegels of the rivers named from
6 to 18 inches.

“Tn the Elbe the falls of the lowest and of the mean water levels
are 15°76 and 16:28; and they might indeed have been considerably
greater had it not been that since 1842, in consequence of the great
silting up of the river bed with sand, the lower water levels have been
elevated from 13 to 22 inches.

“The lowering of the water level becomes so much the greater the
larger the river is, and the nearer to the mouth of the river in the sea
that the pegel is situated, and this for the reason that the region
drained by the river is the greater, and that it is the sum of the reduc-
tions in the levels of all the brooks and streams and lesser rivers
which have flowed into the main stream which is there represented
in this greater lowering of the river level.

“In regard to the high floods of the said rivers, we see from the
diagrams submitted that, with the single exception of the station at
Orsova, in all of them floods have latterly occurred more frequently
and reached a greater height than in the earlier years in which the
observations were made, from which it appears clear as day that in
these rivers at present, at times of high flood, a much greater
quantity of water is delivered by them than in the earlier years.

“From the diagrams representative of the high floods, it is further
apparent that in the earlier times of observation the rise of water, in
consecutive years, was more uniform ; whereas, in the later decades
of the periods embraced by the observations, in one year there
occurred a very great flood, and in the year before or the year
after only a very insignificant rise of water; from which it follows
that the alternation of very dry with very wet years occurs more
frequently and to a much more marked degree now than for-
merly.

“This is particularly apparent in the tabulated observations on
the Elbe and the Vistula.

“The cause of this remarkable phenomenon lies evidently in this,

TREATISE BY HERR WEX. 189

that since the clearing away of many forests, more especially in the
mountains, deluges of rain and rain-spouts occur more frequently ;
further, while the rain-water, in lands devoid of trees, sinks less into
the soil, it at the same time more speedily reaches the brooks
and streams and rivers, and fills and overflows these water-courses ;
and finally, the body of water, now tearing along with rapidity, cuts
up the mountain sides cleared of forests, and fills up the beds of the
brooks and streams and rivers with earth and sand and rubbish, and
so raises the bed of the river—whence a higher level is reached by the
water-surface.

“The correctness of this allegation is being attested, in a way
which it is saddening to contemplate, by the ever more frequently
recurring inundations in Italy, in the south of France, in Hungary,
in Bohemia, and in many other lands.

“ The aforementioned phenomena of high floods led a distinguished
meteorologist to express to me the conjecture that the great increase
of the body of water passing along our water-courses, in high floods,
may be about equal to the diminution observable in the low and
mean levels.

“This conjecture, however, is not in accordance with the facts of
the case, because, as I have already shown, in the case of the Rhine
and of the Elbe, the annual delivery is approximately represented by
the mean water-levels, which, even in all these five rivers named, is
on the decrease. But the incorrectness of the conjecture is more
particularly manifested by the tabulated observations by the pegel at
Orsova, in as much as, from the geographical position of the very
extensive basin drained by the Danube, it frequently happens that
the high floods of several of the large affluents coincide in time with
that of low water level in several other important accessories of the
river, and yet there is not an equivalent compensation for the lesser
supply coming from the one class of affluents, in the greater supply
coming from the other, in as much as, even at Orsova, the average
of the floods of the mean and of the lowest levels have fallen still
more than have these in the four other rivers named.

“‘But even if, in accordance with this conjecture, in particular years
with repeated extraordinary high floods, some such equalisation of
the increased and the diminished delivery of a river should occur,
this would supply but little consolation for man, as the great evils
consequent on the diminution of the delivery of water at the lowest
and the mean levels are not obviated by the more frequent occurrence
of the greater delivery during high floods, but are being more than

190 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

ever incveased in that those high floods now occasion more frequent
and more disastrous inundations.”

Herr Wex goes on to say:—‘‘ Having in foregoing statements given
indisputable evidence that in the five principal rivers of Central
Europe,—the Danube, the Rhine, the Elbe, the Vistula, and the
Oder, the basins of which embrace an area of 26,860 [German 1]
square miles,*—the lowest and the mean annual water levels, and
consequently also the quantities of water delivered by these rivers,
during a lengthened period of many years, has been continually
decreasing, we may,from this draw the following conclusions :—

“1, As the aforesaid rivers are fed mainly by the brooks and
streams which flow into them, there must have been also in these a
continued decrease in the quantity of water delivered by them for a
great many years, from which we may further conclude that if observa-
tions had been made on the levels of the different feeders,
similar to those which have been made on the five large rivers named,
and these had been compared, they would have supplied results
similar to those at which we have arrived concerning these.

“ The correctness of this allegation receives confirmation from the
fact that many manufactories, &c., which have been built during the
last fifty years, on rivulets and streams, have experienced a marked
diminution in the quantity of water coming through their water-
leadings, and it has been found necessary to employ steam-engines to
meet the deficiency of their water power, which was originally
sufficient for the work they had to do.

“9, As it is possible that the causes which have produced the
effect of the lowering of the water level, and diminution of the
quantity of water delivered in these five river basins, operate
equally in the basins of the other rivers and streams in Europe, and
not only so but in the most populous and cultivated districts of the
other three quarters of the globe—it may be assumed that in most of
the streams and rivers on the surface of the earth a similar lowering
in the lowest and mean levels of the body of water delivered by them
has taken place ; while the high floods in the same, reaching a higher
point, and becoming of more frequency, discharge a greater quantity
of water, and produce more extensive devastating inundations than
previously was ‘the case.

“3. If the causes which have operated in producing the decrease of
the usual water flow of the streams and rivers, with the rapid over-

* A German mile is equal to 44 English miles,

TREATISE BY HERR WEX. 191

flowing of them in times of flood, in the course of the last 140 years,
were to continue to operate also in the future, it is evident from what
has taken place that in brooks, and streams, and rivers, the lowest
and the mean levels of these may be expected to be lowered still
further in the fature. And the question forces itself upon every one
involuntarily, to what degree may this diminution in the quantity of
water thus delivered by the several streams and rivers be carried ?

“Tn the principal rivers, the Danube, Rhine, Elbe, and Vistula, it
is scarcely to be supposed that the lowering of the lowest level of the
flow will go on till it reach the very ground of the bed of the stream,
occasioning the temporary drying up of the river altogether :
seeing that the two first named rivers are in part fed by the melting
of the masses of ice and snow lying on the Alps; while, further, it is
to be hoped that the occasion of the lowering of the water level will
not be carried beyond a certain limit ; and finally, because the highest
and the lowest level of the stream occur in many of these streams
and affluents at different times of the year from what they do in
others.

“Tf, however, we look on the other hand to the very considerable
lowering of the lowest and the mean levels of the rivers mentioned in
the foregoing table, which has taken place within the comparatively
short period of 50 years, we are brought to the disturbing conclusion
that these five rivers, in the course of 100 or of 200 years, may have
their lowest and average levels so lowered that they will be no longer
navigable if we do not take measures to counteract the cause which
is continuously operating to effect the diminution of the water flow
in these rivers.

“‘ The brooks and streams, on the contrary, which drain only basins
of limited extent, may, by the continuous lowering of the water level ;
and by the diminution of the delivery in them, be converted into inter-
mittent torrents, which lie dry during many months of the year, and
then, on a fall of rain, snddenly fill and deliver immense bodies of
water.

That the dread of this is not without foundation is proved by
numerous cases in which very large rivers, which in previous cen-
turies, according to historical records, were navigable at all seasons
of the year, have become now only wildbdche and torrents, such as,
for example, are most of the torrents which characterise the southern
slopes of the Alps in Italy and in Carinthia, Many other streams
and rivers, which not many decades back were of full water, have
latterly, and within the memory of man, become torrential streams,

192 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

which pour down large bodies of water when, and only when, there
have been dashes of rain, and from what has been stated it may be seen
that the prognostication is not without foundation when I allege that
if the causes which have, during the last 140 years, occasioned a
lowering of the water-level and diminution of the above-named five
European rivers shall go on operating in the time immediately before
us, the result will be that the level will be still further lowered and
the delivery diminished, until bye and bye they become so reduced
as to be unnavigable.

“ Although, beyond the results which have been published by Dr
Berghaus in his ‘ Hydrography,’ which has been quoted, and which,
unhappily, are but little known, we have hitherto been unable to
obtain reliable compilations and comparisons of observations con-
tinued for many years of the water-level on the larger rivers, there
are men of observation and experience who, in consequence of what
they have noticed on some few rivers, have called attention to the
diminution of the water supply which is going on, An instance of
this we have in the following communication, which is well-deserving
of consideration, found in an article, by F. Perrot, in Deutsche Monat-
schrift fir Handel, Schif’fahrt. und Verkehrswesen (I. Band, Rostock,
1872).

“A consideration of the three rivers—Weser, Elbe, and Oder—
makes clearly manifest a reduction in the quantity of water delivered
by them, and a silting up of the river-bed with sand. It has been
calculated that if the Elbe continue to diminish in the future at the
same rate at which it has been diminishing up to this time, it will soon
be impossible for heavily laden ships to pass by it. Nor is it otherwise
with the Oder ; in the very dry year 1858, there were only eleven days
in which the navigation of the Oder in Silesia could be carried on
with full force. The Weser delivers the smallest body of water of
the three. One principal reason for this is the destruction of forests
which has taken place on the heights which are found alongside of
the river, and which the Government have latterly taken steps to
prevent ; but still more than what has resulted from the destruction
of forests has been the consequence of the rectifications of the river-bed,
which it has become a general practice to carry out.

“ After weighing fully the collected observations on the water
level, and consequences deduced from them in the foregoing treatise,
I think no Hydrotechnik will venture to call in question the correct-
ness of the allegations advanced by the distinguished hydrographer
Dr Berghaus, in the year 1835, which allegations have been confirmed

STATEMENT BY HERR WEX. 193

and established by myself, that in the brooks, streams, and rivers in
central Europe, within the period of observations, extending over
about 140 years, high floods now appear oftener and attain a greater
height ; on the contrary, the lowest, and the mean levels of the
rivers are falling, and consequently the delivery of the water by these
streams and rivers is being continuously diminished to a very great
degree.”

There follows an expression of the views of the author on the
great practical importance of the fact brought to light. In the
second chapter he describes the reduction observed in the flow of
springs and in the quantity of water yielded by them, and after
citing numerous facts, illustrative of these points, he thus con-
cludes :—

“Tn regard to the diminishing of subterranean waters, we can
adduce the following evidence :—

“ As we have in the preceding chapter shown, from observations
on the water level continued through long series of years, that there
has been seen in later decades a lowering of the level of the lowest
and of the mean annual flows, while the high floods, consequent on
storms of rain, have become of more frequent occurrence—from which
it comes to pass that a greater quantity of water is thus carried away
at such times than formerly—it follows as a consequence that if the
quantity of the rainfall remains the same, the proportion of this
flowing away on the surface of the earth in such circumstances has
increased. On the other hand the proportion sinking below the
surface must be less; and from this it comes to pass that the
quantity of the subterranean water supply, the drainage and super-
ficial waters, and with them the springs which are fed by them must
have been reduced ; and the correctness of this conclusion can be
established by the following facts:

“From these long continued observations on river levels we have
further proved that on brooks, streams, and rivers in these later
times, the lowest and the mean levels, and also the quantity of water
delivered, have been being continuously reduced, and that to a marked
degree ; and that in the very months during which the water courses
have been fed almost exclusively from subterranean flows of water
and from springs the diminution of the water delivered has been
greatest. Whence it may with all justice be concluded that in these
later times the water supplies in subterranean reservoirs and in
the water bearing strata have decreased, and also that drainage

waters and the springs in a river basin in their collective contribu-
U

194 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

tions now furnish smaller water supplies to the feeding of the river
course than was the case at an earlier period.

“Dr H. Berghaus has in his work on ‘Hydrography’ which has
been cited, advanced on this point (p. 30) the following doctrines :

“Tn some parts of the world it has been remarked, the springs
have suffered a loss in the quantity of their water supplies. Thus it
is in France in what was formerly Poitou, and in the department of
the lower Charente, where there has been remarked a decided reduc-
tion of the springs since 1825.

“The phenomenon is attributable to the desiccation of the land,
the cutting of canals, trenches, &c, while Fleuriau of Bellevue has
alleged that the cause is to be found in a diminished rainfall.

“Tt can also be established by manifold evidence that of late years
many springs have dried up, and that in a great many others the
quantity of water yielded by them has been greatly reduced ; further
it is generally known that several solidly and skilfully constructed
aqueducts which erst while conveyed a rich supply of water have
become completely useless in consequence of a permanent deficiency
of water which has arisen, and that very many old wells known
amongst us as inexhaustible have become, since 1852, in consequence
of the lowering of the water level in the subterranean strata by
which they were fed, in some cases absolutely dry ; and in other
cases so impoverished in water supplies that the wells must be sunk
some fathoms deeper if they would be made permanent sources to
meet the demand.

“From amongst the numerous cases which have become known to
me, I shall adduce but a few specimens :

“Tt is generally known that the city of Rome, in its pristine glory,
with its public fountains and baths, and its several aqueducts, was
exceedingly richly provided with water ; some of these, from the dry-
ing up of the springs by which they were fed, have now run dry, and
others have lost a large share of their water supply—as, for example
the aqueduct aqua vergine (some 20,000 metres, or between 60 and 70
feet, long), which it is now in contemplation, at extraordinary expense,
to reconstruct.

“The springs and aqueducts which, at one time, provided for the
City of Constantinople a very abundant supply of water for drinking
and for use, have fallen off to a very considerable extent in their pro-
ductiveness, so that it has become necessary to seek out more, and
more remote, springs.

“The world-wide renowned fountains and water-works of Versailles

\

TREATISE BY HERR WEX. 195

were formerly so abundantly provided with water from the aqueducts
by which they were supplied that they could play almost the whole
day long ; whereas now, from the great diminution which has taken
place in the water coming to them, this must be allowed to accumu-
late for about twenty-three hours to allow the fountains and other
water-works to play a single hour.

‘So also with the numerous fountains and artificial cascades in
the Belvidere-Schwarzenberg and Lichtenstein-Gardens at Vienna, and
those in the palace garden at Schénbrunn, which were abundantly fed
by spring-water led to them, they stand now almost quite dry, as a
saddening monument of the dried up springs.

“The City of Vienna has, besides, about 10,000 sunk wells, and in
addition to these nineteen different aqueducts, with which the springs
and drainage waters in the environs of Vienna are intercepted, col-
lected, and brought into the city. After the water in the sunk wells
had not only diminished, but, in consequence of the filtration from
the canals, had become deteriorated—and also the quantity of water
brought in at one time by the aqueducts had become very much
reduced ; there was constructed, in the year 1836, the Emperor
Ferdinand’s aqueduct, by means of which were brought into the
City of Vienna, from the Vienna Donaucanale, near Nussdorf, by long
and deep suction pipes, an aggregate of about 100,000 ecmers of water
daily ; and now, after this aqueduct also, through a lowering in the
water-level in the Vienna Donavcanale, and partly through the
coincidence with this of a sliming up of the suction pipes, has be-
come insufficient and precarious, the commune of Vienna, after year-
long negociations, has seen itself under the necessity to seek to
obtain the two million emers per day, required by the city for
drinking and necessary uses, from the high springs of the Schneeberg
(Kaiserbrunnen and Stixensteinerquelle), by means of a canal
about twelve German miles long,* which aqueduct will absorb a
capital of about sixteen million of Guldens [or £1,600,000
sterling ].”

Herr Wex goes on to say :—“ J consider that I have satisfactorily
proved, by the foregoing observations, deductions, and examples, that
in recent times the supply of water in subterranean reservoirs, and in
the water-bearing strata of the earth, is being diminished ; further,
that many of the drains and springs of to-day have become some
quite dry, and others yield a comparatively small supply of water ;

* A German mile is equal to about 43 English miles,

196 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

and finally, that through these changes the lowest and the mean
water-levels in brooks, streams, and rivers are being continuously
lowered, and the quantities of water delivered by them continuously
diminished. ‘

“Tf this continuous diminution, which has been going on for the
last 140 years, is to go on continuously still, then will these results
and changes on the surface of the earth entail on coming generations
evils, and evils of incalculable extent and magnitude. Through the
lowering of the level, and reduction of the rivers and of the sub-
terranean drainage, and also through the alternation of very wet and
very dry years,—such as is shown, by the diagram referred to, to be
prevailing,—will the fertility and productiveness of the iand be
reduced in no inconsiderable degree, and not a few lands now covered
with luxuriant vegetation will become veritable deserts, cheerless and
desolate,

“After the drying up of many brooks and streams, and after the
conversion of streains and rivers into torrents, in consequence of these
changes men would have to go for their water supplies for drinking
and for domestic use, and for other purposes, either to the deeper-
lying water-bearing strata of the earth, or to a greater distance from
their dwelling ; whereby the cost of the water consumed would be
increased, while many industrial establishments and manufactories
would be deprived altogether of the supply of water indispensably
necessary; to their operations, and would have either to adopt expen-
sive means of providing a substitute for what has been lost, or remove
to some. remote district where brooks and rivers have not as yet been
deprived of their water supplies.

“Finally, by the continuous diminution of water in streams and
rivers, the former would become quite dry through the greater part
of the year, and the latter would become unnavigable.

“ As, through the consideration of what has been advanced, it may
thus be seen that, through the continuous diminution and lowering
of the flowing water on the surface of the earth, there is imperilled—
and that to a great extent—not only the prosperity and the health,
but also the existence of future generations, it igs desirable that
numerous students of physical science should be incited to further
research into the cause of these intimately connected phenomena, and
then to devise measures to avert the impending calamity, in so far as
it may be within the scope of man’s power to do so.”

The author adds :—“T have given myself also to an attempt to
a solution of this difficult problem, and I give the results of my

TREATISE BY HERR WEX. 197

researches in this study in the two following chapters, in the hope
that distinguished collaborateurs in the same calling and men of
scientific attainments may prosecute further the researches I have
been privileged to commence, and that the results of their study
may bring great good to generations yet unborn.”

The chapter which follows is occupied with a discussion of the
cause or occasion of a diminution having taken place in the quantity
of water flowing in streams and rivers, which he thus concludes :—

“When we fully realise what is implied in the opinions expressed
by men of science, and practical men expert in such matters, in
various countries and in very different parts of the world, after long
experience, observation, and research, we find that forests affect to a
very great extent the quantities of water coming from springs and
flowing in rivers ; that they affect the climate ; and that they havea
great effect upon the fertility of the lands in which they exist ; and
that thus :—

“1. The deposit of rain from the atmosphere is greatly increased
by the amount of woods in a district, in as much as mists and clouds
passing along the surface, striking upon the forests, have the moisture
of which they are formed condensed and precipitated as rain.
Further, the temperature within the woods is cooler by day, and, on
the contrary, warmer by night than it is in the open fields and
meadows; and by reason of this, there is a continual circulation of
air in the vicinity of forests whereby mists and clouds are precipitated
and led to discharge themselves of their contents. This happens not
through the forests in and for themselves, nor as a consequence of
the forests of themselves, but through the difference between the
forests and the open fields; and on this depends the abundance of
the rain. It is also very manifest.that the forests exercise an
attractive influence upon the clouds, by their attracting from them
electricity with which they are charged, and with this the water of
which they are composed, increasing thereby the rainfall. It is also
an ascertained fact that a great part of the water precipitated as rain
remains on the leaves of the trees, one part of which falls to the
ground, but another portion of which evaporates into the atmosphere,
and is again precipitated as fog, mist, dew, or rain,—whence it comes
to pass that rain water is kept longer within forest lands, and may be
precipitated oftener than once, whereby the rainfall is increased.

“9. Through the abundance of forests will the copiousness of the
subterranean drainage flow, and springs be increased, while the rain
-water retained by the foliage of the forest trees, falling slowly to the

198 EFFECTS OF FQRESTS ON SPRINGS AND RIVERS.

earth, is kept by the spongy character of the ground in woods from
flowing quickly away, and is in part absorbed, or is left to permeate
the mineral strata, which is considerably facilitated by the numerous
spreading roots of the trees penetrating cracks, fissures, and canals in
the superficial ground, by which means the rain water reaches a
greater depth, and this in a much greater quantity in forest ground
than in the open field. Further, by numerous experiments it has
been established that the evaporation of the humidity in the open
country is at the least from four to five times as great as it is in wood-
lands ; from all which it appears that the moisture absorbed in forests
is not so readily evaporated, but is retained and directed to the feed-
ing of drainages, springs, and brooklets.

“3. If forests be uprooted, more especially in mountainous regions,
or even in somewhat hilly country, the rain drops, falling upon the
exposed ground with some force, tear it up, and then flowing down the
declivity with considerable rapidity carry with them earth and stones
towards the brooks and streams and rivers, by which these water
courses are suddenly filled up, and experience much higher and more
devastating overflowings, and inundations, than was the case while
the woods stood, as is explicitly testified by the aforementioned
tabulated observations of river levels.

“4, Through the extensive clearing away of forests the heat of the
summer months and the desiccation of the ground becomes increased,
then, as a consequence of this, the duration of droughts is prolonged,
and from this there follows naturally a diminished productiveness of
the land,

“These most disastrous effects of the clearing away of forest show
themselves in a very marked degree in these countries, once blessed
with a luxuriant vegetation, Palestine, Persia, Greece, Sicily, Spain,
and the Canary Islands.”

It is stated also that “a great cause of the diminution of water
supply from springs and subterranean reservoirs in Europe has been
the draining of lakelets and ponds, and the draining of bogs and
marshes, which has taken place, in various parts, of late years.” And
a third cause of the diminution of water in springs and rivers at
present going on is to be sought for in the greatly extended, and
still from year to year extending, operations to bring under culti-
vation, to cultivate, and to improve the land.” Of both of which
statements illustrations are given, with illustrations of the effect of
the latter when carried on on hill sides, to increase the violence and
the magnitude of torrents and devastating inundations,

REPORT BY ACADEMY OF SCIENCE OF VIENNA, 199

There follows a chapter devoted to the consideration of measures
proposed with a view, on the one hand, to prevent continued and ever
extending devastation occasioned by inundations ; and on the other
to arrest and prevent the continuous diminution of water in springs
and in rivers in their lowest state, and in their mean delivery, But
it is the facts of the case established in regard to the effects of forests
on rivers and springs with which alone we have at present to do.

The paper was subsequently published, and it excited much interest.
By several learned Societies Commissioners were appointed to report
upon it. Amongst others this was done by the Royal and Imperial
Academy of Science of Vienna, and the Imperial Academy of Science
of St Petersburg. It was also favourably considered and approved
by the Society of Engineers and Architects of Vienna, the Geogra-
phical Society of Vienna, the Forest Academy of Mariabrun, by
several Polytechnic Schools, and by many men of science.

In regard to the views of Herr Wex relative to the phenomena
observed, the Commission appointed by the Academy of Science of
Vienna reported :—

“Tn view of the facts brought forward by the author, the Commission
has come to the conclusion that the diminution seen within the last
century, in the medium and lower heights of the rwers made the subject
of observation, is attributable to a diminution in the annual delivery of
these rivers.

“The author finds that the diminution of the quantity of water in
the river is attributable to a diminution in the quantity of water
yielded by springs, of which he finds additional indications in the
diminution of water in streamlets, aqueducts, and wells.

“ The Commissioners agree with the author in this view, considering
the low depth of water in the rivers to be justly attributable to the
quantity of water flowing throughout the whole district constituting
the basin of the river having been reduced.

“ The causes of this general diminution in the flow of water may be
found—1. In a diminution of the annual rainfall, connected with the
extension of agriculture occasioned by the clearing away of forests ;
2. In an increased evaporation from the surface of the soil, consequent
on the change of culture spoken of ; 3. In such a change in the mode
of flow that the rainfall, instead of being, for the most part, retained
for a time and percolating through the gravel, flows away quickly,
producing brief periods of high floods, alternating with protracted
periods of drought.”

200 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

After reporting their opinion in regard to the effects of forests on
the distribution of the rainfall, the Commissioners go on to say :—
“The copious flow of springs, and the abundance of water in rivers,
however, does not naturally depend solely on the quantity of rain
falling in the course of the year; for, on the one hand, a very con-
siderable quantity of the rainfall is returned by evaporation to the
atmosphere ; on the other hand, the nature of the soil determines, in
a great measure, the quantity of the rainfall which sinks into it,
forming subterranean reservoirs from which springs are fed.

“Tn regard to both of these phenomena, forests exercise an influence
which can hardly be estimated too highly.

“Tt is proved by direct observation in France, and in the forest
stations for meteorological observations in Bavaria, that the variations
in the temperature of the air in the forests are less than in the open
country. Especially does this hold good in the hours of the day and
in the seasons of the year in which the greatest heat prevails, the
degree of temperature being at these times considerably lower than
in. the open country, and, in accordance with this the temperature of
the soil in the forest, is considerably below that of the land unshaded
by trees.

“Tn like manner the degree of humidity in the forest differs from
that in the open country ; this being, at all seasons of the year,
greater within the forest than it is outside.*

“Tn view of these facts, we need not be surprised that the evapora-
tion in the forest is found to be much less than it is in the open
field ;t and all the more so that, besides the relation of evaporation
to temperature, the strength of the wind or movement of the air
constitutes an essential element in the operation, and there is pro-
portionally much less movement of the air in the forest.

“Tn proportion as it is important to obtain a correct determination
of the quantity of the rainfall which is lost by evaporation go is it
difficult to do so.

“ As the means of making observations on the amount of evapora-
tion from the surface of plants and the surface of the ground are
different,—besides which, the comparison between the quantity of
the rainfall and that of the evaporation is. prejudiced by difference in

* According to Ebermayer, the difference in the four seasons, from spring onwards,
amounts to 5°7, 9°3, 5"2, and 5:2 per cent.
+ According to Ebermayer, the evaporation from an exposed suface of water in the
forest was about 64 per cent. less than from one outside the forest.
—ZLeitschrift fir Meteorologie, viii. 253.

REPORT BY ACADEMY OF SCIENCE OF VIENNA. 201

the exposure of the instruments, they being in some places exposed
to the sunshine and the rain, in others protected from these, by
difference in the sizes of the atmometers, and by difference in the
materials of which these are made,—it is not impossible, from these
causes, that an atmometer of small size, made of metal, and set in
the sunshine, may give an annual evaporation which exceeds by far
say two or three times, the amount of the rainfall.

“Tn consequence of the difficulty of determining by direct observa-
tion on evaporation the evaporation from the ground, and thereby
determining the quantity of the rainfall available for feeding springs
and streams, some have sought to determine this directly in part
by comparison between the quantity of water delivered by a river
in the course of the year, and the rainfall on the whole valley drained
by it; or, otherwise, between the quantity of water percolating through
a given section and the rainfall over a given range,

“Tf now there be also in a wood a considerable portion of the
rainfall kept by the twigs and leaves from immediately reaching the
ground, the difference between that rainfall and the evaporation
(amounting, according to Ebermayer, to 72 per cent., Zeitschrift fur
Mat. viti. 274) will also be retained longer in the forest and get time
to permeate and feed the springs.

“The remainder of what has not been dispersed by evaporation
either penetrates the ground or flows away over the surface.

“In the former case it seems principally to feed the springs; in the
latter case it is carried directly to the water-courses, and after a brief
time produces a more or less considerable flooding of these.

“It is generally acknowledged that the forest, through the vegeta-
tion of lichens, mosses, &c., peculiar to it, is pre-eminently fitted to
absorb the rain, to store up the same, and only gradually—little by
little—to yield it again.

“In view of this, the aforementioned investigations in regard to the
quantity of water which sinks into the ground to certain depths is
very instructive, as they give on the one hand the relative effect of
different kinds of soil on the absorption of the different plants with
which they are covered, and on the other the proportion of the
moisture absorbed by the sod in the course of the year. It appears,
according to the latest of these, that the absorption of the forest is
especially manifested in the warm season of the year.*

‘In regard to that portion of the rainfall which does not penetrate

*® According to Ebermayer, in the summer the following per centages of the rain-
fall was found at the depth of one metre :—
x

202 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

the ground, but flows away over the surface, and to which popularly
is ascribed the swelling of floods, there exists no difference of opinion
in regard to the influence of forests. On all hands it is agreed that
with the removal of forests the tributaries to water-courses rush more
rapidly to these ; and that in mountain regions, on steep precipices,
from which woods have been cleared, the fruitful soil is swept away,
and water-courses are converted into torrents,

“Jn the cutting down of forests which present no longer, as
previously, a hindrance to the flowing off of the rain-water by their
manifold united roots, by lichens and by mosses, may be seen gene-
rally the cause of the more frequent and extensive, and ever more
threatening inundations.

“‘ With the facts before them of the diminution of the water in
the rivers, which diminution is connected with a diminution in
the copiousness of springs, the Commission find the “cause of
these phenomena to lie—1. In the continued extensive destruction
of forests, the beneficial effects of which consist in an increased
humidity of the air, a reduction in the extremes of temperature, a
diminution of evaporation, and the securing a more regular distribu-
tion of the rainfall ; while the injurious effects of the destruction of
them is seen in an alternation of periods of drought at one time, with
wasting floods at another.

“2. In the drying up of the lakes, marshes, and bogs, which
increased the humidity of the atmosphere, diminished evaporation
elsewhere, kept down excessive heat, and finally escaped through
rents in the ground, increased directly the formation of springs.

“3, In the breaking up and cultivation of extensive tracts of
country, for the watering of which considerable quantities of water
are required.

“4, In the increase of population and of domestic animals, although
the diminution of the water occasioned by these causes can amount to
what must be relatively a small portion of the whole.

With litter. Without Utter on the ground.

In open ground,..........19.. cece Uk 1
Int the forestyoskscurnaiOPis weraaiant2 6b 86
Difference... ........88.....500006.53 SL 26

Earlier experiments come to us from Maurice in Geneva, and Gasparin in Orange.
A later one, on a great scale—undertaken by E. Risler at Caléve, by Nyon (Canton
Wallis), who sowed different experimental fields, of 12°300 square metres, with corn,
clover, etc.,—determined the infiltration at 0°35 metres deep, and showed the
comparative humidity of the soil with that of the superficial soil under different
conditions of culture,—Annuatre Meteorologique de l Observatoire de Paris, pour 1873,
p- 27%

REPORT BY ACADEMY OF SCIENCE OF ST PETERSBURG. 203

“5, And, lastly, it appears to this Commission that the view ex-
pressed M. 8. Saeman, * according to which, in the interior of the
earth, water is continually required for the formation of minerals in
which it is chemically combined, and from which mineral operation a
diminution of water must follow, deserves consideration.”

At the instance of the Academy of Science of Vienna, the paper by
Herr Wex was brought under the attention of the Imperial Academy
of Science in St Petersburg, by which also a Commission was ap-
pointed to consider it, to supply information in regard to similar
phenomena in Russia, and to report. In a report submitted by the
Commission to a meeting of the Academy held on the 27th January
1876, amongst others things it is stated, in reference to what had
been said by the author in regard to the effect of the destruction of
forests on the humidity of different countries :—“To these examples
we may add the districts in Southern Russia, where it is well-known
that large forests existed about 150 or 200 years ago in the very
spots invaded by the steppes, the higher portions of which are
perfectly arid, so that the inhabitants, to prevent their dying of
thirst, are obliged to live on the banks of tiny streamlets in the
lowest valleys. We may also make mention here of the Volga and
Dnieper, where the destruction of the forests, from south to north,
has made and is making such progress that these rivers, so indispen-
sable to the commercial prosperity of Russia in the middle and in the
lower portions of their course, now flow through regions which are
quite cleared of forests. There the floods reach a higher level than
they did formerly. And who has not heard serious complaints,
annually repeated, with regard to the modifications of river-courses
caused by these floods by changing the direction of the navigable
channel and hollowing out new beds for the streams? And who does
not know that gorges, deprived of water in winter and dry in summer,
during spring, in consequence of the rapid melting of the snow on the
naked steppes, become, after heavy rains, impetuous torrents, which
undermine their banks and carry away large portions of valuable soil ?
Furthermore, all the affluents of these rivers bring down masses of
detritus, which every year contribute to the formation of new river
beds. We may state it as our conviction that the injury caused at
present by the Volga, the Don, and the Dnieper, would be much

* Sur U unité des phénoménes geologiques dans le systéme du soleil. Bull, de la Société
Géologique de France. 2 Serie, t. xviii. p. 322... 1861,

204 ACTION OF FORESTS ON SPRINGS AND RIVERS.

less serious if the land along the banks had been preserved from
deboisement.”

Thus do abound observations which go to establish it as a fact
that, whatever may be the effect of trees on the rainfall, there is an
effect produced by them on the humidity and moisture deposited
from the atmosphere which is such as to affect the existence of
springs, and the flow of rivers. It is the fact alone, and not the
way in which it has been brought about, with which we have here to
do, and the fact seems to be established beyond question by the ob-
servations which have been brought forward.

It is not to be expected that the treatise by Herr Wex should at
onee command universal unhesitating acceptance of all the observa-
tions cited, and reasonings and deductions founded thereon. Since it
was published (in 1873) Herr Wex has collected a great many new
and interesting observations of facts and experiments in relation to
the diminution of water in lands under culture, and in relation to the
influence of the extensive destruction of forests; and while these
sheets, are passing through the press he is carrying through the press
a second treatise on the subject, in which he meets all doubts and
conflicting observations known to him to have been advanced against
the statement made by him in regard to the diminution of water
in. springs and rivers.

Reference is made by the Commissioners appointed by the Academy
of Science of Vienna to report on the treatise by Herr Wex, to
observations made by Dr Ernst Ebermayer, professor in the Central-
‘Forster Lehanstalt, School of Forest Science, Aschaffenburg. For
some seven or eight years he had been engaged in the study of
observations on the meteorological effects of forests, made by himself,
or under his direction, and corresponding observations made. by
others. Results have been published from time to time in scientific
journals. And the more important were embodied in a volume
published under the title of Die physikalischen Einwirkungen des
Waldes auf Luft und Boden und Seine klimatologische und hygienische
Bedeutung, begriindet durch die Beobachtungen den forstlich-meteorologi-
schen stattonen in Kénigreich Bayern.

The following is a resumé of facts noted by him, embodied in a
report on the Cultivation of Timber and the Preservation of Forests,
submitted to the Congress of the United States in 1874. It is given
as taken from a report made by H. J. Wiseman, Consul of United
States at Sonneberg, to the Department of State, November 1873.

OBSERVATIONS BY EBERMAYER. 205

“That the forests of a country are not only of great importance
in supplying many necessary productions of ordinary life, but also
serve still higher purposes in the domestic economy of nature—to
the extent that within certain limits the arability, the inhabitability,
and beauty of the land depend upon an appropriate area of woods—
has often been declared. Indeed, this fact is now generally ac-
knowledged, at least by all educated persons, and it forms the basis of
a series of legislative measures, which have for their object the pro-
tection of the forests from destruction and misuse on the part of the
ignorant for selfish purposes. But, hitherto, the exact relations
between the woods and the fields have not been fixed by the certainty
of figures. There has always been a lack of scientific accuracy in
connection with a matter of so great importance, simply because no
systematic method has been carried out by which, from actual experi-
ment, these relations could be surely determined. The discussions,
therefore, which for years past have taken place on this subject, the
conflicting opinions which have been advanced in literature and in
scientific bodies, have been only valuable to the extent that they
served to keep alive interest in a vital question. No argument which
has been made has been deemed conclusive, because there has always
been a failure to base theories upon the results of scientific researches.

“To obtain this scientific foundation upon which to prosecute
future investigations, the kingdom of Bavaria has taken the initiative.
Since 1867, under the organization of Dr Ebermayer, professor at the
Forest Academy at Aschaffenburg, a series of meteorological observ-
ations and experiments have been made at several stations within the
kingdom, which were selected as being best adapted for the object in
view ; and most painstaking and minute investigations have been
pursued by competent and experienced observers. These interesting
and very important results, which have been obtained by these six
years of close inquiry, have just been made public.

“The observations have been made simultaneously at a station
within the forest, and at a station corresponding thereto in all
respects in the open country. The results which have been reached
are as follows :

“1, That the average annual temperature of the atmosphere in the
woods is somewhat below that of correspondingly situated areas
which are unwooded. (About 1} to 143 of a degree Fahrenheit.)

“2. That the average annual temperature at the crowns of the
trees is about 14° above that which is found in dense woods at a
distance of 5 feet. above the surface of the ground; while in the

206 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

former case the average temperature is 45° below that of unwooded
lands at a distance of 5 feet above the surface of the ground.

“ 3, That the average temperature of the spring within the forest
was 2°95° below that of unwooded land. This difference was less
apparent among shade-trees, than where pines were the growth.

“4, That the average temperature of summer in the day-time, in
thick woods, is 3°78° below that of unwooded land.

“5. That the temperature of the atmosphere within the woods, in
the summer season, increased 3°94° from the ground to the tops of
the trees.

“6, That the average temperature of autumn within the woods
was scarcely 14 below that of the open land ; and

“7, That in winter this difference in temperature almost entirely
disappeared.

“ These briefly mentioned differences between the temperature of
the atmosphere within the forests and that of unwooded lands, affect
the constant current of air in the day-time. For instance, the stream
of air flows from the surface of the ground within the forests toward
the periphery of the woods, and thence spreads over the open fields.
It afterward passes back again to the crowns of the trees, and by
coming in contact with the leaves which, during the day, are colder
than the atmosphere, the latter itself grows cooler and heavier, and so
gradually descends from the tops of the trees to the surface of the
ground.

“ At night the conditions are entirely different, The thermometer
now is higher in the woods than in the open lands. The Bavarian
observations for the month of July show that, while at midday the
temperature within the forest is 801° below that of the unwooded
land, at night it is 4°39 higher, (18 and 29 per cent.) ; in August,
during the afternoon, 7:13° lower, and at night 3°71 higher, (16 and
22 percent.) During the night, therefore, the colder and denser air
of the unwooded land passes into the forest, displaces the warmer air,
which rises and is cooled by contact with the leaves, and then
radiates.

“The maximum and minimum temperature of the open lands is
never reached in the forest. The [mean ?] atmospheric temperature
of the woods always remains several degrees lower.

“ From these data, therefore, it is evident that the thermal effects
of woodland are of great moment, and that climatic alterations must
result from deforestation on a large scale ; that these climatic changes
will consist, as a general thing, in increasing the annual temperature,

OBSERVATIONS BY EBERMAYER. 207

and in sharpening still more the extremes of heat and cold. But
these thermal effects are not alone confined to the atmosphere, but
have, as well, a particular influence upon the soil. The Bavarian
investigations have clearly demonstrated that the average annual
temperatures at various depths beneath the surface of the ground are
nearly equal; that the average temperature diminishes downward
quite slowly and by small degrees, (at a depth of 4 feet never more
than 1:12°,) but that the average annual temperature of woodland
soil, at all depths, is below that of unwooded land, on an average of
3°37°.

“Further, it has been demonstrated that the temperature of the
soil in the spring and summer is highest at the surface and diminishes
downward. In spring the difference between the warmth of the soil
at the surface and at a depth of 4 feet amounts within the forest to
562°. In summer these differences show 7°50° both in the wood and
in the open land. But the soil of the woods in summer is 75.0°
colder than that of the unwooded land, and the greatest difference
has been found at a depth of 2 feet.

“In contrast to spring and summer, the temperature of the soil
increases in autumn and winter, from the surface to a depth of 4 feet
beneath. In autumn this advance of temperature, according to the
Bavarian observations, amounted to 4°50° outside of the forest and to
3'49° within the forest ; in winter, relatively 4:°21° outside and 4-41°
inside the woods. Wooded and unwooded lands have, therefore, in
winter, to the depth of 4 feet, very nearly the same temperature ; the
result of which is that the influence of the woods upon the temperature
of the soil is not less than that which they exert upon the tempera-
ture of the atmosphere.*

* It cannot be supposed that trees have any vital process by which a degree of heat
is maintained above the medium in which they grow. Their trunks, branches, and
leaves are heated and cooled in the same manner as inorganic bodics under like condi-
tions of exposure. But wherever evaporation or condensation is taking place, the
same change occurs in them as elsewhere, and the universal law of thermal result ap-
plies. ‘‘ The trunks of trees,” says M. Becquerel, “‘ only acquire their maximum tem-
perature after sunset. In summer it occurs as late as 9 p.m,, while in the air the max-
imum temperature occurs from 2 to 3 p.m. Changes of temperature take place very
slowly in the tree, but in the air they are rapid. When the leaves are cooled by noc-
turnal radiation they recover from the trunk by radiation the heat they have lost.
The temperature of the air above the trees which have been heated by solar radiation,
acts on the temperature of the air, and prevents it falling as low as it would otherwise
have done.”"— yptes Rendus, Sé de VAcad. des Sciences, May 22, 1855, tome ix,
p- 1049 ; also Jour, of Scottish Meteorological Soc., (new ser.,) i, 234, [I give the note
as given appended to the text, but I do not homologate what is said in the opening
sentence.— J. C. B.]

208 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

“Far more important, however, than the thermal effects upon the
soil and the atmosphere are the influences inherent to the forests of a
country which affect the humidity of the soil and air, the quantity of
the rainfall, and the abundance of the springs. In relation to these
points the investigations of Ebermayer have produced very valuable
results.

“In the first place, it has been discovered that the influence of
forest-lands upon the absolute contents of moisture in the atmosphere
—the evaporation pressure—cannot be proved, in spite of the fact
that the air of the woods is always more humid, relatively, than the
air of the open grounds. This is easily explained by the greater cool-
ness of the former. The higher a place is situated, the more marked
was the relative difference observed in Bavaria between the humidity
of the wooded and unwooded country. Ebermayer assumes that the
augmentation of aqueous descents, caused by a larger area of wood-
land, noticed at many places, is to be attributed merely to the
increase of the relative moisture within the forests.

“Tn close connection with the relative humidity of the atmosphere
of wooded and unwooded lands stands the quantity of water which
has been discovered to evaporate at given points, during a given
interval of time, at a certain temperature, and at a certain pressure
of the atmosphere, from an open surface of water.

“The Bavarian observations have proved that in an average of one
year less than 64 per cent. of water evaporates within the forest than
outside of it. The fact is more remarkable, because the proportion of
evaporation was nearly the same at all seasons of the year, although
the temperature of the atmosphere of the forests and the open lands
is so different in the winter from what it isin summer. This forces
us to the conclusion that the movement of the air, which is very much
less within the woods than outside of them, plays a far more
important part in relation to evaporation than has hitherto been
supposed.

“ But for the abundance of water and the forming of springs in any
country, the evaporation from rivers, ponds, and lakes is not so impor-
tant, by any means, as the evaporation of the water of the soil.

“The amount of evaporation from one square foot (Parisian
measurement) of an open surface show, in Parisian cubic inches, as
follows :—

OBSERVATIONS BY EBERMAYER. 209

April, 1869...0.ccccccescsescsses sessesseeees 399 2003
April, 1870... ohare ees 373 226
DOL Ys U8 69 ese versa vies vatecvevevacavcocvies 407 151
July, 1870....... aes. wae 394 151
October, (1868 vsvzesssvevencdeevensxmaaeenedes 158 73
October, 1869 is csssersavsasrecne sseocecensess 194 50

“‘ There evaporated, therefore, from the water contained in the soil
of wood-lands, as well as from open water-surfaces, far less than
evaporated from the water of the soil of the open grounds—about 40
to 50 per cent. in April, 60 per cent. in July, and 70 per cent. in
October—and this decrease reaches its maximum in the hottest
season. Still more glaring does this difference of exhalation appear
when wood-soil, covered with leaves and pine-needles, is compared
with wood-soil which is free of litter of this description.

“Under the first-mentioned conditions the evaporation from ‘one
square foot (Parisian measurement) amounted, in Paris cubic inches,
to the following :—

wood-soil, covered with litter
April, 1869........cscscesteseseeeeerentene 2003 78
April, 1870.. 226 102
July, 1869.... 151 55
July, 1870....... 151 55
October, 1869... 50 25

“In wood-soil covered by litter, when compared with the bare soil
of the fields, the difference in the amount of evaporation per square
foot (Parisian measurement) is shown, in cubic inches, by the
following figures :—

From bare soil of = From litter-covered

the field. forest soil.
Bepprtl, SEED ovens era ceoesony So setae 399 78
April, 1870........... sb adiestehnvsents 378 102
July, 1869... 407 55
Taaly,:1870vcccisecssnctecseuse sccstasteenass 394 5D
October, 1869......ccccccsecseeceececeseees 194 25

“ From these figures, therefore, it is perfectly apparent how impor-
tant are the influences of the woods of a country upon the abundance
of its springs and the mellowness of its soil ; and in this connection
how essential are wood-lands which are covered with the litter of
fallen leaves, the uprooting of which effects a direct injury to
cultivation.

x

710 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

“Bus it must also be borne in mind that extensive areas of wood-
land materially increase the quantity of the rain. At Rohrbrunn
(Spessart) 62 per cent. more rain falls than at Aschaffenburg, in its
immediate neighbourhood, on an average of the years 1867 to 1871.
Certainly one-quarter of the gross quantity of the rainfall was caught
by the tree-tops and conveyed, by evaporation, again to the atmos-
phere, (average of the years 1868 to 1871 at all the meteorological
stations.) But of the remaining three quarters of the aggregate rain
which fell upon the earth, there evaporated during the same interval
six times less'from the soil of the forest than from that of the open
country ; and, therefore, a much greater quantity of water is absorbed
by the forest, where the leaf-litter is retained, penetrating to the
deeper strata of the earth, than is held by the soil of the fields.
This fact is of the utmost importance in its relation to the formation
of springs to the supply of water to the rivers, and to all the
numerous interests of agriculture which stand in so close connection
with it.

“ The investigations of Ebermayer have also led to very important
conclusions in regard to the amount of ozone in the atmosphere.

“The air contains most ozone in situations of great altitude,
where there is much humidity. In dense woods, however, the
amount of ozone in the atmosphere is somewhat less than in the
directly adjoining open land. The most healthy dwelling-places,
therefore, are not in the midst of the forests, but at their borders.

“The proportion of ozone, on an average, at the six meteorological
stations in Bavaria, on the borders of the forest, relatively to that
contained in the atmosphere at Aschaffenburg and Zwickau, was as
follows :

In spring, as 8-20 : 6-80 : 3:20
In summer, as 7°70 : 3°20 : 3°10
In autumn, as 8:00 : 5°40 : 2:20
In winter, as 8:40 : 6°00 : 1:80

“These few data satisfactorily demonstrate the general importance
to which these forest meteorological stations may lay claim. A con-
siderable increase of the number of these observations may soon be
expected.

“To the six stations now existing in Bavaria will shortly be added
ten in Prussia, one in Mecklenburg-Schwerin, and three in Alsace-
Lorraine. In Bohemia, at Promenhoff, one observatory is already in
operation ; also three in Switzerland, Canton-Berne. The erection of
a station at Valambrosa, near Florence, in Italy, is also projected.”

OBSERVATIONS BY EBERMAYER. 211

About the time that Herr Wex’s paper was published in 1873,
there was held in Vienna an International Congress of distinguished
students of forest science. By them was resolved to send to the
different governments of the civilized world the following expression
of their views :

“1. We recognize the fact that, in order to effectually check the
continually increasing devastation of forests which is being carried on,
international agreements are needed, especially in relation to the
preservation and proper cultivation (for the end in view) of those
forests lying at the sources and along courses of the great rivers,
since it is known that through the reckless destruction of them,
there results a great decrease of the volume of water, causing detri-
ment to trade and commerce, the filling up the river’s bed with
sand, caving in of the banks, and inundations of agricultural lands
along the river course.

“2. We further recognize it to be the mutual duty of all civilized
nations to preserve and to cultivate all such forests as are of vital im-
portance to the well-being—agricultural and otherwise—of the whole
land, such asthose on sandy coasts, on the sides and crowns, as well as
on the steep declivities of mountains, and on the sea-coasts and other
exposed places, and that international principles should be laid down,
to which the owners of such protecting or “‘ guardian forests” should
submit in order to preserve the land from damage.

“ 3. We recognize further that it is the case that we have not at
present a sufficient knowledge of the evils (disturbances in nature)
which are caused by the devastation of the forests, and therefore
that the efforts of legislators should be directed to causing exact
data to be gathered relating thereto.”

It has been noticed as a singular coincidence, that, at nearly the
same time, the American Association for the Advancement of Science
had under discussion measures tending to similar results, although
not expressly designing to extend its recommendations beyond the
limits of the United States, except in the way of correspondence with
other associations having similar objects in view. It is not supposed
that either of these bodies derived their suggestions from the other,
although the proceedings at Portland antedate those at Vienna only
about three weeks in time.

The coincidence, however, shows the wide and general prevalence
of a realizing belief that the time for action has now come, and that it
is the duty of all Governments to look well to the future, and take

212 EFFECTS OF FORESTS ON SPRINGS AND RIVERS.

early and effectual measures to provide against the injuries that might
soon follow a further neglect of interests in this regard.

Szor. [V.—Immediate Action of Trees in Arresting the Flow and
Escape of Rainfall.

While it is true that the rainfall is only the precipitation from the
air of a quantity of moisture which it could no longer hold in solution,
it is no less true that thus often a much larger supply of moisture is
brought to a locality than it would have obtained in the same
time, or in a much longer time, either by deposit of dew, or by the
attraction of moisture from the atmosphere by any of the constituents
of the soil; and we have now to consider the immediate effect of
trees upon it when thus precipitated. Some of these have been
adverted to in documents which have been quoted; but they require
more detailed consideration.

The testimony which goes to show that the destruction of forests
has occasioned the drying up of springs, and that the replanting of
woods has been followed by their re-appearance, seems to be incon-
trovertible ; but it has been questioned whether the views which
have been advanced and have been generally received in regard to
some of the phenomena connected therewith be correct.

Marshal Vaillant, whose experiments on the emission of moisture
from the leaves of trees have been cited in a preceding chapter,
remarks :—“In the report read by Monsieur Becquerel, at the
Academy of Science, it is asserted that springs generally have their rise
in mountains, It is true, and according to nature, that the causes
which formed the mountains have at the same time broken up the
impermeable strata in which are stored the water which creates and
supplies the springs. That forests are more usually formed on
mountain declinities than in the plains is generally true, and this is a
simple consequence of the superior fertility of the plains and valleys,
and of the greater trouble which the avriculturist, would have in
cultivating such difficult localities where there are often not even
forest tracks ; but to conclude from this that there is a necessary
and intimate relation between the existence of forests and of springs
is perhaps a rather far-fetched conclusion ; and we think it would
be well to examine what the conclusion is really worth.

“The same report states that, ‘the roots of the trees by dividing
the soil make it more permeable and facilitate infiltration.’

“‘ May we be permitted to make some observations on this point.

STATEMENT BY MARSHAL VAILLANT. 213

Usually there is no ground harder or less permeable than that
formed close to the trunks of trees ; if required we can bring forward,
as a proof, the long and deep trenches which have lately been opened
on some of the Boulevards of the capital, the substitution of rich
vegetable mould for the exhausted and, as it were, petrified soil, and
finally, the drainage works intended to convey air and moisture to the
trees on the Boulevards. All these sufficiently prove that these roots
would suffer in the soil in which they are condemned to grow, and they
are powerless as regards the penetration of water or rain, as well as in
imparting the least measure of permeability to the soil which stifles them.

“ Monsieur Becquerel, in support of the opinion that forests are
favourable to the maintenance of springs, cites two facts the impor-
tance of which we do not deny, but which would require a more
careful study before being considered incontestable. We allude to
the Scamander, which M. de Chouseul-Gouffier found to have dis-
appeared, and the invasion by the lake of Tacariqua of a large tract
of land formerly under cultivation. Is it quite certain that the
source of the Scamander has dried up, simply in consequence of the
destruction of the cedars on Mount Ida? May not the reservoir
which supplies this spring have been disturbed by some subterranean
convulsion? Have any observations been made regarding the other
springs on MountIda? And as to the lake of Tacariqua may not the
loose soil of such localities so often disturbed by volcanic eruptions
have first sunk and then risen, so as to cause in the first place the
water to retreat from, and in the second to invade, the shores of the
lake? Does not the entire globe, even in its most stable portions,
continually present such phenomena? On the western shore of
Schleswig and Holstein, in the strata of the ground there are found
alternate layers of peat, formed by fresh water, and marine deposits,
which sufficiently indicate alternate rises and falls of the land.

“To. resume I agree with my honourable friend, M. Becquerel, in
saying that forests exercise a complex action. I add that this action
has never been studied, specially with regard to the desiccation of
the soil which they cover, and the exhaustion of the springs which
may be the result. On this point there is work to be done, prejudices
to be destroyed, and truth to be revealed.”

All that is thus advanced by Marshal Vaillant is entitled to re-
spectful consideration. But along with these theoretic objections may
be taken into consideration facts which have been cited above in
numbers, and at the same time the following :—

214 ACTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER.

M. Conte-Granchamps, Ingénieur en Chef des Ponts et Chaussées,
has established by direct experiment, made with precision and with
the greatest care in the forests of coniferous trees situated in the
‘regions of the Loire and the Alps :—

“1, That existing sources have ceased to flow on the destruction
of forests.

“9, That these identical springs have re-appeared along with
‘vegetation.

“ 3. That the discharge from a water-course, the bassin de réception of
which is wooded, varies from one to two; whilst that of another water-
course, proceeding from a bassin de réception which is devoid of woods,
all things else being equal, varies from one to six.

“4, Finally, that the reboisement of one hectare, or two and a half
acres, will increase the discharge from the spring sixteen cubic.
metres daily ; whilst gazonnement, or covering it with herbage, in the
same circumstances increases the discharge by four cubic métres,.”

And on the other hand, M. d’Arbois de Jubainiville, in reply to an
appeal made to its readers by the Revue des Haux et Foréts, for
information respecting the influence of forests over the water system,
expresses himself as follows :—

“Several forest clearings have been executed in the canton of
Vaucouléurs. I have tried to discover what changes have been
produced in the springs. All the springs of this territory have their
rise in the middle strata of the oolitic system. And the forests above
are treated as are usually coppice and timber forests.

“In the territory belonging to the commune of Taillancourt the
spring of Vaux-de-Bure had never dried up so long as the plateau
which supplied it was shaded by the forest of Vauwx-de-Bure, but
ever since the half of that forest was cut down every summer the
spring has ceased to flow. The clay bed underlying the spring is at
no great depth ; it lies within a few métres of the surface throughout
the greater part of the basin of supply.

“In the commune of Sauvoy, near the Mayoralty, a perennial
spring became ephemeral when a wood was cut down which covered
the side of a hill, at the foot of which the spring was situated.

“Qn the contrary, in the commune of Monsigny-les-Vaucouleurs,
the partial clearing of a hill overhanging the spring has not interfered
with the outflow, the fountain of supply seeming to be very deep.

“JT have also examined the effects of exploitation where felling
takes place in the basin of the springs, giving thus free access to
to them of sunshine and wind.

TESTIMONY OF M. D’ARBOIS. 215

“In the reserved quarter, in Maxey-sur-Vaise, the summer flow of
the spring of Moymout was much diminished when its basin was
exposed by the exploitations. The impermeable bed on which the
water is collected lies at no great depth, for during the season of
making charcoal the taste of the spring is affected by the smoke.

“The inhabitants of the small town of Void have also noticed a
diminution in the summer discharge of water, on the destruction of
the woods subject to a right of felling which surmount the springs.

““M. Clavery—who, for a long time, and with such enlightened
care, has administered Commercy,—has also made similar observa-
tions on the water system which supplies that town. He writes thus
on the subject :—

“ «Since the exploitation of the woods situated in the basin of the
source called Fontaine Royale, which supplies the town, for two or
three months every year the inhabitants are deprived of ‘ater.
Almost all the springs dry up about the month of July. Even
before these woods were cut down this scarcity had begun to appear,
but only slightly, very few springs being entirely dried up during
great heat ; but since the exploitations near the Fontaine Royale the
greater number are exhausted every year.’

“ Cutting down woods has a still greater influence on ponds. Thus
the ponds situated in the reserved quarter at Taillancourt was full of
water during the growth of the neighbouring woods, but ever since
they were cut down it becomes dry during the summer.

“In the same way roads which were muddy and impassable have
been rendered dry and good in summer by cutting down the adjoin-
ing woods.

“In fine,” he remarks in conclusion, “ forests increase the summer
out-flow of the springs by preventing the ground being dried up, and
this influence is all the greater when the water collects on an
impermeable bed at no great depth.”

From these facts, and the many others which have been adduced,
there seems to be no room for doubt, notwithstanding the authority
to be attached to anything proceeding from the pen of a man like
M. le Marshal Vaillant, that forests exercise a great influence on
the water system of a district.

But we can carry our investigations much farther, and trace the
operation whereby trees arrest and so regulate the flow of and escape
of the rainfall in many of -its details, and so make manifest what the
effect of trees in this operation is.

216 ACTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER,

Herr Wex has expressed his views on this point in a passage I have
quoted, and Marsh in his treatise on the “ Earth as Modified by
Human Action,” states in regard to a forest :—

“ By its interposition, as a curtain between the sky and the ground,
it both checks the evaporation from the earth, and mechanically
intercepts. a certain portion of the dew and lighter showers, which
would otherwise moisten the surface of the soil, and restores it to the
atmosphere by exhalation. While in heavier rains the large drops
which fall upon the leaves and branches are broken into smaller ones,
and, consequently, strike the ground with less mechanical force, or are,
perhaps, even dispersed into vapour without reaching it.

“The vegetable mould, resulting from the decomposition of leaves
and of wood, seems as a perpetual mulch to forest soil by carpeting
the ground with a spongy covering which obstructs the evaporation
from the mineral earth below, drinks up the rains and melting snows
that would otherwise flow rapidly over the surface, and perhaps be
conveyed to the distant sea, and then slowly give out by evaporation
infiltration, and percolation, the moisture thus imbibed. The roots,
too, penetrate far below the superficial soil, conduct water along
their surface to the lower depths to which they reach, and then by
partially draining the superior strata, remove a certain quantity of
moisture out of the reach of evaporation.”

The meteorological effects produced thus by forests resolve them-
selves into the prolongation and consequent increase of the evapora-
tion of water falling in the forms of rain, snow, and hail, effected in
two distinct operations, first the absorption and retention of a large
portion of the rainfall, and second the retardation of the flow of the
remainder towards the great reservoir and source of all, in accord-
ance with the observation of the Hebrew preacher, “ All the rivers
run into the sea; yet the sea is not full: for unto the place from
whence the rivers come thither they return again.”

Mr Marsh speaks of the ever-renewed and increasing vegetable
mould as a perpetual mulch, and in reference to the humidity of
forest soil he cites the following passage from Etudes sur I Economie
Forestiére, by Jules Clavé:—“ Why go so far for the proof of a
phenomenon which is repeated every day under our own eyes, and of
which every Parisian may convince himself without venturing beyond
the Bois de Bologne, or the Forest of Meudon? Let him after a few
rainy days pass along the Chevreuse road, which is bordered on the
right by the wood, and on the left by cultivated fields. The fall of
water, and the continuance of the rain, have been the same on both

STATEMENT BY M. MARSCHAND. 217

sides ; but the ditch on the side of the forest will remain filled with
water, proceeding from infiltration through the wooded soil long after
the other, contiguous to the open ground, has performed its office of
drainage and become dry. The ditch on the left will have discharged
in a few hours a quantity of water which the ditch on the right requires
several days to receive and carry down to the valley.” And but for
this drainage into the ditch the water might have remained there for
an indefinitely longer time. Thus by an operation, distinct from all
that have been mentioned, the humidity of the soil is prolonged and
maintained by forests. By continuous exhalations of moisture
through the stomates of the leaves—the moisture being obtained
in part, and it may be in great part, fromm what is stored up in these
superficial and deeper-lying reservoirs, replenished from time to time
by rain—the humidity of the air in a forest is increased ; bnt it is
the other phase of the operation with which we have at present
more especially to do.

It is this effect of forests which has led to the extensive replanting
of the Alps, the Cevennes, and the Pyrenees with trees, herbage, and
bush, with a view to arresting and preventing the destructive conse-
quences and effects of torrents. In a separate volume I have given a
copious compilation of records of what has been done, of what led to
this being done, and of the successful results which have followed.
Here I may cite some of the statements made by one of the writers
on the subject, M. L. Marschand. I have already referred to
remarks by him on the hydroscopicity and capillarity of certain
minerals ; as a property distinct and different from these which retain
moisture, he speaks of the permeability of soils, by which they give
passage to moisture and allow of its transmission; and he gives
cases of minerals which absorb and retain very little moisture in
their structure, but which are very permeable by water.

In general, rocks which are highly hydroscopic are not very
permeable, for the molecules, once moistened, cohere and present the
appearance of a cofmpact mass impermeable to water, as may be seen
in clay.

On a permeable soil or subsoil, trees create and maintain on the
surface a layer of humus of considerable hydroscopic and capillary
properties, retaining water, and modifying the general permeability.
While, on an impermeable rock, the roots break up this and increase
the permeability.

The’principle which he seeks to establish is, that forests have the
Z

218 ACTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER.

effect of modulating the properties of rocks, giving to them what they
have not ; and he alleges it is in this way, more especially, that their
action is salutary in the contro) of waters on the mountains, Of this
view of the subject he gives the following illustration :—‘ When the
rain falls on a denuded brow of a hill, composed of argillaceous earth
the water moistens the surface—this absorbs a great quantity of it,
through its hydroscopicity and capillarity—but when once this surface
is moistened, the transmission of water goes on only very slowly from
particle to particle, for the permeability is almost nothing, in
consequence of the minute subdivision of the molecules which are
brought into the closest contact ; and that which is absorbed remains
on the surface and dilutes the superficial layer, which is soon thustrans-
formed into a thin clay devoid of cohesion. A layer more or less deep
will then detach itself from the surface of the mass, and will flow to the
bottom as mud more or less fluid, according as the rain may have
been more or less violent. By a very gentle rain, a superficial layer
is moistened ; but the water falling slowly may be able to penetrate
it completely, in virtue of its hydroscopicity and capillarity. In this |
cas2 there will be only a superficial flow, for the greater portion of the
water will penetrate the soil.

“ But suppose that this same argillaceous land, or other unstable
ground, were wooded, the trees in spreading the fall of the rain over
an expanded surface, that of their foliage, would moderate the rain-
fall, and would at the same time augment the absorbent power of the
soil, as well as its permeability, and as a consequence augment the
quantity of water retained superficially. The mobility of the surface
thus softened would, undoubtedly, be increased, but the roots im-
prisoning it would retain the softened ground to such a degree that
no amount of water falling upon them from the heavens alone could
cause it to slip away. Wherever landslips occur on wocded grounds
they can be otherwise accounted for.

“Tf, in conclusion,” says he, “we examine a forest situated on a
land permeable en masse, as are the plateaux of jurassic limestone, the
first effect of the forest would be to cover the soil with a thick layer
of humus and of moss, which combine in a very high degree
hydroscopicity and capillarity. The quantity of water retained thus
in the upper layer of the soil will be much greater than it would have
been had there been no forest there, for on the rocks referred to the
destruction of woods is almost immediately followed by a denudation
of these rocks of soil.

“Tt follows from this that on these lands the forest arrests the

SPATEMENT BY M. MARSCHAND, 219

descent of the waters to the bottom of the valleys, for it is only very
slowly that water retained by hydroscopicity and capillarity quits the
substances which they penetrate. Moreover, as the greatest storms
of rain never do saturate completely the layer of humus on wooded
soils, it is impossible to form torrents on these.”

He states that the effect of gazonnement is to augment the
hydroscopicity and capillarity of the surface of the soil, but that this
is not sufficient to secure the absorption of all the water that falls
upon it in a storm of rain, and he sites facts in support of the allegation.
The same good effects, he states, are produced to a greater extent by
buissonnement, or the planting of bushes, while a layer of humus of
great hydroscopicity, produced by the decay of their leaves, co-operates
in the production of these good effects; but he cites evidence that
even gazonnement and buissonnement combined have failed to prevent
erosion and the formation of torrents.

But forests produce in a surpassing degree each and all of the
effects referred to, as produced in a minor degree by meadows and
bush. (1) They form by their detritus a very hydroscopic layer, and
in consequence augment the quantity of water retained ; (2) They
augment the expansion of surface on which the water falls; and (3)
They augment the capillarity and permeability of the subsoil.

“T have,” says he, “in treating of the permeability of the soil,
explained the influence of forests on this. In retaining for some time
the water at the surface they augment considerably the quantity which
is absorbed, particle by particle, by hydroscopicity and capillarity, for
this absorption is slow ; and thus, in a word, the forest tempers the
action of rain dashed downwards in a storm, and leads the water gently
on to the soil, as if it had fallen in a gentle shower; and further, it
augments, in fine, the permeability of the soil, by keeping the surface
unhardened and in some sort always open tg receive the water which
comes slowely from the heavens,

“‘T make no mention of the influence of forests in regard to
evaporation—in regard to the direct absorption of water—and in re-
gard to the humidity of the atmosphere, etc. I take up one point of
view alone of the torrential management of waters in the high
mountains, and these relate to this only indirectly.

“ Tf a storm of rain beat upon a forest the whole of the water which
falls is temporarily retained, all penetrates more or less deeply the
soil without flowing on the surface ; and, it may be objected, if the
subsoil is impermeable the result will be the same. But the objection
is without foundation. I shall suppose, what is frequently the case,

220 ACTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER.

that there is impermeable rock underlying the humus: all the water
should arrive at this bed of rock and flow down, but the hydroscopicity
and capillarity of this humus—of the ground—of the foliage—of the
branches of the trees—in a word, of the material of which the forest
is composed—will arrest the water to such a degree and measure as
to regulate temporarily the delivery.

“T have glanced rapidly at the action of eT in view simply of
their effect on the water which falls on their surface ; but their
function is by no means limited to this, for they serve alsa to arrest
the waters which come from the pastures above them. They constitute
in some measure a kind of immense and powerful barrage, or barrier
placed between the summit and the bed of the valleys.

“In support of this allegation, I shall cite personal observations
which seem to me conclusive. Never have I seen, during the most
violent storms of rain, superficial flowings of water in the forests
situated under pastures, though such flowings may have existed in the
meadows at a greater elevation than the forests ; all the waters which
these supplied were literally absorbed and retained by the forest soil.
I except, intentionally, well-marked ravines, which coming from above
traverse forests, for the question here is only of slopes somewhat uniform,
or but slightly undulated ; it is evident that the soil of the forest will
not absorb the water of a stream which traverses it encased in a bed.

“‘T take, for example, a valley which rises to a summit line some-
what elevated. The end situated at a great height is formed entirely
of pasture lands, which spread out equally on the summits of the
brows of the mountains; at a lower level beneath these are the
forests. The waters which fall into the cistern formed by the head
of the valley rapidly accumulate, and give birth to a torrent which
traverses the forest. On the contrary, that which falls on the pasture
lands above the brows do not commonly reach the depth of the
ravine; descending to the forest zone uniformly extended over the
soil, they are there absorbed.

“Tn a word, the zone of the forest absorbs generally the water
flowing from the zone of pasture lands which correspond to it. In
support of these observations, I appeal to all who, in the Alps, have
observed storms of rain in the forest. I except water accumulated in
ravines or depressions, which are in another condition.

“ But the beneficent action of the forests does not limit itself to
this ; the flow in the ravine may also, if it be not completely absorbed,
be by them rendered less injurious if it should come to spread itself
ever a cone de déjection in a forest otherwise covered with wood. 1

STATEMENT BY M. LEMOINE. a)

have observed, in connection with this, numerous muddy floods in
ravines which, spreading themselves out in the middle of a forest,
come out thence very limpid, depositing in it their slime, and leaving
in it also almost the whole of the water.

“The great forest of the Ofen, in the Grisons has supplied me
me with many instances of this. The soil, composed of the dolomite
limestone of the triassic period, is somewhat unstable ; in the middle,
of the pasture lands whicL surmount the forest there are formed every
year numerous torrents, which to an enormous extent carry off the
small pebbles, which are characteristic of the dolomite. All these
torrents arriving in the forest, then expand and diffuse themselves,
and very rarely do they penetrate to the bottom of the valleys. In
the upper portion of the Munster-Thal, I have seen on the right-hand
side an enormous ravine, the muddy torrents of which are arrested by
the forest. And the waters of the Munster, so well enclosed at this
point, are a proof of the beneficial action of the forests. In fine, from
the moment that the forests begin to retain the mud they retain also
temporarily the greater portion of the water in which this was sus-

pended, which are arrested by the enormous absorbent powers they
possess.”

At the meeting of the Brititsh Association held at Brighton in
1876, M. G. Lemoine, Zngenzeur des Ponts a4 Chaussées, read a paper
“ Sur les Forets dans leur Rapports avec l‘Hydrologie.” In which he
stated that in the basin of the Seine it had been established that, com-
pared with soil covered with grass, or even with other permanent culti-
vation forests had no special influence on watercourses. The only
‘absolutely certain action of forests was their influence in protecting
the soil and preventing it from being carried away; but from this
single fact it followed that in mountainous countries they would
retard the flow of torrential water. In the Department of the Hautes
Alpes the presence of forest vegetation prevented the formation of
torrents ; re-planting woods led to the drying up of torrents already
formed ; but in most cases turfing, alone, was sufficient to pruduce
the same effect.

M. Cézanne, in writing of what he calls the Mécanisme de [Inonda-
tion, remarks that the rain as soon as it has fallen becomes divided
into three portions, the first of which, taken up again by evaporation,
returns into the atmosphere to be formed into new showers; the
second, after infiltration into the soil, appears again at a lower leye]
in the form of springs, when it loses not itself in the deeper

222 ACTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER,

reservoirs, whence it is made to project itself by artisian wells ;
finally, the remainder flows away by a thousand streamlets towards
the thalweg, feeding the brooks, and streams, and rivers.

But these portions do not stand to each other in any definite pro-
portion. Their relative importance varies not only, between one
water-course and another, with the nature of the ground, according
as this may be more or less favourable to the flow, or to the infil-
tration, but also in the case of the same water-course according as
the season restrains or promotes evaporation. In summer the drier
soil and warmer air are more greedy ; they drink up or absorb the
waters ; in winter the moist air and damp ground allow the sheet of
rainfall to flow away.

The only general and certain law is that over the area of the river’s
basin these are complemental to one another, their sum is equal to
the quantity of rainfall. And if, for example, after evaporation has
taken away its portion, the infiltration be complete, the flow will be
nought.

It is the infiltration which is here brought under consideration.

Following out this division he says that it is by springs that the
permeability of the soil may be said to be revealed to us, and if their
régime be connected with meteorology, their existence depends on
geological conditions. And in illustration he says :—

“ Mount Ventoux—separated from the Alps by deep valleys, and
isolated on all sides,—is a mass of very permeable cleft limestone,
resting on an impermeable base which slopes toward the south-east.
So constructed, the mountain is a veritable filter, through which the
rain disappears at once ; and excepting in the cases of any violent
storms of rain, the superficial ravines are always dry. The sub-
terranean waters protected from evaporation descend slowly by the
internal fissures of the rock, and stopped at last by the impermeable
bed, they are directed towards the south-east, and flow out in springs
and streams sufficiently powerful to give motion to water-mills.

“The fine fountain of Vaucluse owes its origin to analogous
circumstances : it is a veritable river, which is formed as other rivers
are by the means of a great many imperceptible tributaries ; but it
presents this peculiarity, that its basin instead of being open to the
vault of heaven, is subterranean, and covered by a great thickness of
permeable limestone. The area of the basin is nearly 100,000
hectares, * the delivery of the fountain is at low water from 10 to 12

* Bouvier, Annales des Ponts et Ohaussées. (1855, p. 367.)

8TATEMENT BY M. CEZANNE, 223

cubic métres, 300 to 350 cubic feet, that is almost the sixth part of
the Seine.* The Eure, the basin of which is in extent six times that
of the fountain of Vaucluse, gives no more water than this at low
water.

“What a difference there is between the climate of Provence and
that of Normandy! In Provence the evaporation might carry off three
or four times as much water as the rain supplies ; the greater purt of
the water-courses there are dried up in summer, and the plains of the
Camargue, notwithstanding inundations and irrigation, are covered
with saline inflorescence. If then, under this climate, the source of
the Vaucluse is so constant and so abundant, it is because its basin
being, as is the case with all sources, subterranean, the water which
has once penetrated the ground is there sheltered against evaporation.”

Now, turning to the consideration of forest lands, we find that,
besides the desiccating of swampy land by evaporating through the
stomates of the leaves the moisture taken up by the rootlets, another
effect of the growth of trees is to desiccate the superficial soil by
aiding the water which it receives to descend along its roots toa
lower level, whence it is less likely to be carried off quickly by
evaporation,

* The roots of vegetables,” says d’Hericourt, in a passage which is
quoted by Marsh, “perform the office of draining in a manner
analogous to that artificially practised in parts of Holland and the
British Islands. The method consists in driving deeply down into
the soil several hundred stakes to the acre ; the water filters down
along the stakes, and in some cases as favourable results have been
obtained by this means as by horizontal drains.”

And by Marsh it is remarked :—“ It is an important observation
that the desiccation of trees by way of drainage, or external conduc-
tion by the roots, is greater in the artificial than in the natural wood,
and hence that the surface of the ground in the former is not char-
acterised by that approach to the state of saturation which it so
generally manifests in the latter. In the spontaneous wood, the
leaves, fruits, bark, branches, and dead trunks, by their decayed
material, and by the conversion of rock into loose earth, through the
solvent power of the gases they develope in decomposition, cover the
ground with an easily penetrable matter extremely favourable to the

* On the 12th August, 1858, the Seine was lower than had been observed for a
hundred and fifty-six years before, The gauging that day gave a delivery of 48 cubic
métres per second. The ordinary low water of the Seine is from 75 to 80 matres,
Belgrand, Annales des Ponts et Chaussées. (1858 t. ii p. 222.)

224 AcTION OF FORESTS ON THE SURFACE-FLOW OF RAIN WATER.

growth of trees, and at the same time too retentive of moisture to
part with it readily to the capillary attraction of the roots.

“The trees, finding abundant nutriment near the surface, and so
sheltered against the action of the wind by each other as not to need
the support of deep and firmly fixed stays, send their roots but a
moderate distance downwards, and indeed often spread them out like
a horizontal network almost on the surface of the ground.

“Tn the artificial wood, on the contrary, the spaces between the
trees are greater ; they are obliged to send their roots deeper, both
for mechanical support and in search of nutriment, and consequently
serve much more effectually as conduits for perpendicular drainage.”

If attention be given to the mode of growth in roots and rootlets,
it may be seen how it comes to pass that the fact is as stated by
Mr Marsh.

The root does not bore its way into and through the soil it
enters, but it is prolonged, as is the line of dominoes by the players
with these. The extreme cells, and probably the extreme cells only,
or chiefly, multiply in the spongioles in accordance with the usual
mode of cell genesis by the formation of cells within cells, and that
in proportion as they are supplied with nutriment; and if this
multiplication of cells occasion a pressure in all directions, it tends
more to the extension of the root than to what may be called the up
rooting of the tree. The direction of growth appears to be to whence
chiefly come the supplies of nutriment, or material of growth.
Where this is found on the level reached the roots extend. Where it
is found in the soil below them they descend. Where it is found in
the soil above them they ascend. I have had reported to me a case
of roots extending towards a ditch, descending by the side of this,
changing then their course so as to pass beneath it, ascending then
on the further side till they came near the surface, and then spreading
horizontally as at first,

I have often heard of roots growing towards a quantity of assimilate-
able material as if guided by instinct ; and I am given to understand
that in willows by a stream there is generally a much more copious
growth of roots on the side towards the stream than on the other
sides around. Roots of forest trees are often prevented from descend-
ing by planting them above a flat stone, which cuts off supplies ; and
roots of fig-trees growing upon rocks fullow and penetrate every crack
and crevice where, and where alone, they find nutriment.

Thus may the downward growth of roots of planted trees be ac-

sECONDARY EFFECTS OF TREES. 225

counted for, and the horizontal growth of roots of trees in a forest.
when such phenomena are seen; and by this downward growth of the
roots of planted trees may the descent of water to the subsoil be
promoted, there to be reserved against a day of need, converting the
subsoil into a reservoir of water, which, raised by evaporation by heat,
would moisten the superincumbent sail, promote vegetation, and
pass again through the stomates of the leaves into the atm>sphere,—
again to be precipitated ani absorbed by the soil instead of flowing
off to the sea, to be lost in that abyss which never says it is
enough '‘—the springs and fountains and river sources being to us
significant of the greatness of the quantity of water which is thus
retained.

In view of all that has been advanced, it appears that trees
by their growth, the extent of their rootage, and the decay and de-
composition of their foliage and debris, tend to increase the proportion
of the rainfall which is preserved by infiltration, and to utilise for the
promotion of vegetation, a larger portion of what is thus retained
than otherwise would be so utilized.

The depth at which evaporation ceases must vary with the
temperature, humidity of the atmosphere and character of the soil.
Some interesting observatisns on this point are recorded by Johnstrus,
in a work entitled Om Fugtighedens Bevaegelese i den naturlige Jord-
bund, published in Copenhagen in 1266. He found in the neighbour-
hood of Copenhagen that there, at the depth of a métre and a half
(59 inches) the effects of rain and evaporation were almost impercep-
tible, and became completely so at a depth of from two to three
metres. (64 to 10 feet.

Sect. V.—Secondary Effects of Trees in Arresting the Flow and
Escape of the Rainfall, and thus equalizing to some extent
the Flow of Rivers.

While rivers in their sources indicate to us that the quantity of
water retained by the earth after a copicus fall of rain, by the infil-
tration of a portion of this into the soil, must be very great—even
these being composed =f what is only the drainage of the quantity in
excess of what the ground can retain—rivers in their flood indicate
that the portion of the rainfall carried away by ruiss-llement, or
by flowing away over the surface of the groand, must 4]s9 be great.

It may be noted that of what is retained by infiltration a great

deal may be utilized by vegetation ; and that of what is in excess of
2a

226 ACTION OF FORESTS ON THE FLOW OF RIVERS,

this and is carried off, feeding springs and fountains, and streams, the
saddest thing that can be said is that it is lost, though this can only
be said with a show of truth of that portion of it which is lost in the
sea; but of what is carried off by ruissellement comparatively little is
utilized ; a much greater proportion of it finds its way to the sea, and
this in rushing thither often carries with it devastation and destruc-
tion,

According to the statements I have cited from Surell, evaporation,
infiltration, and rwissellement, are equal in their sum to the quantity
of the rainfall, and if after evaporation has taken up its part the in-
filtration be complete, the ruissellement will be nil.

To the negative good which might thus be done, or damage which
might thus be prevented, and the effect of trees in doing these, by
equalizing to some extent the flow of rivers, would I next draw
attention.

In connection with a statement made in the preceding section,
relative to the effect of the destruction of forests upon the Darance,
reference was made to the important circumstance that while the
river is confined to a current little more than thirty feet in width,
the bed in some places exceeds a mile and a quarter in breadth, and
so far back as 1789 it was computed that it had covered an area of
not less than 130,000 acres with gravel and pebbles; and it was
intimated that thus was brought before us another of the effects of
forests, or rather of the destruction of forests, which would be sub-
sequently brought under discussion.

Mr Marsh, writing on this subject, says : “ The traveller who visits
the depth of an Alpine ravine, observes the length and width of the
gorge, and the great height and apparent solidity of the precipitous
walls which bound it, and calculates the mass of rock required to fill
the vacancy, can hardly believe that the humble brooklet which
purls at his feet has been the principal agent in accomplishing this
tremendous erosion. Closer observations will often teach him that
the seemingly unbroken rock which overhangs the valley is full of
cracks and fissures, and really in such a state of disintegration that
every frost must bring down tons of it. If he compute the area of
the. basin, which finds here its only discharge, he will perceive that
a sudden thaw of the wiuter’s deposit of snow, or one of those terrible
discharges of rain so commen in the Alps, must send forth a deluge
mighty enough to sweep down the largest masses of gravel and of rock.
The simple measurement of the cubical contents of the semicircular

8TATEMWENT BY MR MARSH. 227

hillock which he climbed before he entered the gorge, the structure
and composition of which conclusively show that it must have been
washed out of this latter by torrential action, will often account
satisfactorily for the disposal of most of the matter which once filled
the ravine.

“When a torrent escapes from the lateral confinement of its moun-
tain walls and pours out of the gorge, it spreads and divides itself
into numerous smalier streams, which shoot out from the mouth of
the ravine as from a centre, in different directions, like the ribs of a
fan from the pivot, each carrying with it its quota of stones and
gravel. The plain below the point of issue from the mountain is
rapidly raised by newly-formed torrents, the elevation depending on
the inclination of the bed and the form and weight of the matter
transported. Every flood both increases the height of this central
point and extends the entire circumference of the deposit.

“Other things being equal, the transporting power of the water is
greatest where its flow is most rapid. This is usually in the direction
of the axis of the ravine. The stream retaining most nearly this
direction moves with the greatest momentum, and consequently
transports the solid matter with which it is charged to the greatest
distance.

‘The untravelled reader will comprehend this the better when he
is informed that the southern slope of the Alps generally rises suddenly
out of the plain, with no intervening hill to break the abruptness of
the transition, except those consisting of comparatively small heaps
of its own debris brought down by ancient glaciers or recent torrents.
The torrents do not wind down valleys gradually widening to the
rivers or the sea, but leap at once from the flanks of the mountains
upon the plains below. This arrangement of surfaces naturally
facilitates the formation of vast deposits at their points of emergence,
and the centre of the accumulation in the case of very small torrents
is not unfrequently a hundred feet high, and sometimes very much
more.

“The deposits of the torrent which has scooped out the Nantzen
Thal, a couple of miles below Brieg in the Valais, have built up a
semicircular hillock, which most travellers by the Simplon route pass
over without even noticing it, though it is little inferior in dimensions
to the great eones of dejection Gescribed by Blanqui. The principal
course of the torrent having been—I know not whether spontaneously
or artificially—directed towards the west, the eastern part of the hill
has been gradually brought under cultivation, and there are many

228 ACTION OF FORESTS UN THE FLOW OF RIVERS.

trees, fields, and houses upon it; but the larger western part is
furrowed with channels diverging from the summit of the deposit at
the outlet of the Nantzen Thal, which serve as the beds of the water
courses into which the torrent has divided itself. All this portion of
the hillock is subject to inundation after long and heavy rain, and as
I saw it in the great flood of October, 1866, almost its whole surface
seemed covered with an unbroken sheet of rushing water.

“The semi-conical deposit of detritus at the mouth of the Litzner-
thal, a lateral branch of the valley of the Adige, at the point where
the torrent pours out of the gorge, is a thousind feet high and,
measuring along the axis of the principal current, two and a half
miles long. The solid material of this hillock—which it is hardly an
exaggeration to call a mountain, the work of a single insignificant
torrent and its tributaries—including what the river which washes its
base has carried off in a comparatively few years, probably surpasses
the mass of the stupendous pyramid of the Matterhorn.

“In valleys of ancient geological formation, which extend into the
very heart of the mountains, the streams, though rapid, have often
lost the true torrential character, if, indeed, they ever possessed it.
Their beds have become approximately constant, and their walls no
longer crumble and fall into the waters that wash their bases. The
torrent-worn ravines, of which I have spoken, are of later date, and
belong more properly to what may be called the crust of the Alps,
consisting of loose rocks, of gravel, and of earth, strewed along the
surface of the great declivities of the central ridge, and accumulated
thickly between the solid buttresses. But it is on this crust that
the mountaineer dwells. Here are his forests, here his pastures, and
the ravages of the torrent both destroy his world, and convert it into
a source of overwhelming desolation to the plains below.

“J do not mean to dssert that all the rocky valleys of the Alps .
have been produced by the action of torrents resulting from the
destruction of the forests. The greater, and many of the smaller
channels by which that chain is drained owe their origin to higher
causes. ‘There are primitive fissures, ascribable to disruption in up-
heaval or other geological convulsion, widened and scarped, and
often even polished, so to speak, by the action of glaciers during the
ice period, and but little changed in form by running water in
later eras.

“Tt has been contended that all rivers which take their rise in
these mountains originated in torrents. These, it is said, have
lowered the summits by gradual erosion, and with the material thus

>TATEMENT BY MR MARSA. 229

derived have formed shoals in the sea which once beat against the
cliffs ; then, by successive deposits, gradually raised them above the
surface, and finally expanded them into broad plains traversed by
gently flowing streams. If we could go back to earlier geological
periods, we should find this theory often verified ; and we cannot fail
to see that the torrents go on, at the present hour, depressing still
lower the ridzes of the Alps and the Apennines, raising still higher
the plains of Lombardy and Provence, extending the coast still
farther into the Adriatic and the Mediterranean, reducing the
inclination of their own beds and the rapidity of their flow, and thus
tending to become river-like in character.

“ We cannot measure the share which human action has had in
augmenting the intensity of causes of mountain degradation, and of
the formation of plains and marshes below, and we know that the
clearing cf the woods has, in some cases, produced, within two or
three generations, effects us blasting as those generally ascribed to
geological convulsions, and has laid waste the face of the earth more
hopelessly than if it had been buried by a current of lava or
a shower of volcanic sand. New torrents are forming every year
in the Alps. Tradition, written records, and analogy concur to
establish the belief that the ruin of most of the now desolate valleys
in those mountains is to be ascribed to the same cause, and
authentic descriptions of the irresistible force of the torrent show
that, aided by frost and heat, it is adequate to level Mont Blanc
and Monte Rosa themselves, unless new upheavale shall maintain
their elevation.

“There are cases where torrents cease their ravages of themselves
in consequence of some change in the condition of the basin where
they originate, or of the face of the mountain at a higher level, while
the plain of the sea below remains in substantially the same state as
before. If a torrent rises in a small valley containing no great
amount of earth and of a disintegrated or loose rock, it may, in the
course of a certain period, wash out all the transportable material,
and if the valley is then left with solid walls, it will cease to furnish
débris to be carried down by floods. If, in this state of things, a new
channel be formed at an elevation above the head of the valley, it
may divert a part or even the whole of the rain-water and melted
snow which would otherwise have flowed into it, and the once furious
torrent now sinks to the rank of a humble and harmless brooklet.
‘In traversing this department,’ says Surell, ‘ one often sees, at the
outlet of a gorge, a flattened hillock, with a fan-shaped outline and

2 30 ACTION OF FORESTS ON THE FLOW OF RIVERS.

regular slops ; it is the bed of dejection of an ancient torrent. It
sometimes requires long and careful study to detect the primitive
form, masked as it is by groves of trees, by cultivated fields, and
often by houses, but, when examined closely, and from different
points of view, its characteristic figure manifestly appears, and its
true history cannot be mistaken. Along the hillock flows a streamlet,
issuing from the ravine, and quietly watering the fields. This was
originally a torrent, and in the back ground may be discovered its
mountain basin. Such extinguished torrents, if I may use the
expression, are numerous,”

The quotation is from Htude sur les Torrents des Hautes Alpes, by
Surell (Chap. xxiv.), and Mr Marsh adds in a foot-note:—*‘In such
cases, the clearing of the ground, which, in consequence of a temporary
diversion of the waters, or from some other cause, has become re-
wooded, sometimes renews the ravages of the torrent. Thus, on
the left bank of the Durance, a wooded declivity had been formed by
the débris brought down by torrents, which had extinguished them-
selves after having swept off much of the superficial strata of the
mountain of Morgon. ‘All this district was covered with woods,
which have now been thinned out and are perishing from day to day ;
consequently, the torrents have recommenced their devastations, and
if the clearings continue, this declivity, now fertile, will be ruined,
like so many others.’ ”

And resuming, he goes on to say :—“ But for the intervention of
man and domestic animals, these latter beneficent revolutions would
occur more frequently, and proceed more rapidly. The now scarped
mountains, the hillocks of debris, the plains elevated by sand and
gravel spread over them, the shores freshly formed by fluviatile
deposits, would clothe themselves with shrubs and trees, the intensity
of the causes of degradation would be diminished, and nature would
thus regain her ancient equilibrium. But these processes, under
ordinary circumstances, demand, not years, or generations, but
centuries ; and man, who even now finds scarce breathing-room on
this vast globe, cannot retire from the Old World to some yet undis-
covered continent, and wait for the slow action of such causes to re-
place, by a new creation, the Eden he has wasted.”

In a foot-note he adds :—‘‘ Where a torrent has not been long in
operation, and earth still remains mixed with the rocks and gravel it
heaps up at its point of eruption, vegetation soon starts up and
prospers, if protected from encroachment. In Provence, ‘ several
communes determined, about ten years ago, to reserve the soils thus

STATEMENT BY MR WARSH. 231

wasted, that is, to abandon them for a certain time to spontaneous
vegetation, which was not slow in making its appearance.’”

Mr Marsh next treats thus of two subjects intimately connected,
the crushing effects of torrents, and the transporting power of water :
—‘‘I must here notice a mechanical effect of the rapid flow of the
torrent, which is of much importance in relation to the desolating
action it exercises by covering large tracts of cultivated ground with
infertile material. The torrent, as we have seen, shoots or rolls
forward, with great velocity, masses and fragments of rock, and
sometimes rounded pebbles from more ancient formations, Every
inch of this violent movement is accompanied with crushing con-
cussion, or, at least, with great abrasion of the mineral material, and,
as you follow it along the course of the waters which transport it,
you find the stones gradually rounding off in form, and diminishing in
size, until they pass successively into gravel, and, in the beds of the
rivers to which the torrents convey it, sand, and lastly impalpable
slime.

“There are few operations of nature where the effect seems more
disproportioned to the cause than in this crushing and comminution
of rock in the channel of swift waters. Igneous rocks are generally
so hard as to be wrought with great difficulty, and they bear the
weight of enormous superstructures without yielding to the pressure ;
but to the torrent they are as wheat to the millstone. The streams
which pour down the southern scarp of the Mediterranean Alps along
the Riviera di Ponente, near Genoa, have short courses, and a brisk
walk of a couple of hours, or even less, takes you from the sea-beach
to the headspring of many of them. In their heaviest floods, they
bring rounded masses of serpentine quite down to the sea, but at
ordinary high water their lower course is charged only with finely
divided particles of that rock. Hence, while near their sources their
channels are filled with pebbles and angular fragments, intermixed
with a little gravel, the proportions are reversed near their mouths,
and, just above the points where their outlets are partially choked
by the rolling shingle of the beach, their beds are composed of sand
and gravel to the almost total exclusion of pebbles.

“ Guglielmini argued that the gravel and sand of the beds of run-
ning streams were derived from the trituration of rocks by the action
of the currents, and inferred that this action was generally sufficient
to reduce hard rock to sand in its passage from the source to the
outlet of rivers. Frisi controverted this opinion, and maintained

232 ACTION OF FORESTS ON THE FLOW OF RIVERS,

that river-sand was of more ancient origin, and he inferred from
experiments in artifically-grinding stones that the concussion, friction,
and attrition of rock in the channel of running waters were inadequate
to its comminution, though he admitted that these same causes might
reduce silicious sand to a fine powder capable of transportation to the
sea by the currents. Frisi’s experiments were tried upon rounded
and polished river-pebbies, and prove nothing with regard to the
action of torrents upon the irregular, more or less weathered, and
often cracked and shattered rocks which lie loose in the ground at
the head of mountain valleys. The fury of the waters and of the
wind which accompanies them in the floods of the French Alpine
torrents is such, that large blocks of stone are hurled out of the bed
of the stream to the height of tweive or thirteen feet. The impulse
of masses driven with such force overthrows the most solid masonry,
and their concussion cannot fail to be attended with the crushing of
the rocks themselves.

“The greatest lenoth of the basin of the Ardéche is seventy-five
railes, but most of its tributaries have a much shorter course. ‘ These
affluents,’ says Mardigny, ‘ hurl into the bed of the Ardéche enormous
blocks of rock, which this river, in its turn, bears onwards, and grinds
down, at high water, so that its current rolls only gravel at its con-
fluence with the Rhone.’

“‘Duponchel makes the following remarkable statement : ‘ The river
Herault rises in a granitic region, but soon reaches calcareous forma-
tions, which it traverses for more than sixty kilometres, rolling
through deep and precipitous ravines, into which the torrents are
constantly discharging enormous masses of pebbles belonging to the
hardest rocks of the Jurassian period. These débris, continually
renewed, compose, even below the exit of the gorge where the river
enters into a regular channel cut in a tertiary deposit, broad beaches
prodigious accumulations of rolled pebbles, extending several kilomé-
tres down the stream, but they diminish in size and weight so rapidly
that above the mouth of the river, which is at a distance of thirty or
thirty-five kilométres from the gorge, every trace of calcareous matter
has disappeared from the sands of the bottom, which are exclusively
silicious,’ ;

“Similar effects of the rapid flow of water and the concussion of
stones against each other in river-beds may be observed in almost
every Alpine gorge which serves as the channel of a swift stream.
The tremendous cleft through which the well-known Via Mala is
carried receives, every year, from its own crumbling walls and from

STATEMENT BY MR MARSH. 233

the Hinter Rhein and its mild tributaries, enormous quantities of
rock, in blocks and boulders. In fact, the masses hurled into it in a
single flood like those of 1868 would probably fill it up, at its narrow
points, to the level of the road 400 feet above its bottom, were not
the stones crushed and carried off by the force of the current. Yet
below the outlet at Thusis only small rounded boulders, pebbles, and
gravel, not rock, are found in the bed of the river. The Swiss
glaciers bring down thousands of cubic yards of hard rock every
season. Where the glacier ends in a plain or wide valley, the rocks
are accumulated in a terminal moraine, but in numerous instances
the water which pours from the ice-river has force enough to carry
down to larger streams the masses delivered by the glacier, and there
they, with other stones washed out from the earth by the current,
are ground down, so that few of the affluents of the Swiss lakes
deliver into them anything but fine sand and slime.

“Great rivers carry no boulders to the sea, and, in fact, receive
none from their tributaries. Lombardini found, twenty years ago,
that the mineral matter brought down to the Po by its tributaries
was, in general, comminuted to about the same degree of fineness as
the sands of its bed at their points of discharge. In the case of the
Trebbia, which rises high in the Apennines and empties into the Po
at Placenza, it was otherwise, that river rolling pebbles and coarse
gravel into the channel of the principal stream. The banks of the
other affluents—excepting some of those which discharge their waters
into the great lakes—then either retained their woods, or had been so
long clear of them that the torrents had removed most of the disin-
tegrated and loose rock in their upper basins. The valley of the
Trebbia had been recently cleared, and all the forces which tend to
the degradation and transportation of rock were in full activity.” Of
the transporting power of water he writes : “‘ The geographical effects
of the action of torrents are not confined to erosion of earth and com-
minution of rock ; for they and the rivers to which they contribute
transport the débris of the mountains to lower levels, and spread them
out over the dry land and the bed of the sea, thus forming alluvial
deposits, sometimes of a beneficial, sometimes of an injurious,
character, and of vast extent.

« A mountain rivulet swollen by rain or melted snow, when it
escapes from its usual channel and floods the adjacent fields, naturally
deposits pebbles and gravel upon them ; but even at low water, if, of
course, it is long enough for its grinding action to have fall scope, it
transports the solid material with which it is charged to some larger

2B

234 ACTION OF FORESTS ON THE FLOW OF RIVERS.

stream, and there lets it fall in a state of minute division, and at last
the spoil of the mountain is used to raise the level of the plains, or
is carried down to the sea.
“An instance that fell under my own observation, in 1857, will
serve to show something of the eroding and transporting power of
streams which, in these respects, fall incalculably below the torrents
of the Alps. In a flood of the Ottaquechee, a small river which flows
through Woodstock, Vermont, a mill-dam on that stream burst, and
the sediment with which the pond was filled, estimated after careful
measurement at 13,000 cubic yards, was carried down by the current.
Between this dam and the slackwater of another, four miles below,
the bed of the stream, which is composed of pebbles, interspersed in
a few places with larger stones, is about sixty-five feet wide, though,
at low water, the breadth of the current is considerably less. The
sand and fine gravel were smoothly and evenly distributed over the
bed to a width of fifty-five or sixty feet, and, for a distance of about
two miles, except at two or three intervening rapids, filled up all the
interstices between the stones, covering them to the depth of nine or
ten inches, so as to present a regularly formed concave channel, lined
with sand, and reducing the depth of water, in some places, from five
or six feet to fifteen or eighteen inches. Observing this deposit after
the river had subsided and become go clear that the bottom could be
seen, I supposed that the next flood would produce an extraordinary
erosion of the banks and some permanent changes in the channel of
the stream, in consequence of the elevation of the bed and the filling
up of the spaces between the stones through which formerly much
water had flowed ; but no such result followed. The spring freshet
of the next year entirely washed out the sand its predecessor had
left, deposited some of it in ponds and still-water reaches below,
carried the residue beyond the reach of observation, and left the bed
of the river almost precisely in its former condition, though, of
course, with the displacement of the pebbles which every flood
produces in the channels of such streams. The pond, though often
previously discharged by the breakage of the dam, had then been un-
disturbed for about twenty-five years, and its contents consisted
almost entirely of sand, the rapidity of the current in floods being
such that it would let fall little lighter sediment, even above an
obstruction like a dam. The quantity I have mentioned evidently
bears a very inconsiderable proportion to the total erosion of the
stream during that period, because the wash of the banks consists
chiefly of fine earth rather than of sand, and after the pond was once

STATEMENT BY MR MARSH, 235

filled, or nearly so, even this materiai coula no longer be deposited in
it. The fact of the complete removal of the deposit I have described
between the two dams in a single freshet, shows that, in spite of con-
siderable obstruction from roughness of bed, large quantities of sand
may be taken up and carried off by streams of no great rapidity of
inclination ; for the whole descent of the bed of the river between
the two dams—a distance of four miles—is but sixty feet, or fifteen
feet to the mile.

“‘ The facts which I have adduced may aid us in forming an idea of
the origin and mode of transportation of the prodigious deposits at
the mouth of great rivers like the Mississippi, the Nile, the Ganges,
and the Hoang-Ho, the delta of which last river, composed entirely of
river sediment, has a superficial extent of not less than 96,500 square
miles, But we shall obtain a clearer conception of the character of
this important geographical process by measuring, more in detail, the
mass of earth and rock which a well-known river and its tributaries
have washed from the mountains and transported to the plains or the
sea, within the historic period.”

The whole process of the disintegrating effects of the Po Mr Marsh
then details with clearness, and concludes :—“ Upon the whole, we
shall not greatly err if we assume that, for a period of not less than
two thousand years, the walls of the basin of the Po—the Italian
slope of the Alps, and the northern and north-eastern declivities of
the Apennines—have annually sent down into the lakes, the plains,
and the Adriatic, not less than 375,000,000 cubic yards of earth and
disintegrated rock. We have, then, an aggregate of 750,000,000,000
cubic yards of such material, which, allowing to the mountain surface
in question an area of 50,000,000,000 square yards, would cover the
whole to the depth of fifteen yards. There are very large portions
of this area, where, as we know from ancient remains—roads,
bridges, and the like—from other direct testimony, and from geo-
logical considerations, very little degradation has taken place within
twenty centuries, and hence the quantity to be assigned to localities
where the destructive causes have been most active is increased in
proportion.

“Tf this vast mass of pulverized rock and earth were restored to
the localities from which it was derived, it certainly would not
obliterate valleys and gorges hollowed out by great geological causes,
but it would reduce the length and diminish the depth of ravines of
later formation, modify the inclination of their walls, reclothe with
earth many bare mountain ridges, essentially change the line of

236 ACTION OF FORESTS ON THE FLOW OF RIVERS.

junction bétween plain and mountain, and carry back.a long reach
of the Adriatic coast many miles to the west.

“Tt is, indeed, not to be supposed that all the degradation of the
mountains is due to the destruction of the forests—that the flanks of
every Alpine valley in Central Europe below the snow-line were once
covered with earth and green with woods, but there are not many
particular cases in which we can, with certainty, or even with strong
probability, affirm the contrary.”

There is thus brought under consideration a secondary effect of
trees ih arresting the flow and escape of the rainfall, and so to some
extent equalizing the flow of rivers. How this is affected next
demands our attention.

As the evaporation, to which attention has been called, may be
considered as only a continuation of evaporation, begun so soon as
the rain-drop was formed in the atmosphere, so may the infiltration
and ruissellement be considered as only a continuation of the descent
by which, under the influence of gravitation, it fell ; but it is effected
under differént conditions, and it presents different phenomena.

So soon as it falls part is absorbed by the hydroscopicity of the
soil, more, it may be, escapes by infiltration through the soil, and the
remainder flows over the surface to a lower level.

It may have been observed that on the footpath, or the rock, it
accumulates in pools, but not on the grass or turf of herbage, or field
of corn ; and on the bare ground, it may be seen flowing off in runnels ;
but on the grassy turf the phenomenon is somewhat different. Even
on the declivity of a knoll, or on the declivity of a mountain side,
the grass arrests, divides and subdivides, and so retains the super-
ficial flow of the superabundant rainfall. In accordance with this is
the action of forests thereon.

The establishment of this fact has followed the study of the natural
history of Alpine torrents. In some of these the whole rainfall in a
mountain basin, rushing off impetuously to the sea, and undermining
the banks of its channel, carried off the detritus, and buried there-
with, it may be, fertile lands, and villages and towns beyond. The
destructive effects thus produced in France called attention to the
subject nearly a century ago, and in 1793 there was published by M.
Fabre, a civil engineer, Hssaz sur la theorie des Torrents et des Riviers,
in which he alleges that the destruction of forests in the mountains,
and the uprooting of their stumps, had been the primary and the
secondary causes of thé formation of these torrents, and had thus been

STATEMENT BY M. SURELL. 237

the occasion of all the disasters accompanying or following these
torrents ; and he urged the abandonment or regulation of these pro-
ceedings, and the reboisement of the mountains, as means of arresting
and counteracting the evil.

The commotions occasioned by the revolution prevented full effect
being given to these views at that time, but some fifty years later a
work was published by M. Alex. Surell, entitled Etude sur les Torrents
des Hautes Alpes, in which similar and more extended views of the
subject were advanced. This work was crowned by the Academy of
Sciences ; and it led to the commencement of extensive works of re-
boisement on the mountains of France. These have been prosecuted
with energy and success at great expense, but ungrudgingly,—the
result having proved corroborative of the principles upon which they
were undertaken. It is only as illustrative of the soundness of the
views upon which these were founded that they are now referred to ;
and here I can only bring forward statements of these views and prin-
ciples, with a passing notice of results illustrative of their truth.

M. Surell says: ‘‘ When we examine the lands in the midst of which
are scattered the torrents of recent origin, we see them to be in every
case stripped of trees and of every kind of arborescent vegetation.
On the other hand, when we look at mountain slopes which have been
recently stripped of woods, we see them to have been gnawed away
by innumerable torrents of the third class, which evidently can only
have been formed in later years.

“‘See then a very remarkable double fact : everywhere where there
are recent torrents there are no more forests: and wherever the soil
has been stripped of wood recent torrents have been formed ; so that
the same eyes which have seen the forest felled on the slope of a
mountain have there seen incontinently a multitude of torrents.”

And again, “‘In examining the basins drained by great extinct
torrents, there are almost always found there forests, and often dense
forests. There may be observed also, along wooded revers, a number
of small torrents of the third class, which appear as stifled under the
mass of vegetation, and are completely extinct. Now this second
observation, which can be verified by a multitude of examples,
supplies a demonstration of a fact of which the first only permitted
us to entertain a suspicion in a vague way :—it is, that the forests
are capable of bringing about the extinction of a torrent already
formed. Indeed, it is impossible to admit that the small torrents,
dug for the most part in mobile and friable ground, can have died of

238 ACTION OF FORESTS ON THE FLOW OF RIVERS.

themselves, so to speak, in their very birth, and through the effect
alone of that equilibrium to which reference has already been made.

“Stability cannot establish itself so speedily on beds which are
scarcely formed, and in the midst of lands which offer still so much
food for erosion by the waters ; it is a work which demands time, and
which is never entirely consummated until the mountain has been
gnawed away to the quick, to its last ridge.

“Amongst the great number of extinct torrents, of which the
basins are wooded, there are some, the forests of which have been
subjected to the commune régume, and have fallen in part under the
axe of the inhabitants. Very well, the result of this destruction of
trees has been to rekindle the violence of the torrents, which only
slumbered. There have been seen thus peaceful streams give place
to furious torrents, which the fall of the wood had re-awakened from
their long sleep, and which vomited forth new masses of déjection on
beds of deposit, which had been cultivated without suspicion from
time immemorial. This is what has been remarked more especially
after the excessive destruction of woods which followed the first years
of the Revolution ; the devastations of many great torrents only date
from this epoch.”

And once more, “ This last fact completes all that need be said in
regard to the influence of forests. In seeming these show themselves
almost everywhere on the body of extinct torrents, one may suppose
that these had first died, and that the woods had then seized upon
them when the extinction had been completed, and when the soil of
the neighbourhood became stable, permitted vegetation to develop
itself in safety: the forest would then only have been one of the
effects of the extinction of these, instead of being the cause of it.
But then the destruction of the woods would only have restored
things to their primitive state, and the torrents ought to have been
able to continue extinct after the taking away of the woods as it was
before their appearance there—and this is exactly what does not
happen. It has sufficed to clear away the woods to see the devasta-
tions immediately reappear. It must be then the forests which, by
their permanent appearance on the soil, hindered the devastations,
and it is the forests, in taking possession of the soil, which have
caused them to cease—and the extinction of the torrents is so com-
pletely their work that it begins, continues, and disappears with
them, the effect ceasing immediately with the cause.

“ One sees by this that the action of forests is not confined to pre-
venting the creation of new torrents, but that it is sufficiently

STATEMENT BY M. SURELL. 239°

energetic to destroy torrents already formed. One sees also that the
injurious result of the removal of woods is not only to open every
where the soil to new torrents, but that it augments the violence of
those which exist, and resuscitates those which appear completely
extinct. We may then sum up the influence which forests exercise
on torrents already formed on two facts, parallel to those which sum
up their influence on lands where the torrents have not yet appeared.
(1.) The presence of a forest on a soil prevents the formation of a
torrent there. (2.) The destruction of forests leaves them subject to
become the prey of torrents. Nor is there in this any thing for
which we may find it difficult to account.”

He proceeds then to explain the modus operandi whereby forests
produce such effects : “ When the trees fix themselves in the soil the
roots consolidate this, interlacing it with a thousand fibres; their
branches protect it, as would a buckler, againet the shock of the
heavy rains; and their trunks, and at the same time suckers,
brambles, and that multitude of shrubs of all kinds which grow at
their base, oppose additional obstacles to the currents which would
tend to wash it away. The effect of all this vegetation is thus to
cover the soil, in its nature mobile, with an envelope more solid and
less liable to be washed away. Besides, it divides the currents and
disperses them over the whole surface of the ground, which keeps
them from going off in a body in the lines of the thalweg and meet-
ing there, which would be the case if they flowed freely over the
smooth surface of a denuded ground. Finally, it absorbs a portion
of the water which is imbibed in the spongy humus, and so far it
diminishes the sum of the washing away forces.

“Tt follows from this that a forest, in establishing itself on a
mountain, actually modifies the surface of the ground, which alone is
in contact with atmospheric agents, and all the conditions find them-
selves then modified as they would be if a primitive formation had
been substituted for a formation totally different. Whence it is not
more astonishing to see the same soil alternately cut up or free from
torrents, according as it is despoiled or clothed with forests, than it
is astonishing to see torrents cease when we come to primitive
formations, or reappear suddenly on friable limestone.

“Tn accordance with this we find—first, the development of forests
brings about the extinction of torrents ; second, the destruction ot
forests redoubles the violence of torrents, and may even cause them
to reappear. And nothing is more easy than to explain these new
actions. It will be remembered what are the causes which call forth

240 ACTION OF FORESTS ON THE FLOW OF RIVERS.

and maintain the violence of torrents : it is, on one hand, the friability
of the soil ; and, on the other, the sudden concentration of a great
mass of water. Now, we know already that the forests render the
soil less liable to be washed away ; we know also that they absorb
and retain a portion of the rainfall, and prevent instantaneous con-
centration of the portion which they do not absorb. Consequently
they destroy both the one and the other cause. They prolong the
duration of the flow, and they render the floods at once more pro-
longed, less sudden, and less destructive.

“Tt may be understood from this how forests, in invading the
bassins de réception, may have contributed powerfully to stifle certain
torrents. Whilst the waters were creating for themselves the most
convenient slopes, the forests were retaining the soil which was ready
to go, were rendering it more solid, were consequently diminishing
the mass of earth washed away, and above all were opposing them-
selves to the concentration of currents. They were augmenting all
the resisting, all the existing obstacles, and were diminishing all the
motive powers ; and they were coming thus to hasten by a double
efficacy that epoch of stability in which the force of the waters would
find itself in equilibrium with the resistance of the soil. There is
one circumstance which ought to render their triumph still more
speedy,—it is, that the torrent, in proportion as it is enfeebled,
abandons to them a soil more and more stable and favourable to
vegetation, in such a way that this augments every day their forces
in proportion as the torrent loses force. In fact, if the expression
may be allowed, it is reinforced by the effect.

‘By this I do not mean to say that the torrents can never become
extinct of themselves. That would be in contradiction to what I have
said, and at the same time to facts observed, for there are examples
of torrents being extinguished without the presence of forests, and
solely through the erosion of the mountains—as, for instance, the
torrent of Saint Joseph, near Monestier. But I say that the forests
expedite the accomplishment of this effect, and that they can produce
it where the other circumstances are not yet producing it.

“ Thus nature, in summoning forests to the mountains, places the
remedy side by side with the evil, She combats the active forces of
the waters ; to the invasions of the torrents she opposes the aggressive
conquests of vegetation. On those mobile revers she spreads a solid
layer which protects them against external attack, somewhat in the
manner that a facing of stone protects an earthen embankment. It
is worthy of remark that the little cohesion of limestones, which is

STATEMENT BY M. SURELL. 241

opposed to the fixing of grounds, which renders them so mobile, and
draws torrents thither, is precisely the quality which renders them
favourable to the development of vegetation. The same cause which
multiplies the torrents ought then to multiply also the robust forests,
and to cause productiveness succeed in the long run to barrenness,
and stability to disorder; not that, strictly speaking, there can be
in nature ariything otherwise than orderly, for there is nothing which
is not subject to the rule of immutable laws, but in popular phrase
the term disorder has also its meaning.

“ One is struck with the illustrations of the observation which has
just been made in going over certain forests in these mountains. One
sees the vegetation doubling its profusion and energy in grounds torn
by ravines, and crumbling on all hands, as if it were mustering its
last efforts to retain a soil escaping from it. To cite one example:
in the forest of Boscodon may be seen the vigour and tenacity of the
vegetation contending against a friable soil composed of schist, tufa,
and gypsum, It is, in fact, the lands which are the most mobile
which are at the same time the most fertile, and the hard rocks on
which vegetation has no hold, brave also the effort put forth by all
the causes of destruction. The mountains, if they were abandoned
quite naked to external influence, would soon be levelled or cut up
into bits, and they would offer to man nothing but a heap of cleft
rocks, uncultivated and uninhabited.

“Tt is vegetation which prevents this ruin ; and as there can be no
vegetation without water, it is on the mountains that nature has poured
out the water in the greatest profusion. We have already called
attention to the remark, that there falls more rain on the mountains
than on the plains. The mountains attract and retain the clouds [1].
Snows and glaciers crown their summits as immense reservoirs, whence
trickles out a perpetual moisture, and whence flow innumerable
streamlets which fertilize their sides, and distribute fertility, from
brow to brow, down to the very depth of the valleys. Thus, the
waters which are the most energetic means of destroying the soil are
at the same time the most active in its conservation. In drawing on
vegetation, they preserve the soil against their own attacks, and the
more they have of power to destroy, the more vegetation they cause
to spring up to preserve. It is in this way that nature imposes on
all her forces moderators which counterbalance them and keep them
from acting always in the same way ; and this must end in bringing
everything to a state of restored peace.”

After dwelling on the thought of self-adjusting aed for the

c

242 ACTION OF FORESTS ON THE FLOW OF RIVERS.

natural extinction of torrents, he, in something like a burst of en-
thusiasm, gives expression to his feelings in view of the thorough
and efficient way in which torrents had naturally become extinct, and
of the contrast thus presented to the puny endeavours of man to
restrain their ravages: the natural and the artificial; God’s way of
doing it, and man’s way of doing ; the work of God and the work of
man; and the results: success, perfect and complete ; and success,
partial and imperfect ! ‘

“Tet us go back for a moment,” says he, “and compare these
effects of vegetation with those exercised by the different systems of
defence hitherto devised. The result of defences like that of vegetation
is to arrest the ravages of torrents; and how powerless appear all
embankments by the side of those great and powerful means which
nature employs when man ceases to oppose her, and when she patiently
prosecutes her work throughout a long series of ages! All our paltry
works are nothing but defences, as their name indicates ; they do not
diminish the destructive action of the waters, they only keep it from
spreading beyond a certain boundary. They are passive masses
opposed to active forces; obstacles, inert and decaying, opposed to
living powers, which always attack, and which never decay. Herein
is seen all the superiority of nature, and the nothingness of the artifices
devised by man.

“‘T make not here a barren comparison. I wish to let it be seen
that it is better to bridle the torrents than to erect at great expense
masonries and earth-works, which will always be, whatever may be
done, expensive palliatives, better adapted to conceal the plague than
to eradicate it. Why then does not man ask assistance of those new
powers, the energy and efficacy of which are so clearly revealed to
him? Why does he not command them to do yet again, and that
under the directions of his own genius, that which they have already
done in times long gone by on so many extinct torrents, and that
under the prompting of nature alone 2”

In 1872 a sequel to this work by M. Surell was published by M.
Cézanne, Ingeneur des Ponts et Chausées, Representant des Hautes
Alpes GU Assemble Nationale. Referring to the phenomena of torrents
brought under review in that work by M. Surell, and in the Sequel
supplied by himself, M. Cézanne says :—

“There may be given in a few words a résumé of the whole series
of these phenomena.

“The mountains are the result of a series of upheavals following

STATEMENT BY M. CEZANNE. 243

one upon another in the same region. A final agitation gave to the
different chains of these the existing elevation; it elevated the
summit and opened up deep fissures or divisions, which have become
the valleys of the present time. From the time this occurred the
waters began to fashion the ¢halwegs, following the line which best
suited them; wearing down outlets and filling up basins. It is
necessary to admit, or to assume, that the depth or thickness of the
alluvial deposits in the bottom of certain valleys—for instance, those
of the Isére in the Graisivaudan, or of the Rhine in Alsace,—is to be
reckoned by hundreds, and perhaps by thousands, of métres or yards ;
for even yet certain lakes existing in depressions of the Alps have
their bottom below the level of the sea.

“ After a long series of ages the mountains assumed the leading
features which they now exhibit, when, the climate changing, great
glaciers carried on actively the work of erosion; these have planed
away escarpments, and fashioned into something like horizontal lines
the rocky belts of the valleys.

“ Débdeles, or inundations, from the escape of the waters of pent-up
lakes, and deluges resulting from the tremendous rains of summers on
the extensive fields of ice, have carried away and deposited in the
principal valleys in certain favourable places, but more especially at
the débouchés of lateral gorges, the masses of loess which have
formed cones in the higher plains, and in which the water-courses
have subsequently dug out the secondary valleys.

“At a later period, after the melting away of those glaciers, the
torrents seized upon the bared mountains; and without restraint
they have dug out their basins, and have again taken up the materials
disintegrated by the glaciers, and deposited these in the gigantic
cones which give to certain regions a physiognomy peculiarly their
own

“But after a time the forests, spreading by degrees, stifled the
waters under a mantle of verdure; the torrents became extinct,—an
era of peace and of comparative quiet supervened in the mountains ;
then the tribes of men, who during the glacial period rambled over
the low-lying plains, in company with the reindeer, the aurochs, and
the bears, began to spread themselves in the high-lying valleys. The
most ancient settlements were made at the gorges of the torrents,
towards the summit of the cone; in point of fact, there are to be
found in the mountain valleys very few of these gorges in which we
do nut meet either with an existing village or with an ancient ruin.

“In this location, which was then one favourable to their pursuits,

244 AOTION OF FORESTS ON THH FLOW OF RIVERS.

the primary inhabitants could profit by the exceptional fertility of
the cone of deposits; they had nothing to fear from the principal
river, which flowed through the lower-lying lands, nor from jthe
torrent, which was then extinct ; they commanded the plain, and
found themselves at the gate of the mountains; the adjacent gorge
supplied them with water, the forest supplied them with wood, the
rock supplied them with stone, and their flocks spread themselves
over the verdant ridges around them.

“ Little by little, a reckless use of the forests and of the pasturage
disturbed the equilibrium of the natural forces ; and now the old sore
is re-opened, and anew, by man’s deed, the mountains are inoculated
with the leprosy of the torrents. The evil has gone on increasing
during prolonged ages of disorder and recklessness ; the position of
the cultivated grounds, and of the villages established at the débouché
of the torrents, has now become critical in the extreme ; and unless
we go back, as we have done; to the olden times, we are unable to
account for men having taken up their dwelling in the spots, of all
others, which at this day appear to be those which are more
immediately threatened. ,

“But at last an era of reparation begins ; and, thanks to the eminent
men who have in byegone years given their mind to the work, the
next generation may hope to see the final decline of the modern re-
newed Torrential Era,”

In 1874 was published Les Torrents leur lois, leur causes, leur effets:
Moyens de les rveprimeur et de les utiliser: leur action geologique
unwverselle, par Michel Costa de Bastelica, Conservateur des Hawa et
Foréts.

This work treats of another aspect or of another department of the
subject than any discussed in the treatises already mentioned, which
the author designates,—Le phénoméne torrentiel, or la torrentialité ;
and thus is opened up another chapter of the natural history of
torrents.

In speaking of the good done by forests on the face of moun-
tains forming a basin drained by water-courses, he says their bene-
ficial action is manifold; and though this manifold action it may
be difficult to unfold, the attempt to do this will place beyond all
question that their beneficial action on the water-course is at once
most marked and considerable.

“In the discussions which have taken place on this subject,” says
he, “the point which has engrossed attention to some extent has

HTATEMENT BY M. COSTA DE BASTBLIGA, 245

been almost exclusively the permeability or impermeability of the
soil, and the proportion borne by the water absorbed to that which
flows off. This is certainly an important question, and no difficulty
is found in showing that forests diminish to an enormous extent the
amount of water which flows away; but the service which they
render is perhaps greater stiJl in regulating, as they do, the flow, and
in securing the delivery of only water of perfect fluidity.

“The study of torrents has shown that the evil done consists not
so much in the greater or less volume of water discharged as in the
disturbances or perturbations of the flow connected with this. The
principal causes of these are sudden changes or variations in the
delivery and in the degree of fluidity of the flood. And if it be
shown that the forests have, in relation to both of these, a regulating
power superior to that of any other force operating on the torrent,
it will be proved that they are the most potent means of extinguish-
ing torrents.

“Tf we could expose, by a vertical section, a wooded slope, it would
show in the upper portion a layer of varying thickness, but most
frequently of from 30 to 40 centimétres (12 or 15 inches) of humus
in which the fibrous rootlets are so developed that the whole has the
appearance of a woolly material. This layer is at once a sponge and
a filter. The large roots of the trees penetrate more or less into the
subjacent rock.

“When the rain falls on ground covered with wood a considerable
portion of the water is restored to the atmosphere by evaporation ;
another portion is absorbed by the immense expansion of foliage and
boughs. If the rain be prolonged the water comes at length to the
ground, which again is capable of absorbing an immense quantity.
A flow from this is slow to establish itself; it is necessary, first that
the saturation of the sponge-like layer be complete ; and when this
is effected—when the water has been able to make a passage for it-
self by an infinite number of imperceptible channels—the flow, like
that of a charged syphon, maintains a certain uniformity of flow, and
this it continues for a long time after the rain has ceased.

“So much is this the case that opponents have alleged that forests
are more hurtful than beneficial, as they tend to prolong floods. The
flood is prolonged, it is true, but the delivery is regulated—diminished
at the commencement and increased at the close: the total quantity
of water drained away takes a longer time to flow ; it flows during the
whole of that longer time ; and, what is of more importance, it flows
uniformly and equally, with no sudden variations, and thereby much

246 ACTION OF FORESTS ON THE FLOW OF RIVERS.

evil is avoided ; and, what is of more importance still, the forest acts
at the same time as a filter, delivers no water but what is of perfect
fluidity, scarcely even discoloured by the washing away of organic
matter, and unable to wash away the earth of the subsoil protected
against erosion by its thick covering of humus.

“« When, on the contrary, the rain falls on a soil stript of vegetation,
it tends to cut this up into ravines, and it does so if the tenacity and
resistance of the ground be not sufficient to withstand it ; and the
flood is subject to great variations in its current, carrying off, here
and there the earth and other debris of the soil.

“Forests have, then, a double action ; on the one hand they
consolidate the soil, on the other hand they reduce and regulate the
flow of the current,—acting at once both on the delivery and on the
perturbation,—in other words, on the primary cause and on the
secondary causes of the overflowing of water-courses.

“Tt has been tried to subject to experiment and observation the
meteorological and hydrological effects of forests. And doubtless
studies so interesting are by no means lost to science. They cannot
be too much encouraged ; but it should be borne in mind that they
can have comparatively little value in this question, seeing that they
cannot take cognisance of this modulating and regulating action.

“Tn regard to any flood which we may wish to make the subject of
study, it would avail comparatively little to know what quantity of
rain falls annually in the basin drained by it. What is necessary to
be known is—In what way did the flow of the flood operate during
the duration of the flood, taking into account the quantity of water
discharged, and all the causes or sources of perturbation operating—
which is a much more difficult problem.

“ And in resolving the whole qnestion into the permeability of the
soil, and its capacity of absorption, it appears importance is attached
exclusively to the reduction of the volume of water which flows
away. It seems to be forgotten in this that water-courses, if steadily
supplied, constitute it may be said the principal riches of a country,
and the most potent of all instruments of labour.

“ By their modulating power forests act as vast reservoirs, not only
in preventing sudden variations of delivery during a flood, but in
feeding the water-courses and raising their level during the period of
exLaustion. In what relates specially to the torrents of the Alps
it has been demonstrated that the renewed devastating power which
they have exhibited, and which has assumed such portentous magni-
tude in the course of the last forty years is a consequence of the dis-

STATEMENT BY M. COSTA DE BASTELICA.. 247

appearance of the woods. When one goes over these lands—cut into
ravines and despoiled of all vegetation—he meets with numerous
stumps of pine and of larch, which testify that at a period as yet still
recent they were covered by vast forests.

“M. Surell cites, as an example of the action of forests, the torrent
of Savines, now completely extinguished, and the basin of which is
everywhere adorned with a magnificent forest of firs and pines. The
forest has effectively contributed to the extinction of the torreut, but
at this point the following observations may be made :

“This natural extinction of the torrent goes back to ages most
remote. The cone is of a perfect geometric regularity. At its base,
opposite the Durance, it presents a troncature or section, produced by
the erosion of the river, and the escarpment of which is about 30
métres (100 feet) in height at its culminating point. This section
of the ground lays open the interior of the torrential deposit formed
of rolled pebbles.

“The whole surface of the cone is cultivated, and on one portion
has been built the large village of Savines, the chief place of the
canton,

“This enormous heap of deposit is situated at the foot of a high
mountain called Morgon, in the flanks of which are dug out a pro-
found gorge surrounded by a vast basin, the work of the water. All
the upper slopes of the mountain are hung with a beautiful forest,
producing firs more than 30 métres (100 feet) in height, and 3 métres
(10 feet) in girth.

The lower slopes are deeply ravined, but wooded to the very edge
of the thalwegs. A pretty strong stream rises from the principal gorge,
but it swells but little ; it carries down no material, and it flows into
the Durance by a bed deeply enclosed in the left bank of the cone.
Extinction and stability are complete ; but it is certain that if the
forest should be made to disappear, anew would disorder revive, and
this with the same intensity as before.

“In going over the basin with attention, I satisfied myself that
everywhere the bed of the thalwegs of the gorges and the ravines,
formed of the hard rock, were absolutely incapable of being under-
mined, From this it may be inferred, that during the activity of the
torrent, when the basin was being deepened. more and more, the sur-
face could not have been wooded. But from the time that the waters
had everywhere reached the hard rock, and that they could no more
be undermined and washed deeper, their thalwegs in the upper slopes
tended to consolidate themselves, taking their natural stable declivity ;

248 ACTION OF FORESTS ON THE FLOW OF RIVERS.

and from that time vegetation could begin to take hold and complete
the extinction.

“ This remark is important in this way, that if the disappearance
of a forest always gives birth to torrential disturbances, it does not
always hold true that one can put a stop to them by the planting of
a forest alone.

“Much as an unstable ground is protected by being wooded—
though it maintains itself and behaves, in a hydrological point of
view, as do the most solid lands, if the wood come to disappear, if
the ground be deeply ravined, if the bottom of the ravine continues
to be easily undermined and washed away—it becomes extremely
difficult to establish vegetation on the mountains, which continually
crumble away, and which with this instability no longer retain any
trace of vegetable soil.

“Tn the Alps there are numerous cases of old mountains which
crumble away when the foot of the slope is undermined by the water.
And one is thus left, if he desire to effect a radical and prompt ex-
tinction of a torrent, to give, artificially, to the bottom of the ravine
a power of resistance to undermining and washing away, by appro-
priate works of consolidation.

“But be this as it may, the potent action of forests is beyond all
question. Whatever be the character of the woods—timber forests,
coppice-wood, or simple shrubbery—all contribute to give firmness to
the soil, to retard and to regulate the flow of the water drained off.

“Tn comparing the different kinds of woods, it may be said that
lofty timber forests, with their vast apparatus of foliage at a great
elevation above the soil, are of most use with a view to meteorological
and hydrological effects ; and that young trees serve perhaps better
to insure the consolidation of the soil on steep declivities. But as
generally, on poor land, the soil of timber forests covers itself with
branches, é&c., it follows that a mixture of the two kinds of woods
accomplishes best the end which it is sought to effect.”

He speaks with similar explicitness in regard to the effect of
gazonnement; and in reference to artificial structures other than
those which he advocated, he remarks: “MM. Scipion Gras et
Phillipe Breton have also loudly proclaimed, in a way the most
explicit, that the boisement of the valley appeared to them the most
efficacious measure which could be adopted against torrents, and that
it was only in default of proceedings with a view to extinction being
adopted—the application of which, when they wrote, was still
surrounded with obscurity and uncertainty—that they proposed the

STATEMENT BY M. MARCHAND. 249

measures they did, as means of diminishing, at least provisionally,

the danger. The torrents in the Alps which have given occasion for
the study of these phenomena owe their origin to the melting of snow ~
on higher lying mountains in summer, and to oragés, or tremendous

storms of rain, which fall in spring. These torrents occasioned by the

latter are generally the most destructive.

“M. L. Marchand, Garde General des Foréts, says on this
subject, —“ When the torrential rains of the Alps are made a subject
of study it is soon seen that they are all of them occasioned by a
particular wind called the fahn. These winds are generally violent,
and present almost always the character of orages, or storms of rain;
it follows that great quautities of rain are poured down upon the soil ;
and to this may be attributed disasters sometimes coming upon spots
which seemed to be placed in the best possible situation and circum-
stances to bear the most persistent rains.

“The fehn is a wind which blows from the south, often with
extraordinary force ; it.is peculiar to the Alps, and is felt throughout
their whole extent. Having climbed over Italy, where it is no other
than the szrocco, the following are its chief characteristics :—It comes
from the south, but its direction is modified at every step, either by
mountain chains or by valleys. Its origin is still a subject of
discussion: according to some it originates in the Sahara, according
to others it originates in the Gulf of Mexico. It gives to the sky a
strangely-marked, peculiar, heavy, whitish aspect ; and the rain falls
on the second or third day following its appearance.

‘The wind arrives on the Mediterranean coast loaded with vapour;
it there encounters that immense calcareous semi-circular wall of the
Maritime Alps, and it scales their higher slopes; but in consequence
of their covering of forests, and the great heat concentrated by them,
in doing so it only attains a higher temperature. It is rarely the
case that the moisture is condensed or precipitated on these countries
which it rapidly traverses ; but it cools by degrees as it mounts the
Maritime Alps, and on reaching the upper basin of the Var and its
affluents it deposits an enormous quantity of water; then it continues
to advance northwards to French Comté, before reaching which
latitude it has lost much of its force.

“If a glance be cast over a map of the Southern Alps, it may be
observed that from mount Viso there part off great chains running
perceptibly-from east to west ; the fwhn comes up the valleys of the
basin of the Var, or of the upper sources of the Durance, it strikes

upon the first chain parting from the col of the Pas-de-la-Cavale, or of
2D

250 ACTION OF FORESTS ON THE FLOW OF RIVERS.

the Grandes-Communes, taking a deviation to the north of Digne. It
is against this chain that the first great storms of rain dash them-
selves. The clouds in passing over these mountains seek the cols or
lower parts, and they arrive in the valley of the Ubaye by the openings
of Grande-Commune, of Enohastrayes, of the Cold’Allos, of the Lawergq,
of the Bas, and in fine, by the great passage of the mountains of the
Seyne.

“The fahn forces a passage for itself into the valley of the
Durance ; goes up this throughout its whole length ; it makes its way
also by some cols of the chains which separate this valley from that
of the Ubaye, and more especially by those which are opposite Embrun.

“‘ Tf now the forest chart of the country spoken of and the chart of
the feehn be compared, it will be seen that the mountains of Seyne
have been cleared of woods, and that the whole southern upper slope
of the valley of the Ubaye is devoid of forests; in a word, that all
the parts which bear the direct attacks of the fwehn—those which
arrest it—force it to ascend them, and to pour upon them masses of
water, are all of them almost entirely cleared of woods. Here we
have no longer, as is the case above Menton, a tropical sun to warm
the soil; the wind has cooled down as it rose higher from the sea,
and it is obliged with fatal effect to precipitate in the form of rain the
moisture it has borne thither ; and at that place where the forests
are an absolute necessity, and where the most considerable quantities
of water fall, there it is that they have completely disappeared.

“This summary is incomplete, but it may suffice to render intelli-
gible the general course of the orages, or storms of rain in the Alps,
and the intensity of these on certain parts, which are generally those
at which the fahn is compelled to rise considerably or to change its
direction. The celebrated torrent of Riou-Bordous, near Barcelonette,
in face of the opening at Allos, is exactly so situated. The portion of
the Alps situated below the department of the Istre almost completely
relieves the fohn of its humidity, and this is the classic region of the
orages.

“The fehn does not confine itself to the production of torrential
rains ; it is not less terrible in its action on the snow, and on the
glaciers. As has been stated, it blows sluggishly and warm for one,
two, or three days before the rain appears ; if at this time the ground
be covered with snow this is not slow to melt rapidly, and absorbing
a great quantity of water it becomes like a sponge ; then supervenes
the rain which expedites the process and brings on a kind of débéele,
or breaking up, and the water arrives in great quantities in the

STATEMENT BY M, MARCHAND. 251

valleys. If the rain do not supervene the action of the fehn may
suffice to cause all the snow to melt aud to produce great consequent
disasters. In 1856 the inundations of the valley of Barcelonette had
no other cause of production ; the maximum of the flood was attained
under a magnificent sky, and all the water came from the melting of
the snow which covered the mountam. In Switzerland the terrible
inundations of 1868 had in general a double origin—with warm con-
tinuous rains were combined the melting of the glaciers. Itis always
in the spring, or with the first snows of October, that the latter
torrents are to be dreaded if the mountains be not covered with
glaciers ; where this is the case the danver is constant.

“The fehn sometimes produces general rains over the whole of
the country over which it blows, but sometimes only local orages, or
storms of rain. This can easily be accounted for when itis considered
that the contour of the Alps admits of one current of air passing up
a valley to be in its cause and in its effects quite independent of a
current passing up a neighbouring valley, though they have had a
common origin,—and that a difference in the cooling of the currents
of air may occasion a precipitation of rain in one valley, while the
neighbouring valleys, being warmer, are enjoying a cloudless sky.”

When the late Emperor Napoleon came to power he took steps to
give effect to the observations and reasonings of MM. Fabre and
Surell, which the pre-occupation of public men with political changes
had previously prevented.

In 1860 the work of reboisement was begun. To the report given
by the Director-General of the Administration of Forests, of what had
been done in 1867-1868, are appended a number of monographs on
works executed in different departments, embracing the departments
of the Isére, the High Alps, the Low Alps, Dréme, Gard, Hérault,
Aude, and the High Pyrenees, all telling of success.

Amongst others, of which details are given of what had been
done, and of what results had followed, is mentioned the case of the
torrent of Saint Marthé, on the right bank of the Durance. Of this
M. Costa de Bastelica, in a work already cited, remarks :—‘ This
torrent supplies amongst many others a remarkable example of what
can be done. In 1841, when M. Surell wrote his valuable work, this
torrent had a sad celebrity for its violence. It swept away every
bridge thrown across its course. On every occasion of a storm of
rain the inhabitants of the banks of the river were thrown into dis-
quietude, fearing to see it burst their dykes, and spread over the plain.

252 ACTION OF FORESTS ON THE FLOW OF RIVERS.

“The works undertaken with a view to secure its extinction were
only begun in 1864, and in 1869, when M. Cézanne, before the
publication of his work, did me the honour to allow me to show to
him and explain our works, he noted the fact that the work of ex-
tinction was so complete that a simple foot-bridge placed only 50
centimétres, or 20 inches, above the torrent, had become a work
that bade defiance to the greatest floods which now occur. This
foot-bridge still stands, and there have been no want of violent
storms of rain: in the interval there has been no change in the
meteoric conditions. The effect of the extinction of the torrentiality
was then attained and certain, and this so much so that the syndicate,
organised by the proprietors interested, having no longer anything to
do, dissolved itself.”

In accordance with this fact are facts innumerable illustrative of
the efficiency of vegetation in extinguishing torrents and preventing
the formation of torrential floods, by which disastrous inundations are
occasioned. Of these, as has been stated, details have been given in
a separate volume,* and with these details copious information in
regard to legislative measures and practical operations by which the
results in question were obtained, together with résumés of the works
which have now been cited, and notices of others which have been
published:on the subject.

In the conclusion of the volume there are remarks on the pre-
ventability by reboisement and gazonnement of such sudden and dis-
astrous inundations as that which in 1875 proved so destructive to
Toulouse and the valley of the Garonne.

A similar inundation of the Loire occurred in 1846. Ina valuable
work by M. Vallés, published in 1875, entitled “ Etude sur les in-
ondations lewr causes et lewrs effets,” the author denies the efficacy of
reboisement a8 a means of preventing inundations. But M. A. F.
Hericourt, in writing of this work in the Annales Forestieres for De-
cember 1857, in an article entitled Les cnondations et le livre de M.
Vallés, combats his views ; and he thus maintains his position that the
reboisement of a portion of the upper basin of the Loire would have
prevented the inundation of 1846 :—“ Accepting,” says he, “ the data
of M. Vallés, who has analysed with much care the various phenomena

* Reboisement in France; or, Records of the Replanting of the Alps, the Cevennes,
and the Pyrenees with trees, herbage, and bush, with a view to arresting and
preventing the destructive consequences and effects of Torrents. London: H. 8.
King & Co. 1876.

sTATEMENT BY M, HERICOURT. 253

which characterised the flood of October 1846, in the upper basin of
the Loire, I will admit with him that if we could have held back
175,000,000 cubic metres of water, the inundation which proved so
sad a calamity to France would not have proved so painful an
event. The upper basin of the Loire, as far as Roanne, comprises an
area of 640,000 hectares (158,080,000 acres), of which at least a
third, say 213,000 hectares (52,693,000 acres), might be profitably
re-forested. The inundation was caused by a rain which lasted sixty
hours, and poured upon the soil a sheet of water 153 millimetres (about
6 inches) indepth. This portion of the basin of the Loire, therefore,
received 979,200,000 cubic metres of water. On the hypothesis of
M. Vallés, 244,800,000 cubic metres were absorbed. There accord-
ingly remained for superficial fiow, +34,400,000 cubic metres.

‘But let us suppose that, in 1846, the 213,000 hectares above-
mentioned to have been covered with massive woods, and then let us
calculate what would have happened. These 213,000 metres would
have received, as theirshare, 290,000,000 cubic metres. The absorbent
qualities of the soil are increased 40 per cent. by reforesting, and this
operation would have withdrawn 130,116,000 cubic metres from the
superficial flow, which would have reduced the amount upon the re-
timbered portions to 195,174,000 cubic metres. But this liquid
mass would have been hindered in its course down the valley, as we
have above explained, by the passive resistances of every kind which
the forest presents, and a half, at least, would not have arrived until
after the other half, which had fallen in other portions of the basin,
had passed off. We may therefore conclude that the superficial
flow would not have exceeded 500,000,000 cubic metres, and that the
calamities occasioned by the inundation of 1846 would have been
completely prevented by reforesting.”

As rain is the precipitation from the air of a quantity of moisture
which it can no longer retain, so rivers are composed of the draining
off of a quantity of the rainfall which the ground upon which it has
fallen can uo longer retain ; and—while the flow and escape of the
rainfall is arrested by much of it being absorbed and retained by the
decaying debris of leaves and twigs lying on the surface of the
ground in a forest, and by the humus in the soil, and by being
carried to a great depth along the channels of the roots—a secondary
effect of this is to regulate, and, in doing so, to some extent to
equalise over a considerable time the continuous flow and delivery of
the streams and rivers by which it is drained.

a
254 ACTION OF FORESTS ON THE FLOW OF RIVERS.

In not a few of the statements which are given in preceding chap-
ters in regard to the effects of the destruction of forests, mention is
made of what had previously been pereanial streams being often dry,
while at other times the water-course was filled from bank to bank
with a rushing torrent. There might be as much water delivered by
these in the course of the year as ever there was—though this might
be questionable, and the observations cited by Herr Wex, and given
above, show that in some of the principal rivers of Europe a greatly
increased irregularity of flow has been accompanied by a diminished
annual delivery—but the flow was irregular, and the correction of
this is a consequence of the absorption referred to. Among the con-
sequences of this may be reckoned the following :—

1. The devastating and destructive effects of floods are mitigated, if
not altogether prevented. 2. The prolonged retention of the rainfall in
an inland situation increases both the moisture of the atmosphere
and of the soil, by prolonging the periods of evaporation and infiltra-
tion. 3. From both of these effects will follow other consequences
tending to perpetuate the results so obtained. 4. Not only will the
promotion of vegetation, desirable as an end, be accomplished, but
one of the meteorological effects of vegetation, the increased or
maintained humidity of the atmosphere, will be secured.

CHAPTER VI.

ON THE CORRESPONDENCE BETWEEN THE DISTRIBUTION OF THE RAINFALL

AND OF FORESTS.

As the student of Anatomy takes up now a muscle, now a nerve, now
an artery, and now a vein, and traces it by careful dissection from all
integuments and other structures with which it may be united, giving
to it for the time his undivided attention, and leaving for subsequent
consideration the connections and relations in which each stands to
each and each stand to all, so would I pass from the consideration of
one subject to the consideration of another, treating each as for the
time the one subject with which we have to do, and leaving for sub-
sequent consideration the various facts evolved in their combined
connections and relations.

It has been alleged that the distribution of forests corresponds to
some extent with the distribution of the rainfall. And this raises
the questions, Which is cause and which is effect? or are they both
consequences of a common cause? and in either case to what extent
may they be legitimately regarded as cause and effect ?

In Scottish courts of justice it is customary for the public prose-
cutor to lead evidence and then to state his case as founded on this,
while in English courts he states his case and then leads evidence to
establish it. I do not admit that I have got a case to establish ; but
JT shall state what my belief is, adduce observations in illustration of
different particulars, and then state what I consider to have been
proved.

Tt appears to me that observations made show in many gases a
general correspondence between the distribution of the two—that in
many cases the distribution of the rainfall has been determined in a
great measure by the geographical position and by the contour of the
country, and that this distribution of the rainfall may have determined
the distribution of the forests—but that the forests once established
may have exercised an important influence in further modifying the
distribution of the rainfall in time and in space.

256 DISTRIBUTION OF RAINFALL AND OF FOPESTS.

Sect. I.—On the Measure of Correspondence between the Distribution
of the Rainfall and of Forests.

I have said it appears to me that observations made show in many
cases a general correspondence in the distribution of the rainfall and
of forests. It may occur to many on the mention of this that while
there are found forests covering extensive plains, their special habitat
appears to be the mountain side—and that the rainfall in the vicinity
of a mountain range is in general greater than it is on the horizontal
area of an extensive plain.

But the correspondence is more marked than this alone would inti-
mate. It happens to be the case that, in some cases, the observations
have been given to the world by observers having decided views in
regard to the connection of cause and effect, and in illustration of
their views ; but at this stage they are adduced only as illustrative
of the measure of correspondence which has been observed.

The first observations I adduce are some brought before the Meet-
ing of the British Association for the Promotion of Science, held
at Brighton in 1867, by Dr Brandis, Superintendant-General of Forests
in India, in a paper On the Geographical Distribution of Forests in
India. Dr Brandis considering India as divided, by observation of
the rainfail, into arid, dry, and wet districts, stated that in the west
corner of India was what might be called the arid tract, extending
from the coast of Cutch and from Scinde in the south to the Salt
range in the north, and from the hills of Beloochistan in the west
to the Aravalli range in the east. The average rainfall in this
district was less than fifteen inches. Throughout this arid part of
India the spontaneous arborescent vegetation was extremely scanty,
although a thin sprinkling of low thorny scrub on the hills offered
ample and interesting employment to the botanist. In this region
the work of the forester was limited to those tracts which stretched
along the Indus and its principal tributaries, watered by the annual
overflow of the river during summer, or which could be otherwise
irrigated. Thus in Scinde there were on both sides of the Indus
river 352,000 acres of Government forest maintained solely by the
overflow of the river and by percolation. The result of the deflec-
tion of a river from its course was that the forest near the old bed
frequently perished.

Outside this arid tract there were two belts, with an annual
rainfall of between fifteen and thirty inches, which might be called

DISTRIBUTION OF RAINFALL IN INDIA. 257

the dry zones of India. The spontaneous arborescent vegetation was
scanty, save in the moist lands along the great rivers, but it was
better than in the arid tract. In the southern dry zone, comprising
part of the Deccan, was the country of the sandal wood, a small tree
which did not grow gregariously, and did not form continuous forests.
Here, too, were the ancient irrigation works, tanks, and gigantic
stone dams across rivers ; and where water was thus supplied, fields
and gardens were most luxuriant.

“ Beyond these dry zones, and in the rest of India generally, the
rainfall exceeded 30 inches; but even in these moister parts of the
country the conditions for forest vegetation were not everywhere as
favourable in India as in Europe. Really thriving forests were only
found where the fall exceeded 45 inches, and luxuriant vegetation
was limited to those belts which had a much higher rainfall. Within
the moist regions, with a rainfall exceeding 60 inches (in one place
rising to 250 inches) and in Eastern India, there was a great variety.
of good forest. Of the Deodar forests of the North-West Himalaya
a small portion only fell into this belt, the greater part lying in land
where the rainfall was less than 60 inches. Between the dry and
moist regions was a vast tract of country with an annual rainfall of
more than 30, but less than 60 inches, comprising the greater portion
of the upper Gangetic plain, the whole of Central India, and the
western side of the peninsula. In this part of India the main
obstacle to a luxuriant forest growth was not so much an in-
sufficient supply of moisture, as its unequal distribution over the
seasons of the year. Of the moist zones, there were two in which
the annual rain exceeded 75 inches, the smaller one along the
western coast of the peninsula, and the more extensive one on the
outer Himalaya ranges, the hills of Bengal, and the coasts of Burmah.

“On the western coast the rainfall was moderate as far down
as Surat, 47 inches, and Bombay had 72 inches; but Janna, only
a few miles inland, had 102. Further down the coast the rain-
fall was heavier, Rutnaghem had 115, and Canara had 123 inches.
Approaching the southern extremity of the peninsula, the rainfall
gradually diminished to 28 inches at Cape Comorin. In this narrow
moist belt were found some of the finest forests in India. The teak
forests of North Canara, protected by the difficult nature of the
country, the teak and blackwood forests of Wynaad and the
Anamallays and the forests of Travancore were reputable forests,
which might stand comparison with the oak and beech forests of the
Spessart, and the oak forests of Central France. The are planta-

258 RELATION OF FORESTS TO

tions of Nellumboor, in Malabar, which were commenced in 1844,
and now covered upwards of 2,400 acres, were a splendid instance of
luxuriant forest growth on a good soil, in a foreign climate, and
under good management. The moist region of the Himalaya and
the eastern part of India had a much larger extent. The Kangra
valley, in the Punjab, had a rainfall of 100 inches, and from here
the moist narrow belt, but widening gradually, ran in a south-westerly
direction as far as Sikkim. Near Simla, the width of this belt, with
a rainfall of 75 inches, was not more than 30 miles. Near Darjeel-
ing, it extended into and comprised the whole of Assam, Eastern
Bengal, as far as Dacca and British Burmah. A second belt of
between 60 and 75 miles, ran outside the foot of the Himalaya,
comprising the estuary of the Ganges and part of Orissa. Within
these moist regions of northern and eastern India, were a great
variety of good forests. Only a small portion of the deodar forests
of the north-west Himalaya fell within this belt, the greater part
lying inland, where the rainfall was less than sixty inches. The
india-rubber forests of Assam and Cachar were within the range of
the heavy rainfall as well as the ironwood forests of Arracan and the
teak forests of British Burmah,

“ Between the dry and moist belts there lay, as has been intimated
above, a vast tract of country with an annual rainfall varying
from thirty to sixty inches. In this part of India the main obstacle
to a luxuriant forest growth was not so much an insufficient supply
of mvistuce as its unequal distributions over the seasons of the year.
In the grenter portion there was a long dry season and a short rainy
season. During the dry season the leaves and grass get excessively
dry and inflammable, and the smallest spark was then sufficient to
create a conflagration, which did not stop until it had reached the
limits of the forest. These jungle-fires destroyed millions of seed-
lings, and those which escaped were scarred and had in them the
germs of early decay. The jungle-fires were sufficient to explain the
remarkable fact that, in a large proportion of the forests of Southern
and Central India, and in some of those of the north, the mature trees
were unsound or hollow.”

I could scarcely desire a better illustration of what I mean by a
general correspondence between the distribution of rainfall and of
forests, leaving out of view all that may be said bearing upon the
question of cause and effect, than is afforded by this statement,

A view similar to that advanced in regard to the geographical

DISTRIBUTION OF RAINFALL. 259

distribution of forests in India is advanced in regard to the distribu-
tion of forests in America, by Mr Charles Maclaren, in an article on
America in the “ Encyclopedia Britannica.”

In this the writer says,— We are induced to think that in all
countries having a summer heat exceeding 70°, the presence or
absence of natural woods, and their greater or less luxurianve, may
be taken as a measure of the amount of humidity and of the fertility
of the soil. Short and heavy rains in a warm country will produce
grass, which, having its roots near the surface, springs up in a few
days, and withers when the moisture is exhausted; but transitory
rains, however heavy, will not nourish trees, because after the sur-
face is saturated with water the rest runs off, and the moisture
lodged in the soil neither sinks deep enough nor is in sufficient
quantity to furnish the giants: of the forest with the nevessary
sustenance. It may be assumed that twenty inches of rain falling
moderately, or at intervals, will leave a greater permanent supply in
the soil than forty inches falling, as it sometimes dves in the torrid
zone, in as many hours. It is only necessary to qualify this con-
clusion by stating that something depends on the subsoil. If that is
gravel or a rock full of fissures, the water imbedded will soon drain
off ; if it is clay ora compact rock, the water will remain in the soil.
It must be remembered also that both heat and moisture diminish as
we ascend in the atmosphere, while evaporation increases ; aud hence
that trees will not grow on very high ground, though its position in
reference to the sea and the prevailing winds should be favourable in
other respects.”

Assuming as unquestionable that the trade winds are the agents
which transport the moisture exhaled from its surface to the interior
of great continents, where it is precipitated as rain, or dew, or snow ;
and that mountains, by obstructing aerial currents and presenting
great inequalities of temperature, cause precipitation, this writer says,
—‘ Let us consider then what will be the effect of a mural ridge like
the Andes in the situation which it oscupies. In the rezioa within
the 30th parallel the moisture swept up by the trade win from the
Atlantic will be precipitated, part upda the mountains of Brazil,
which are but low, and so distributed as to extend far into the
interior; the portion which remains will be borne westward, and,
losing a little as it proceeds, will be arrested by the Andes, and fall
down in showers on their summits. The aerial current will now be
deprived of all the humidity which it can part with, and arrive in a
state of complete exsiccation at Peru, where no rain will consequently

260 RELATION OF FORESTS TO

fall. That even a much lower ridge than the Andes may intercept
the whole moisture of the atmosphere is proved by a well-known
phenomenon in India, when the Ghauts, a chain only 3000 or 4000
feet high, divide summer from winter, as it is called: that is, they
have copious rains on their windward side, while on the other the
weather remains clear and dry ; and the rains regularly change from
the west side to the east with the monsoons.

“In the region beyond the 30th parallel this effect will be reversed.
The Andes will in this case serve as a screen to intercept the moisture
brought by the prevailing west winds from the Pacific Ocean ; rains
will be copious on their summits, and in Chili on the their western
declivities, but none will fall on the plains to the eastward, except
occasionally when the winds blow from the Atlantic.”

And he adds,— The views on the subject of climate we have been
unfolding will enable us to throw some light on an interesting point, .
the distribution of forests.”

There is appended a small. map of America, in which by long
hatched lines are shown the positions of the chains of mountains ;
white spaces represent lands on which little or no wood grows;
shading represent the regions of forests, dense forests being repre-
sented by double shading, and thinner ones by open lines; while
arrows indicate the direction of prevailing winds. And in explanation
it is stated,—“‘ In speaking of the region of forests, we neither restrict
the term to those districts where the natural woods present an un-
broken continuity, nor extend it to every place where a few trees
grow in open plains. It is not easy to give a definition that will be
always appropriate ; but in using the expression we wish to be under-
stood as applying it to ground where the natural woods cover more
than one-fourth of the surface.” And there is given the following
statement in regard to the distribution of the forests,—“In North
America, to the west of the Rocky mountains, is thus represented a
woody region, extending from lat. 35° to about 58°, of unknown
breadth, densely wooded from the coast, more thinly wooded towards
the mountain range; to the east of the mountains, an extensive
region stretching E.NE. to the ocean, partly a bare desert, partly
covered with grass and clothed with trees. On the east coast and
more to the south is the Allegany range, with dense forests on the
east and the south and thin on the west, the forest region thus
indicated being bounded by a curved line passing from the mouth of
the St. Lawrence, in lat. 50°, through Lake Huron to St. Luis in
Mexico; and an arrow points out the direction of the wind turned

DISTRIBUTION OF RAINFALL. 261

from its course, ascending the valley of the Mississippi, and nourish-
ing the western parts of these forests. To the south of lat. 30° the
equatorial winds blowing from the east prevail ; and from 35° south-
ward from the forest lands of the Rocky Mountains, is the table land
of Mexico, graduating in the north-west into the dry plains of Sonora
and California, all bare or nearly bare of wood. From this region,
down through the Isthmus of Panama, there are dense forests.
These dense forests fork and stretch to some extent along the
western coast of South America to Amotape, whence stretches a long
strip of dry bare sand; on the west side of the Andes, which
constitute Lower Peru and the north part of Chili, a little to the
north of the equator, about midway from both coasts, is the Llanos,
(a bare plain of caraccas, nearly fenced round with mountains) ;
passing this to eastward, the dense forests follow the coast line,
stretching far into the interior, somewhat diminished in density, and
forming the great region of forest which constitute the basin of the
Amazon and occupies all the rest of Brazil.

“Near the equator the moisture is so excessive that after 150 or
200 inches of rain have fallen on the east coast there is still sufficient
humidity in the atmosphere to afford copious showers to all the
country up tothe Andes. Here, therefore, the woods reach from side to
side of the continent. But as we recede from the equator the
humidity diminishes rapidly, and though the continent becomes
narrower towards the south the supply of rain falls off in a still
greater proportion, and the forests extend over a much smaller space.
At the foot of the Andes the forests extend to 16° or 18° south lat. ;
on the east coast, to 25°, probably 30°. Thence, on the east coast
are the Pampas, or open lands of Buenos Ayres, extending, on the
east side of the Andes, from the latitudes mentioned to Cape Horn.

“But on the western side of the Andes, extending through the
same latitude, are the forests of Chili, where the prevailing winds
which are from the west, coming loaded with the moisture of the
Pacific Ocean, produce copious rains to nourish the herbage and
forests. This applies chiefly to the country south of the 35° parallel.
From that to Coquimbo, lat. 30°, the wood is scanty.”

Tn this, as in the account given by Dr Brandis of the Geographical
distribution of forests in India, we find, apart from the facts
embodied in the statement, an illustration of a general correspon-
dence between the distribution of the rainfall and of forests.

Independent testimony on the distribution of the rainfall in

262 RELATION OF FORESTS TO

America is supplied by the Smithsonian Institution, unencumbered
by any theory. The arrangements made by this Institution for col-
lecting, collating, reducing, and utilizing meteorological observations
are on the most ample scale.

Towards the close of 1873 I received from Professor Henry a series
of rainfall tables, comprising all the observations that have been made
in regard to the rainfall in the United States since the settiement of
Europeans in the country, and an intimation that they had com-
menced a new epoch, and had subsequently to the publication of
these tables distrisuted several hundred rain-gauges in addition to
those previously used, and to those which had been been provided by
the Government in connection with the signal source ; and three rain
charts are given showing, from the material collécted in the general
table of results, the geographical distribution of rain over the area of
the United States, with the average amount fallen during the year, and
during the seasons of summer and winter. The first chart exhibits
the results from 750 stations, and the others the result obtained from
nearly the same number.

In regard to the general character of the distributions of rain on
the average throughout the year, it is stated,—‘‘ The most striking
features of the phenomenon of rain, as delineated on the chart, are
the apparent precision and continuity in the law of its distribution,
and the great variation or range in its amount. Thus the curve,
passing over places where the annual fall amounts to 40 inches, can
be followed from New Brunswick, on the Bay of Fundy, to Texas ;
the isohyetal line of 36 inches, similarly, runs without interruption
from the St. Lawrence River to the mouth of the Rio Grande. The
regularity of the curves is sufficiently distinct to mark out everywhere
the progression in the deposition of the aqueous vapour. The annual
amount varies from four inches in the Yuma and Gila Deserts, at the
head of the Gulf of California, to 80,inches and more on the Pacific
Coast in Washington Territory ; on the Gulf Coast 64 inches appears
to be the maximum amount, and 48 on the Atlantic Coast.

“ The principal supply of rain over the United States comesfrom the
Gulf of Mexico ; its diffused vapour can be traced from the eastern
slope of the Rocky Mountains to the Great Lakes ; while the supply of
vapour from the Atlantic Ocean is distinctly traceable over that area
lying north and east of Virginia. All States and Territories west of
the Rocky Mountains receive their supply of rain from the condensed
vapours of the Pacific Ocean.

“There are distinct localities of entry of maximum rain from each

DISTRIBUTION OF RAINFALL. 263

of these basins of supply ; the vapours from the Pacific are deposited
within a remarkably well-defined coast region between latitude 41°
and our boundary at the Straits of Juan de Fuca; the rain pours
down with great intensity on the coast between the mouth of Columba
River and Cape Flattery. It is surprising how little rain falls on the
Pacific coast between San Diego and Cape Mendocino, and how
quickly the atmosphere becomes drained of its vapour as we leave
the coast and proceed inland in latitudes north of 41°. The coast
range of mountains here act powerfully as condensers by forcing the
air up their western slopes.

“ The densest part of the Gulf vapour is thrown over the delta of
the Mississippi River, and as far east as longitude 86° its aais of
diffusion can be traced distinctly to the west end of the Lake Erie:
it is inclined towards the northeast: for two reasons—the effect of the
earth’s rotation on a flow from the south, and the influence generally
of the prevailing westerly winds. A second sweep over the country
occurs in southern Florida, most likely due to the immediate proximity
of the Gulf Stream ; and there is a third, as yet undefined, influx,
passing through Georgia and South Carolina.

“The condensation of vapor from the Atlantic is most apparent a
short distance inland at the following localities: Along the coast of
Maine near Eastport and near Portland, in central Connecticut,
western Massachusetts, and extending to southern Vermont, and
near the entranee of Chesapeake Bay. Upon the whole, hills and
mountain ranges appear tc have a comparatively small directive
influence upon the distribution of the rain. Florida, which may be
considered as almost perfectly flat, exhibits well-defined bounding
lines of rain distribution. River courses also seem to influence the
amount ofrain, asalong the RioGrande. At the mouth of the Hudson
River, the curves become suddenly contracted ; and some similar
feature can perhaps be traced out on the Mississippi delta near New
Orleans. Beyond furnishing by their evaporation a supply to the
general fund of moisture, the Great Lakes do not appear to exercise
any direct influence; on the yearly average the rains along their
borders are not increased. There is even a remarkably small amount
of rain-fall in northern New York, close to Lake Ontario. The effect
of equalizing the temperature produced by all large bodies of water
has no doubt a direct influence upon the distribution of rain; the
greater and more sudden the variations in temperature, the greater,
comparatively, the rain-fall.

“The laws of the distribution of the rain-fall, as far as they depend

264 RELATION OF FORESTS TO

upon the changes of temperature and direction of wind, can be studied
to better advantage by means of the two charts showing the dis-
tribution in summer and in winter, than by that for the year, since
the latter necessarily brings out the resultant phenomena, and should
consequently be of greater complexity than either of those for the
extreme seasons. With a few exceptions, presently to be noticed, the
distribution of rain in the extreme seasons is not very dissimilar from
that of the year as a whole.”

It is stated in the report that the tables show that mountains, and
hills have apparently a comparative trifling divertive influence on the
distributions of rain. For this conclusion some of my readers may
not have been prepared. To what extent, if any, the distribution of
forests may correspond with the distribution of rain is not referred
to; but in a work on the aspects presented by forests in different
parts of the world, by M. F. S. Marny, we have notices of the forests
in the United States, of which we may avail ourselves to see how far
these independent records—the one of the rainfall, and the other of
the forests—correspond.

After a graphic description of the forests of South America, M.
Marny says:—“ On re-ascending into upper Mexico and reaching
California, arborescent vegetation resumes, with regard to kinds, the
character of our temperate climates, but it still preserves its gigantic
character which belongs to the trees of the New World. In Oregon,
the pines thai fill the forests spread along the sea shore seem to be
the kings of all the pines in the universe. Their diameter is often 5
métres, their height surpasses sometimes 100, and their cones are 15
inches long. The pine lambertina gives to the coast of California an
imposing but melancholy aspect. The lines of pines run along the
shore as far as Russian America, where they are associated with oaks
and birches. Their less lofty species prevail in the forests of New
Hanover, of New Georgia, where they adorn, with sycamores and
maples, the slopes which incline towards the ocean.”

Along the coast, from lat. 50° to 41°, we have according to the
rain-chart a rainfall of from 60 to 40 inches, diminishing as we pro-
ceed inland to 52, 44, 32, 30; and in the longitudes of Nevada,
extending thence to Minnesota, Nebrasku, and Kansas, 16 and 20,
with no mention of forests, but in the State last-named it rises to 20,
24, and 28.

M, Marny proceeds :—“ Crossing the Appalachian and the Rocky

DISTRIBUTION OF RAINFALL, 265

Mountains, we encounter new lines of forest-trees. One of the first
is traced by the bald cypress, which seems to be surrounded by
natural boundaries. These are protuberances formed upon the roots
of this conifera, and they often rise to a métre in height: which
barriers defend the trunk against the attacks of large animals,
These cypresses compose gigantic thickets, which cover the swamps
of the lower Mississippi, of the Arkansas, of the Red River, and of
Florida, and extend as far as the mouth of the Ohio. It was under
the vast shade of one of these trees that Cortez and all his army
found a refuge in Mexico. Their wide stems, of conical form, are
crowned with a multitude of horizontal branches, which are entangled
with each other, and confounded with those of the neighbouring
cypresses. These vaults of foliage, which are frequently superimposed,
give to the forests of this cypress an aspect quite peculiar. The short
leaves of a sombre green, represent on drawing near a kind of crape,
which impresses on these shades a funereal appearance. And under
these gloomy domes, which are here and there enlightened by a few
openings made by the winds, or due to the age of the branches, all
the scourges of man, whether animate. or inanimate, seem to have
given each other the rendezvous. Death soars over these shady
solitudes, which incessantly evoke the idea of it. Fevers, alligators,
serpents, mosquitoes contend with each other for the woodman
who goes with his axe to sirike their trunks—the growth of ages.
But no danger arrests the avidity of man, nothing terrifies the enter-
prising descendant of the Anglo-Saxon race. The Jumberers venture
through these pestilential swamps, and precipitate into the waters of
the Mississippi the trunks they have uprooted.

“ The Mississippi, that ancient father of waters, is indeed the great
agent of destruction to these forests of North America; its waters,
especially at the period of inundation, are continually charged with
enormous masses of wood, with gigantic rafts which encumber its
bed, and are self-constructed with more solidity than any raft made
by the hand of man. These trains of trees are especially remarkable
upon the Atachafalaya, one of the arms of the Mississippi. They are
equally met with upon the Red River. One of the affluents of this
river, the Nashita, is interrupted for a space of seventeen leagues by
an almost uninterrupted succession of these rafts. M. de Humboldt
has made known the same fact in the Orinoco, whose bed is unceas-
ingly encumbered by a mass of trunks, which seem as if driven into
the mud.

“‘These swampy forests, by the destructive action of humidity,

2r

266 RELATION OF FORESTS TO THE

finish by transforming themselves into vast bogs, which present the
appearance of great inundated plains, whose surface might be covered
with trees brought along by the waters. These immense stagnant
pools, these seas of mud, still furnish a soil sufficiently firm for a
species of cypress, and of broom which grow there; they offer the
only ground of support for the foot of the animals that wander in
these aquatic solitudes,—bears, wild cats, wolves, The most cele-
brated of these swamps is the Great Dismal, which Mr Lyell has
described in his interesting journey in the United States, and which
extends between the towns of Norfolk, Virginia, and Weldon, North
Carolina.” :

In the Lower Mississippi we have, according to the rain-charts, a
rainfall of 56, 60, and 64 inches per annum; in Arkansas, a rainfall
of 42, 44, and 50; in Norfolk, Virginia, 44; in North Carolina, 44,
48, and 52.

M. Marny continues,—“ Upon the lower levels of the Alleghany
Mountains, the rhododendron and the kalmia display their elegant
flowers. From stage to stage the vegetation is modified; and to
forests of oak ssucceed the resinous pines, with which are associated
magnolias, poplars, and different species of nysst.

“The forests of the Alleghanies belong to one of four forest zones
which embrace North America; they extend over the south-west
coast as far as to the south of the bay of Chesapeake. They chiefly
contain pines, firs, cedars, and cypresses.”

In this district we have a rainfall of 36, 40, and 44 inches.

“The second zone, which corresponds with the region of magnolias,
catalpas, tulip-trees, stretches over the Floridas and Louisiana ; it is
characterised in several parts by forests of cedars, known under the
name of cedar-swamps. In Louisiana the rather stunted stems of the
wax-myrtle are found among the rhododendrons.

“In Florida and Carolina are forests cAlled pine-barrens composed
of gigantic pines, reaching a height of more than 50 métres, and
rivalling those which clothe the opposite coast of the American
continent. These pinre-barrens comprise a broad band several hundred
miles in length. Behind these forests of coniferee, which form the
second forest line, one encounters on disembarking upon these shores
—the first being composed of graceful palms—come other forests not
less dense, but composed of a thousand kinds of wood. ‘There,’
writes M. F. de Castelnau, ‘the magnolia exhibits with profusion its

DISTRIBUTION OF RAINFALL. 267

leaves like immense spatulas, while the air is embalmed by itsbeautiful
and enormous flowers so dazzlingly white. It is intermingled with a
hundred species of sassafras, catalpas, laurels, cedars, gum-trees, in
the midst of which the magnificent evergreen-oak distinguishes itself.
Everywhere the cornel-tree dazzles the eyes by its silvery splendour ;
the azalea is lavish of its corolla, like an elegant butterfly ; and the
sumach displays with pride the magnificent splendour of its scarlet
bouquets. All these various trees are closely matted together by
lianes without number—veritable alliances with these brides of
nature.’”

In Florida we have arain-fall of 60, 52, 48, 44, 40, and 36 inches,
and in South Carolina the same.

“The third forest zone invests the hills and low mountains
of the Carolinas, of Pennsylvania, and comprehends the slopes
of the Alleghanies which we have just described. The oak, the
birch, the mulberry, the sycamore, the maple, occupy these
woods. The willow-leaved oak, the elm, and the chestnut, principally
form forests in Pennsylvania and in New Jersey; in the environs
of Habochene venerable forests run parallel to the coast. The two
parts of this state form a strikmg contrast to the rest; whilst a
vigorous vegetation adorns the northera divisions, thos that lie to the
south offer only an arid sandy soil, which has its owa species and its
especial forests. Tne upper Ohio flovs ualer a bower of tulip-trees
and planes, whose elegant foliage is reflected in its waters.

“ But it is in the state of Indiana, above all in the environs of New
Harmony, upon the banks of the Wabach, that the forests of North
America show themselves in al] their mugnificence. They present,
among the forests of the New world, a distinct character, and one of
their peculiarities is the want of evergreen plants, with the exception of
the mistletoe, a species of bignonia, Dutch rushes, which are a kind of
equisetum, and the Jfiegia microsperma. When the woods are stripped
of their foliage, the eye is attracted only by the equisetum just named
which reaches a height of eight or ten feet In these collections of trees
the traveller is struck by the gigantic planes, ramifying themselves
into a certain number of hollow trunks, which serve him as a shelter
in time of need. To these planes are united maples of proportions
almost as great, several oaks, and notably that which bears the name
Mossy aver-cup oak, whose enormous acorns are strewn over the ground,
and which grow in close ranks. A multitude of climbing-plants em-
brace the trunks of the large kinds, the quinate-leaved ivy, the poison

268 RELATION OF FORESTS TO THE

ivy, the bignonia, which attach themselves to the trunks like a thick
net-work formed of aérial roots, to which are attached at right angles
the branches that bear the leaves, Among these mighty trees there
are lofty thickets of 15, 20, and 30 feet in height, composed of the
papaw-tree, the spice-wood or fever-bush, and the red-bud tree. Be-
low these smaller kind of trees the ground is still covered with shrubs,
and in the openings grow the Rhus typhina and the Rhus glabra,
Magnificent catalpas appear at every step in a wild state; but the
botanist seeks in vain for trees with aciculate leaves, the pine, the
cypress, or for the rhododendrons, the azaleas, the magnolias, the
chestnuts, which are met with in other parts of America.

“These woods are rapidly thinning. Legions of backwoodsmen
take up their abode in them ; and they are speedily cleared. Already
wood is becoming singularly dear at New Harmony ; and the hickory,
which gives out so powerful a heat, has been cut down with a pro-
fusion and ignorance usual with the first colonists of forest countries.”

In Indiana we have a rainfall of 44, and 40.

*‘ The fourth zone loses the physiognomy of the subtropical vegeta-
tion, to resume that of the vegetation of our northern countries. It
comprehends the greater part of New York, New England, Vermont,
New Brunswick, Canada, the region of the lakes; to this region New-
foundland belongs.

“In the state of New York, forest vegetation is of a heavy and
dense character; which is owing to the predominance of certain
kinds of hemlock, spruce, fir. The black-spruce constitutes the
characteristic tree of this cold region; it forms a third of the forests
in all the districts comprised between 44° and 53° north latitude.

“A great part of Long Island is covered with forests, of which
one-half is formed, according to Dr Timothy Dwight, of yellow-pines.

“The borders of Lake Huron are covered with gigantic forests of
planes, between the close ranks of which are seen groups of tamarask
or of American larch, of pendulous larch, that frail tree which seems to
be an arborescent reed. All the vegetation of the borders of this lake
is of a more decidedly grand character than that of the other lakes.
The forests of Lake Erie are enriched with the sassafras-laurel, the
magnolia, the Cornus Florida, whose branches, adorned in autumn
with bunches of scarlet, agreeably diversify the sombre verdure of the
rest of the forest. The vegetation of Lake Ontario resembles that of
Lower Canada ; yet we find there some characteristic species—Canada
poplars, the robinia, the lime, the resinous pine, and the red pine.

DISTRIBUTION OF RAINFALL. 269

Upon the borders of Lake Champlain, the sugar-maple, the balsam-fir,
the Virginian poplar, are equally remarkable.

“Tn the environs of the Falls of Niagara the tulip-tree, the red
cedar, and the Canadian yew grow in great abundance; whilst near
to Kingston, which is only seven miles from the cataracts, an immense
forest, composed of horse-chestnut trees, has taken possession of the
soil to the exclusion of every other kind.

Around Bloomfield, not far from Lake Canandagua, magnificent
forests of oak furnish the colonists with a valuable wood, and embel-
lish the slopes of the hills.

Throughout the district specified we have a rain-fall of 44, 40, 36,
32, and on one very limited spot so little as 28.

“When we advance into Canada, forest vegetation gradually
dwindles, and at length becomes quite stunted. We no longer meet
with any thing but little firs, dwarf birches, and lank poplars, This
is observed to the north of Quebec, and of the parallel of the Isle of
Manitoulin.”

Within the line indicated we have a rainfall of from 32 to 44, the
latter being the rainfall at St. Johns, New Brunswick ; falling to 40
and 36 as we come nearer to the St. Laurence.

Thus does it appear that every observation made in North America
seems to tend to show a general accordance between the distribution
of the rainfall and of forests.

Something similar may be observed in the distribution of forests in
South Africa. In the Colony of the Cape of Gooa Hope all the existing
forests are found on mountain slopes following the convex curve of
the sea coast from the mouth of the Orange River on the west to
Port Natal on the east. The trees are comparatively few in number
on the Cedar-Bergen range, in Clanwilliam, but so numerous were
they formerly as to have suggested the name given to the mountains ;
they are more numerous on the Table Mountain range near Capetown ;
they appear in greatest abundance in the districts of the Knysna and
George ; but they abound also in Kaffraria and in the Trans-Kei
territory. This curve encloses an extensive inland district almost
destitute of trees, bounded on the north by a district crossing the
continent beyond the colonies, in which trees are more numerous,
connecting the forest lands of the east with forests on the west coast
further to the north.

Co-extensive with these forests, there is what may be called com-

270 RELATION OF FORESTS TO THE

paratively a copious humidity of soil and climate; while in the
districts in which there are none, the soil and the climate are com.
paratively dry. There have been described by Livingstone three
distinct meteorological zones in South Africa: the eastern, compre-
hending Zulu-land, Natal, Independent and British Kaffraria ; the
central, comprising a portion of the elevated Central Basin of the
continent, and divided from the eastern by the Drakenberg, Malutis,
and other ranges; and the western, including the Kalahari Proper,
the wastes of Namaqualand, and_the wilds of Bushmanland—the
latter, situated to the south of the Orange Biver.

The first of these is comparatively well watered, and there we find
extensive districts covered with ever-green succulent arborescent
herbs, and most of the extensive forests. In the second we find
comparatively little water, and forests disappearing. The third is
arid and sterile and barren in the extreme.

I have had occasion to cite the statement that “the prevalent
winds of most of the country thus divided are from the northeast.
Heavily laden with vapour from the Indian Ocean, the clouds, under
the influence of these easterly currents, are driven over the Zulu
territory, Natal, and Kaffirland, watering those lands luxuriantly; but
when the moisture-bearing nimbi arrive at the peaks of the mountain
ranges, not only have they parted with a large proportion of their
water, but they are then on the edge of the more arid central basin,
and begin to meet with the influences of the heated and naked plains,
under the radiation from the surface of which, and in an increasing
degree as the Bechuana tribes are past and the Kalahari is reached,
the clouds rise higher above the earth, the moisture evaporates in a
thinner vapour, and as a consequence fewer showers fall upon the hot
thirsty soil beneath.

“The further we journey from the Drakensberg eastwards, the
greater becomes the diminution of water.

“ Leaving the mountains, the Lesuto or Basuto land, as it is called,
is without doubt the best watered portion of the central meteoro-
logical district, mainly, it is presumed, on account its being intersected
by the Malutis range. Towards this important section of country,
from November to April, the northeast winds blow from the shores
of Mozambique and the delta of the Zambesi immense masses of
cloud, which sweep heavily over the earth, darkening the sky, and
preceded in their course by dreadful peals of thunder. On reaching
the high land, the aérial lake is shut in by the huge table-headed
mountains ; as a consequence, a rapid condensation takes place, and

DISTRIKUTION OF RAINFALL. 271

then a veritable deluge ensues. In a few moments cataracts rush
from the mountain heights, the smallest and most thread-like rivulets
are transformed into torrents, and the rivers overflowing their banks
cover the plains: this sometimes lasts for days together (Casalis).
It is from the accumulation of these waters that the Lekoa, the
Caledon, and many other tributaries of the great Orange River, which
with slow and niajestic course flows to the westward across the vast
plains of the centre of South Africa, take their rise. As the moun-
tains, however, merge into the plains, and these again into the
Kalahari, we are reminded by the gradual diminishing rivers of the
continual aridity of the soil, till we reach Great Namaqualand, where
the occurrences of periodically filled water-courses again testifies to
the descent of rain.

“Tn this latter district, however, as well as in the desert, rain falls
only from thunder-clouds. These rise from the northeast, and are
always hailed with delight by the inhabitants of those parched and
burning regions; but they are partial in the distribution of their
precious treasure, the storms frequently passing over with tremendous
violence, striking both European and native with awe at their terrific
grandeur, while not a particle of rain descends to cool and fructify
the barren waste.”

Thus do we findin Asia, in America, and in Africa alike, a general
accordance between the distribution of the rainfall and of trees.

Secr. Il.—On the Distribution of the Rainfall dependent on Geogra-
phical Position, being determined by the contour of a country.

Of two existing phenomena it is sometimes difficult to determine
what is the order of sequence in which they have appeared—which
is cause and which is effect—or whether both be not consequences
of the same cause ; and this we may experience in view of the cor-
respondence between the distribution of the rainfall and that of
forests.

Whatever may be the effect of a copious rainfall on a mountain
side in promoting a growth of forest trees—and whatever may be the
effect of a forest there, in producing and maintaining an abundant
rainfall—it is the case that the configuration of a country, irrespective
of forests, exercises a considerable influence on the territorial distri-
bution of the rainfall.

The effect which may be produced by altitude alone on the dis-
tribution of the rainfall receives an interesting illustration from

273 RELATION OF FORESTS TO THE

observations collected and published by M. Belgrand* in regard to
a wind-wave which passed over Europe towards the end of September,
1866.

This wave originated in America, on a line which extends from
Buenos-Ayres to the North Pole; it traversed the Atlantic, and reached
England on the 20th September, and France, Belgium, and Holland
on the 21st. On the 22nd, it reigned at the same time over Nancy,
and over Paris. On the 23rd, it raged over the sources of the Seine,
and of the Loire, and extended to the Garonne. On the 24th, it
passed over Lyons; its fury broke upon the St Bernard, from the
24th to the 26th; and from the 23rd to the 24th, upon the
Simplon.

On all the elevated places it poured out a quantity of rain equal to
about a fifth of the average annual rainfall. On the contrary the
low-lying plains were almost everywhere spared; England and Nor-
mandy did not receive a twentieth of the annual rainfall. Shielded
by the mountainous backbone of France, which stretches obliquely
from the Vosges to the Pyrenees, and as a watershed divides the
water between the ocean and the Mediterranean, Carcassonne, Mont-
pelier, Grenoble, Lyons, Bourg, and Bezangon did not receive any
extraordinary rainfall ; it did not rain at all at Strasburg, at Dresden,
at Munich, at Breslau—nor did it in Austria or in Italy. In Swit-
zerland, and even in Savoy the rain was not great, while Mont Blanc,
the Simplon, and the St Bernard received only 17 per cent. of the
annual rainfall,

There is much that is interesting in the study of the atmospheric
wave, sweeping along 1700 feet above the level of the sea, with a
stretch of wing, extending some 1200 miles and more, skimming the
high lying plateaux of France, and by a flight of 200 leagues a day
dashing itself against the summits of the Alps; but it is to the dis-
tribution of the rainfall occasioned by it with which alone we have to
do here.

At the meeting of the British Association for the advancement of
science, held this year (1876) in Glasgow, Sir William Thomson
made a communication in regard to the production of the phenomenon
known as a “mackerel sky,” which suggests an illustration of the
phenomenon under consideration.

Schoolboys amuse themselves sometimes with skimming flat stones

*® Belgrand: Annales dea Ponts et Ohausees. Sept, 1866.

DISTRIBUTION OF RAINFALL, 273

along the surface of smooth water. The same phenomenon is pro-
duced upon a greater scale when a cannon ball, aimed at a floating
target, strikes the water and’ rebounds into the air again and again
ere it disappears. I have often, at the Cape of Good Hope, seen
indications of the southeast wind advancing in waves, raising dust
where it seemed to descend and strike the ground, but leaving un-
disturbed alternate stripes over which it seemed to bound or rebound
at a higher level. ‘I'hus may it be with all currents, whether of
water or of air, descending and striking upon other matter, solid,
liquid, or gaseous, at an acute angle of inclination—as is indicated by
the undulations or waves raised by the breath on a cup of tea,
by the wind on a pond or placid stream, and by a storm upon
the sea, And, according to the supposition of Sir William Thomson,
a current of air striking upon a lower current, advancing in the same
direction but with less velocity, or advancing in another direction, or
upon a stratum of air in a state of quiescence,ymay rebound as does the
skimming stone or the rebounding cannon ball on striking the water.
And if the temperature of this current of air were near to that of the
dew-point, or point of saturation, when it rebounded to a higher
elevation, the temperature being thereby reduced, a condensation of
moisture would ensue ; but when the rebounding force was exhausted,
and it again descended to a lower level, it would acquire a higher
temperature, and the condensed vapour would be again dissolved in
the air, producing the phenomenon of alternating stripes of cloud
and of sky.

It is to this difference in the power of air to sustain vapour in
solution at the different temperatures through which it passes at
different elevations that I refer as illustrative of the rainfall occa-
sioned by the wind-wave which has been spoken of. I have had
occasion to refer to an illustration of the same kind afforded by
the passage of the southeast wind over Table Mountain, producing
dense clouds and even drizzling rain on the mountain top, but the
clouds disappearing as the current pouring over the front of the
mountain reached a lower level but a higher temperature ; so is it
with the wind-wave deluging the mountains with rain but passing
over the lower-lying plains without. any such effect,

Such wind waves, varying in their sweep and in their dimensions,
but essentially the same, are not of unfrequent occurrence, Most of
those, of which the phenomena have been studied, have swept along

the surface of the earth and the ocean, and even they es have
ic

274 RELATION OF FORESTS TO THE

produced or yielded a greater rainfall on mountains than on plains ;
as in passing over mountain elevations the temperature of the air
would experience a great reduction, “and a precipitation of the
moisture they contained would follow.

And it may be the case that the presence or the absence of forests
on the mountain summits might affect within a limited range the
degree to which the temperature of the wave in passing over the
ridge would be reduced. So would a fire in a hunter’s cabin! So
would the huntsman’s breath, and even the huntsman’s presence, and
every discharge of the huntsman’s rifle! But in the presence of
such meteorological phenomena as are under consideration all of
these are as nothing,

And as is the case in such occasional disturbances, so may it be,
and most probably it is, with the regular current of the atmosphere
passing over a mountain range in its course to the equator from the
pole, or striking upon a mountain top in its return to the arctic or
antarctic zone. The great change of temperature occurring in the
case cited made manifest in such a way as to arrest attention the
consequence of such a change in so far as it affected the rainfall ;
but any reduction of temperature below the dew-point would, in pro-
portion to its extent, produce corresponding effects. Such a reduction
of temperature frequently follows the passage of an atmospheric
current over a mountain range ; and to the altitude of the mountain,
* so completely as almost to warrant the use of the term exclusively, is
the greater rainfall on the mountain attributable.

T have hesitated about using the term exclusively, not on account
of the influence which the circumstance of the mountain summit
being clothed or being bare of forests might have in somewhat, but
probably to an imperceptible degree, modifying the result; but I
have done so on account of the influence on the rainfall exercised by
the contour of the mountain range.

This subject, the influence on the rainfall exercised by the super-
ficial configuration of a country, has engaged the attention of M.
Cézanne. From his sequel to Etude sur les torrents des Hautes-Alpes,
I translate the following statement :—

“When a rain-producing wind strikes against an eminence which
forces it to rise in the atmosphere, a double effect is produced : the
ascent of the air itself tends to a reduction of temperature, and con-
sequent condensation of vapour ; but besides this, the atmospheric cur-

rent turned from its course is subjected to friction against the cooled
Hw)

DISTRIBUTION OF RAINFALL. 275

surface of the earth, and the rain is, as one may say, mechanically
pressed out of the clouds, For these reasons, it rains more on the
headlands than on the exposed slopes; but in the deep jiords of
Norway, a pluvial rain, sharply arrested by a wall of rock, deposits
immediately a maximum of rain.

“There falls annually at Bergen, 2 metres (80 inches) of rain ; at
Bourdeaux, only 719 millimétres (29 inches) ; at Nantes, 1 métre (40
inches) ; at Cherbourg, 830 millimétres (33 inches).

“On the coast-land of the Mediterranean, the rain-producing wind
blows from the east, or the south-east, in a vertical direction to the
wall of the Cévennes, upon which descend violent showers. There
falls annually at Marseilles, 512 millimétres (20} inches); at Tou-
lon, 505 (20 inches); at Nismes, 640 (26 inches) ; at Montpelier,
770 (31 inches); at Viviers, at the foot of the mountains, 900 (36
inches); at Joyeuse, at the bottom of a valley, 1:300 millimétres
(52 inches).

“The region of the Jura gives as characteristic of the rainfall the
following figures: Lyons, 776 millimétres; Magon, 876; Bourg,
1™ 172; Syam, in the gorge, 1™ 630.

“Some writers have erred in thinking that they may conclude,
from such and similar facts, that the quantity of the rainfall in a
place increases with the altitude of the place. Formulated thus, the
law is not correct; and the phenomenon cannot be explained satis-
factorily. The phenomenon is mechanical as well as physical, and is
more intelligible when formulated thus: The pluvial rainfall is greater
in proportion as the atmospheric current arrested by an obstacle is com-
pelled to rise more rapidly. It is not then the altitude of a place
which is of most importance, it is the incidence with which the rain-
yielding wind strikes the slope which opposes it; but the law regu-
lating this incidence it is not easy to determine.

“From what has been stated it comes to pass that in order satis-
torily to compare two rain-gauges it is necessary to take into account
their absolute elevation, and along with this the slope and configura-
tion of the mountain sides which support them. The following table,
in which are brought together several localities situated in the gorges
of the Jura, show that the altitude is not the dominating element—
for the maximum of rainfall is far from corresponding with the
maximum of elevation :—*

* L’Epeillé: Recherches sur les inondation (annales de la Société agriculture
de Lyon, 1858):

276 RELATION OF FORESTS TO THE

Altitude. Rainfall,
Locality. Metres. Millimétres.
Pierrechatel, s bss _ int 161 1260
Varambon, $s Pon i tee 233 11118
Saint-Rambert, ... ect soe oy 310 1592
Syam, oo es saa aes 365 1741
Saint-Claude, oe rr aoa sie 444 1457-7
Pontarlier, bas a8 ee ses 840 970
Fort-de-Joux, es ate te «. 1001 1176-7
Saint-Cerques, ees ae wee 1045 1560

“At the convent of the great Saint Bernard (altitude, 2620
métres, = 8733 feet) there is collected annually 1500 millimetres (60
inches) of water. Ifthe most elevated pluviométre in Europe be at
the same time one of those giving the high measurements, the cause
of this is perhaps less its altitude than its topographical position.
The instrument is placed in a narrow embrasure, dominated by
glaciers, in which the winds, come from what direction they may,
must pass on violently, and be rapidly cooled.

“The obstacle once passed, the rain diminishes—the current
descends and becomes heated again ; desirous of repairing its loss,
it drinks up the clouds with avidity, and dries up the mountain
slope on the opposite side.”

Giving then a graphic account of the appearance presented by a
sea, of clouds rising up a mountain side and pouring over into the
valley beyond, when this is contemplated from a surmounting height,
which has been already quoted (ante p. 157), he goes on to say,—
“ That the superficial aspect of a country has an important influence
on the phenomena of the rain may be illustrated by many well-
known cases.

“On the two sides of the Scandinavian Alps, the west wind and
the east wind give inversely fine weather and rain, the one to Sweden
and the other to Norway.

“When it rains at Narbonne the sun shines at Montauban.

“The rain comes from the west in Switzerland, and from the east
in Lombardy. It is in consequence of its being sheltered from the
south and,southeast winds, which drench the basin of the Rhone,
that the valley of the Durance presents that exceptionally dry climate
which M. Surell points out to be favourable to the development of
torrents.* It rains upon an average, at Marseilles, 57 days in the
year; at Arles, 45 days; at Aix, 40; but in the region of the Durance
it rains only 38 days in the year.t

* Surrel, chap. xxi. t Arago: Melanges, p. 430,

DISTRIBUTION OF RAINFALL. 277

“Under the tropics, where prevail the trade-winds blowing from
the east, the lands which incline towards the east are inundated with
torrential rains: thus is it on the coast of Mozambique, and in the
basin of the Amazon. On the contrary, it almost never rains on the
western slope of the Andes. It is said that thunder has not been
heard at Lima three times in as many centuries.*

“In the Indian peninsula the eastern coast, or that of Coromandel,
is watered by the North-east Monsoon ; and the west coast, or that of
Malabar, by the South-west Monsoon.t

‘‘ When, after having climbed the slope of a mountain, the atmos-
pheric current, greatly relieved of its load, comes upon a platean, it
freely expands ; but its lowest layer, being in contact with the earth,
is alone reduced to a lower temperature. From which it comes to
pass that, from the same wind, a plateau, though more elevated,
receives less rain than the ascending slope, but receives more than
does the descending slope beyond.

“The summit of the elevation which separates the Ocean from the
Mediterranean supplies the following table :—t{

Region. Altitude—M?étres. Rainfall—Millimatres,
West Slope (Toulouse), ... ee ie 148°50 632°7
Summit (Castelnaudary), ... wee es 170-00 630°0
East Slope (Carcassonne), ... 8 ae 113-00 7573

“From this table it may be seen that the slopes receive a little
more rain than do the summits, and if it be borne in mind that the
summit gets rain—now from the east wind, now from the west
wind,—while Carcassonne, for example, does not receive it except
by the east wind, it is beyond a doubt that the summit receives
less rain from the same wind than is received by the two slopes
which are ascended by the pluvial current.

“On a very interesting hyétographic chart, prepared by M. Delesse,
Ingenieur en chef des mines,|| it is seen that the plateaux of La Beauce
and of La Brie, subject to the influence of the west wind alone, present
avery manifest minimum. There falls at Chartres 540 millimétres, at
Meaux 400 millimétres of rain annually.

“La Burgogne forms, as is known, a basin which stretches itself

* Review: Theorie de la pluie (Annuaire de la Société météorologique de
France, (1866) tome XIV.)
+ Lamairesse (annales des pont et Chaussées, October 1869).
$ Raulin: Observations Pluviométriques.
|| Delesse: Distribution de la Pluie en France (Bulletin de la Société de
geographie Aon, 1868.)

278 BELATION OF FORESTS TO THE

from North to South, between the walls of the Forez and of the
Jura. This basin is crossed by the west wind, which distributes its
rain in such a way as to give clear testimony to the influence of
mountain elevations. *

Regions, Mean of observations, Places of
Altitude— Rainfall— Observation.
Metres. Millimetres.
Slope-of the Forez passed over by the

pluvial wind descending, uw. 440 704°3 8 stations,
Bottom of (Right bank of the Scie, ies 252 695'7 Boy
Valley. (Left bank of the Saone, Site 234 730°1 6 y»

Adjacent region at the base of the Jura
passed over by the pluvial wind re-

ascending, ais 301 1087°8 On i
Gorges of the Jura “where the pluvial
current iscompressed, ... a ast 549 1358 °0 8 y

“From this table it is seen that the pluvial wind produces very
different effects indeed according as it descends an incline, or re-
mounts an acclivity. When it is descending it gives quantities of
rain almost equal at the very different altitudes of 440 and 252.
While, when it re-ascends, it suffices to pass on the opposite bank, from
the level of 234 to the height of 301, forthe quantity of rainfall to
increase 50 per cent. During the descent there is precipitated less
rain at the level of 252, than is precipitated in the re-ascent at the
lower level of 234; there falls twice as much rain on the re-
ascending acclivity, at the level of 549 métres, than falls on the’
descending incline by which it came, at the level of 440 métres,
although the difference between the two altitudes scarcely exceeds
100 métres.”

From what has been advanced it may be seen that in rainfall
determined by geographical position, the distribution of this is
greatly modified by the contour of the country. But this is not
done only in the way which has been referred to. M. Cézanne goes
on to say :— The elevation of the ground acts in yet another way
on the distribution of the rain: altitude modifies the proportion of
rain falling in the different seasons of the year; in this way elevation
above the level of the sea has the same influence as distance from the
coast. During summer the maximum of rain falls in places of con-
siderable elevation or distance from the sea, but during winter in

* L’Eveille: Recherches, dic.

DISTRIBUTION OF RAINFALL. 279

low-lying lands or places near the coast. And when one observes the
distribution of the rainfall over the ramifications of the same valley,
the phenomena become still more interesting. The basin of the
Seine is particularly suited for this study, since it is regular in form,
largely open to pluvial winds, and more especially since M. Belgrand,
who has explored it in its every part, has made us acquainted with
his scientific investigations.*

“‘ Near the sea, at the lighthouse of Fatonville, there falls annually
799 millimétres of rain. From this point to the valley of the Oise
the plateau maintains perceptibly its level; in consequence of this
the quantity of the rainfall diminishes in proportion as the pluvial
current advances from the sea. The average sinks to 580 milli-
métres in the valley D’Oise, and to 575-6 millimétres at Paris ; but
it re-increases from that point as the land itself rises: it amounts to
656 millimétres at Hirson ; towards the Ardennes, at the altitude of
196 metres; and to 1570 millimétres at the Settons, on the height of
the Morvan, where the altitude is 596 métres.

“Tt is remarked that it rains more in valleys than on elevated
plains, because the atmospheric current follows by preference the
deep depressions which cut up the plateaux, in the same way as on
the flat bottom of a valley levelled by an inundation, the current by
its tumultuous waves still marks out distinctly the line of the old
thalweg.

“But M. Belgrand, however, has established as a fact that the
pluvial current does not go up indifferently every valley ; it passes
bye the valley D’Oise, and ascends by preference the valley of the
Seine, and by that of the Yonne, which in going up from Montereau
igs a direct continuatiou of the first.

* Even at Paris the hill of Montmartre divides this current, which
bifurcates as does a river around a pier of a bridge; the pluvial
wind passes by preference behind the hill, and La Villette receives
more rain than does Paris. Thus each valley receives more rain in
proportion as it is set towards the atmospheric current which brings
the rain.”

Other observations not less interesting are adduced by M. Cézanne,
illustrative of an influence on the distribution of the rainfall being
exercised by the contour of a country.

In illustration of the same thing, M. Raulin, Professeur & la

* Belgrand: Regime de la pluie dans le basin de la Seine (annales des Ponts
et Ohausées, 1865),

280 RELATION OF FORESTS TO THE

Faculté de Bourdeaux, has given the following note as a contribu-
tion to the researches of M. Cézanne :—

“Tn 1868 and in 1869 I established as a fact that in Northern
and Central Europe, and in Siberia, on to Kamschatka, there had
been a predominance of rain during three months of summer, the
more marked as we advanced farther to the east, while in the region
of the Mediterranean there had been a sparsity of rain during the
same season.

“It is interesting to investigate what is in France the pluvial régime
of the lofty chain which separates the two great orographic or
mountain-bound basins of northern and of southern Europe; and this
I shall now attempt to do by means more especially of observations
made by the Service des Ponts et Chaussées, which the Ingenieurs en
Chef of the Alpine Departments have had the kindness to communi-
cate to me.

“Tt might naturally be supposed, @ priori, the northern régime
having summer rains so copious and predominant on one hand in all the
plains of Switzerland, and on to Lyons; and on the other hand in the
Lombardo-Venetian plain of the Adriatic, on to that of Milan,—that
this régime would be continued in the equally cold high mountains of
the western branches of the Alps, which stretch from Mont Blanc in
the south to Nice and Draguigan ; but it is not so.

“Tn the high southern summits at the Great St Bernard, even there
the Mediterranean régime is deplored, and it is matter of complaint
that the rains of summer are scarcely two-thirds of those of spring,
which exceed somewhat those of autumn ; and this poverty of atmos-
pheric moisture in summer goes on progressingly increasing in pro-
portion as advancing from that northern station one approaches to
the Mediterranean,

“Tn the High Alps, at Briangon, the rains of spring prevail still
more, being more than double those of the summer; on the other
stations of the department, Gap and Serres, and also at Die on the
Drome, the rains of autumn reach on an average double the measure
of those of summer.

“Tn the Lower Alps, at Barcelonnette, Digne, Castellane and
Manosque, the difference between the quantities of the rainfall in
summer and in autumn is still greater: it is the same on the
plateaux from Var to Régusse.

“ At Valences, at Yiviers, at Orange, at Avignon, the spring rains
still predominate, but they are greatly exceeded by those of autumn,

“On the coast from Marseilles to Toulon, Hyéns and Génes, the

DISTRIBUTION OF THE RAINFALL. 281

rains of spring are frequently less than those of winter, the quantity
of which is greatly exceeded by that of the autumn rains.

“The Mediterranean régime, thuscharacterised, clears the Appennines
and extends itself into the southern portion of the plain, from the Po
to Parma and to Guastalla; but already at Bologne, and in the
northern part at Padua and Milan, and in Piedmont at Turin and
Yvrée, the northern régime is again found characterised there as at
Geneva by a constant augmentation of the quantity of rain in winter
and in autumn.

“On the circumference of the western branch of the Alps, the pluvial
region presents a great difference, such as has already been referred to.
On the plain of Switzerland, and on its prolongation to the south-west,
from Zurich to the confluence of the Rhone and the Isére, it is the
northern régime which most prevails, with a preponderance of summer
rain at Zurich, exceeded by that of autumn rains at Geneva, at
Chambérg, at Lyons, and even at Annonay and Tournon (Ardéche).
But it is seen suddenly to change and to pass completely into the
Mediterranean régime in the valley of the Rhone, from the point at
which it passes the confluence of the Isére.”

There is given a tabulated statement of observations made on the
coast of the Mediterranean throughout the year from 1851 to 1866;
on the basin of the Rhone from 1853 to 1860; and on the basin of
the Durance from 1856 to 1866; with the names and the altitudes
of the stations at which they were made, which gives evidence of the
facts stated. The stations included in the table, with the respective
altitudes are the following :—On the sea-border of the Mediterranean,
Marseilles, Toulon, Hyéres, Génes and Régusse ; in the basin of the
Rhone, altitude 40 métres, Valence 113, Lyons 295, Chambérg 305,
Geneva 387, Die 413, and Great St. Bernard 2491; in the basin of
the Durance, Manosque, altitude 370 métres, Digne 639, Serres 662,
Gap 740, Castelane 786, Embrun 870, Barcelonne 1173, and Brian-
gon 1305.

And AM. Raulin goes on to say :—“ As regards the quantity of rain
which, upon an average, annually falls on the ground in the Western
Alps, there are great differences between different stations. That
of the Great St. Bernard, the most elevated, receives the greatest
quantity of water.

“In the High Alps, and in the Lower Alps, the quantity much
less considerable goes on, in general, increasing in proportion as the
stations are less elevated, as is also the case from Briangon to Die

(Dréme) and from Barcelonnette to Régusse (Var).
25

282 RELATION OF FORESTS TO THE

Altitude in Metres. Rainfall in Millimetres,
2491 Gt. St Bernard, ... 1239°1
1305 Briangon, ae 684°6
1173 Barcelonette, ... 439-7
870 Embrun, or 603-6
740 Gap, ae 796°9 .
763 { 786 Castellane, ib 873-4 bess :
662 Serres, de 706°4
GAD { 639 Digne, _ 705-5 \ £08
575 Regusse, ae 993°3
413 Die, - 732:9
a3 { 370 Manosque, 632-0 \ 682'5

“Thus whilst in the Pyrenees the rainfall goes on increasing with
the altitude, it is rather (with the exception of the Great St. Bernard)
the reverse which is the case in the French Alps, which are more-
over much less rainy.

“The quantities of water which fall in the circumference of the
Alpine region to a similar extent show great diversities : almost the
same at Zurich and Geneva ; they increase at Chambérg, to diminish
at Lyons, Annonay and Tournon. Descending the Isére they are
greatest from Valence to Orauge; and diminish greatly at Avignon.
On the sea board they are remarkably great from Marseilles to Génes.
In Piedmont they are as great at Turin as in the valley of the Rhone ;
in descending the Isére; at Yvrée they reach a figure much higher
than at the Great St. Bernard.”

To this statement by M. Raulin there is appended a valuable note
of considerable length on the extent of what has yet to be learned in
connection with the theory of rain. The observations which have
been cited are advanced in proof of its not being the altitude of
localities irrespective of the contour of the country which determines
the quantity of rain falling there; and they have been adduced here
solely in illustration of the fact that the contour of a country has
much to do with the distribution of the rainfall.

There are countries in which rain rarely or never falls. Inthe Great
Sahara of Africa, says Sir John Herschel, rain is unknown ; as also in
Arabia and part of Persia, in the great desert of Geb; in the table
land of Thibet, &c.; while at Coimbra, on the coast of Portugal,
there falls 118°8 inches of rain per annum ; at Mahabalchwar, near
Bombay, there falls upwards of 254 inches ; at Uttray-Mallay, there
falls upwards of 267 inches ; and at Cherra-Ponjee, 592 inches,

DISTRIBUTION OF THE RAINFALL. 283

Such a distribution of the rainfall is evidently attributable
primarily to geographical situation, and thus may it be with the
rainfall generally. But the observations of M. Cézanne and of M.
Raulin seem to show that irrespective of forests the distribution of
rainfall dependent on geographical position may be determined by
the contour of acountry. And when, in view of this, we look to the
correspondence between the distribution of the rainfall which has
been adverted to, we see no necessity for concluding that it has been
the existence of the forests which has determined the corresponding
distribution of the rainfall in the places cited, as that seems to
exercise a much more powerfnl influence than this can. ,

Sect. III.—On the Distribution of Forests Affected by the Distribution
of the Rainfall.

The general accordance between the distribution of forests and the
distribution of the rainfall on the earth’s surface, detailed in the first
section of this chapter, naturally suggests, as has been stated, the
enquiry, Can they be consequences of some common cause? or is
this general accordance only an incidental coincidence? or are they
connected together as being one of them the effect of the other as
the cause or thé occasion ofits appearance? And if so which of them,
the distribution of the rainfall or the distribution of the forests, which
is the cause and which is the effect? To what extent is the one the
cause or occasion of the appearance of the other? and may not that
which may appear to be the effect have a reflex influence upon that
which appears to be the cause or occasion of the other ?

Such is the question raised, and I have adduced evidence to show
that the distribution of the rainfall dependent on geographical
position may be determined in a great measure by the contour of a
country, the elevation and the configurations of its mountains, its
valleys and its plains, irrespective of whether it be clothed with
woods or altogether devoid of these; and in a preceding section
I have stated my opinion to be that the distribution of the rainfall
may primarily have determined the distribution of the forests, but
that the forests once established may have exercised an important
influence on the distribution of the rainfall.

It is stated by Mr Marsh : “ There is good reason to believe that
the surface of the habitable earth, in all the climates and regions
which have been the abodes of dense and civilized populations, was,

284 RELATION OF FORESTS TO THE

with few exceptions, already covered with a forest growth when it
first became the home of man. This we infer from the extensive
vegetable remains—trunks, branches, roots, fruits, seeds, and leaves
of trees—so often found in conjunction with works of primitive art,
in the boggy soil of districts where no forests appear to have existed
within the eras through which written annals reach ; from ancient
historical records, which prove that large provinces, where the earth
has long been wholly bare of trees, were clothed with vast and almost
unbroken woods when first made known to Greek and Roman civiliza-
tion ; and from the state of much of North and of South America, as
well as of many islands, when they were discovered and colonized by
the European race. :

“ Whenever a tract of country, once inhabited and cultivated by
man, is abandoned by him and by domestic animals, and surrendered
to the undisturbed influences of spontaneous nature, its soil sooner or
later clothes itself with herbaceous and arborescent plants, and, at
no long interval, with a dense forest growth. Indeed; upon surfaces
of a certain stability and not absolutely precipitous inclination, the
special conditions required for the spontaneous propagation of trees
may all be negatively expressed and reduced to these three: ex-
emption from defect or excess of moisture, from perpetual frost, and
from the depredations of man and browsing quadrupeds. Where
these requisites are secured, the hardest rook is as certain to be over-
grown with wood as the most fertile plain, though, for obvious reasons,
the process is slower in the former than in the latter case. Lichens
and mosses first prepare the way for a more higbly organized vegeta-
tion. They retain the moisture of rains and dews, and bring it to
act, in combination with the gases evolved by their organic processes,
in decomposing the surface of the rocks they cover ; they arrest and
confine the dust which the wind scatters over them, and their final
decay adds new material to the soil already half formed beneath and
upon them. A very thin stratum of mould is sufficient for the ger-
mination of seeds of the hardy evergreens and birches, the roots of
which are often found in immediate contact with the rock, supplying
their trees with nourishment from a soil deepened and enriched by
the decomposition of their own foliage, or sending out long rootlets
into the surrounding earth in search of juices to feed them.

“The eruptive matter of volcanoes, forbidding as is its aspect, does
not refuse nutriment to the woods. The refractory lava of Etna, it is
true, remains long barren, and that of the great eruption of 1669 is
still almost wholly devoid of vegetation. But the cactus is making

DISTRIBUTION OF THE RAINFALL. 285

inroads even here, while the volcanic sand and molten rock thrown
out by Vesuvius soon become productive. Before the great eruption
of 1631 even the interior of the crater was covered with vegetation.
George Sandys, who visited Vesuvius in 1611, after it had reposed
for several centuries, found the throat of the volcano at the bottom of
the crater ‘ almost choked with broken rocks and ¢érees that had falne
therein.’ ‘Next to this,’ he continues, ‘the matter thrown up is
ruddy, light, and soft: more removed, blacke and ponderous; the
uttermost brow, that declineth like the seates in a theater, flourish-
ing with trees and excellent pasturage. The midst of the hill is
shaded with chesnut trees, and others bearing sundry fruits.’ ”

And Mr Marsh adds in a foot-note :—“ Even the volcanic dust of
Etna remains very long unproductive. Near Nicolosi is a great extent
of coarse black sand, thrown out in 1669, which, for almost two
centuries, lay entirely bare, and can be made to grow plants only by
artificial mixtures and much labour.

“The increase in the price of wines, in consequence of the diminu-
tion of the product from the grape disease, however, has brought
even these ashes under cultivation, ‘I found,’ says Waltershausen,
referring to the years 1861-62, ‘plains of volcanic sand and half-
subdued lava streams, which twenty years ago lay utterly waste, now
covered with fine vineyards. The ashfield of ten square miles above
Nicolosi, created by the eruption of 1669, which was entirely barren
in 1835, is now planted with vines almost to the summits of Monte
Rosso, at a height of three thousand feet.’——-Ueber den Sicilianischen
Ackerbau, p. 19.”

I accept as probable the statements which have been cited in re-
gard to the tendency of trees and arborescent shrubs, in common with
other vegetables, to diffuse themselves extensively, and in the struggle
for life to retain possession of the soil; but there are conditions
essential to their success in doing so, and one of these is an adequate
supply of water, not in excess, and varying with varying require-
ments. An excess of water may prevent vegetation,—it may pre-
vent germination, prevent vigorous growth, prevent the formation
of flowers and the maturation of fruit; and a deficiency of water at
any corresponding critical period may have the same effects. There
are general laws in accordance with which is governed the distribution
of all vegetables, and the consideration of some of these laws may
make this manifest.

We may study the phenomena in the growth of mould as well as
in the growth of a forest, and find some advantage in doing so.

286 RELATION OF FORESTS TO THE

If a little decaying cheese, a decaying orange, and a decaying pear
be exposed to the air they may be found after a time covered with
mould ; and microscopic examination will show the three moulds to
be different each from the others. How may this be accounted for ?
Observation fails us ; we are thrown upon reason. Nobly have several
students of natural history endeavoured to extort from Nature an
answer to the question—How do germs first originate? and Nature,
ever truthful, has truthfully replied to her questioners, but the reply
has always shown that the question was not so expressed as to elicit
by an explicit answer to it the information which was desired. It is
thus that I look at the experiments which have been made in con-
nection with what has conventionally but unscientifically been called
spontaneous generation, And whilst awaiting patiently, and with
deep interest, the devising and application of a testing experiment—
which shall finally close all controversy—I take up the question I
have stated : How has the mould been produced, and that in three
different forms 4

There are three solutions of the problem which at once offer them-
selves ; and these are not necessarily antagonistic to each other: it
may be the case that each and all of them may be correct. It may
have been the case, for aught we know to the contrary, that by
chemical action, or this in some one or other of its correlated forms,
the decomposed organic matters which were the subjects of experi-
ment have been resolved into the germs of these moulds ; it may, for
aught we know to the contrary, have been the case that there were
germs of mould floating in the atmosphere, which alighted on the
decaying cheese, orange, and pear, and there germinated, the different
forms they took being determined by differences in the conditions in
which they were placed on these different substances ; or it may have
been the case, for aught we know to the contrary, that germs of all
the three species of mould, and many germs of other genera of organic
structures were floating in the atmosphere, but of these only those
which found in the decaying masses an appropriate soil and con-
dition of growth germinated there, and grew and brought forth fruit.

These several suppositions are not necessarily antagonistic ; but
the last is the only one in entire harmony,—or, if that form of ex-
pression be deemed too sweeping, the one most in accordance,—
with what has been observed in regard to the diffusion of more
highly organised vegetable forms.

It is of these I have to speak, and I employ what has been said not
as an argument but as an illustration.

DISTRIBUTION OF THE RAINFALL, 287

To allay suspicions and fears which may arise in some minds, but
which I consider groundless and unnecessary, I may state that the
underlying question does not relate to the existence of what may be
called a personal Creator, though that question may legitimately be
engrafted upon it ; but it relates solely to the mode of creation—the
wonderful workings of the Creator in clothing the earth with diversi-
fied forms of vegetation; and further, that it takes not up the
question of evolution and development, which has disturbed many
of the Christians of our day—as did the discovery of the earth’s
motion, by Galileo, disturb many of the Christians of his day,—but
it takes up only the question of the distribution of existing species of
plants, in whatsoever way these have been produced.

We do not find the pear mould growing on the cheese, nor the
cheese mould on the orange, nor the orange mould on either. Each is
confined to it own habitat. Neither do we anywhere find all kinds of
plants growing intermixed 6n the same bank. In different places we
may find many different kinds of plants growing intermixed, but the
plants so intermixed in their growth are different in different places.

There are some plants which are widely distributed. With others
it is otherwise, they are confined each to some one locality. Of the
former, we have examples in the silver weed (Potentilla anserina),
in the goosegrass or cleavers (Galiwm aperine), in the square-stalked
willow herb (Zpilobium tetragonum ), in the water starwart (Calztriché
verna), and in the daisy (Bellis perennis); of the latter, we have
examples in the Scottish primrose (Primula Scottica), which is found
only in the north of Scotland and the Orkneys, in the Pride of
Table Mountain (Disa grandiflora), which is found only on the
mountain at the Cape of Good Hope, whose name it bears, and in the
Kerguelens-land cabbage (Pringlea antiscorbutica), which is found
growing on an island most remote from any continent, and which,
besides this esculent, yields only seventeen other flowering plants.

Again there are some plants which you never find excepting near
the sea ; others which you never find excepting on marshy ground ;
others which you never find but in Alpine regions. There are some
plants which are never found growing wild excepting in the tropics,
and others which cannot be reared there even by artificial culture.
There appear to be, at least, three determining conditions of the
distribution of plants: heat, moisture, and soil. I say, at least three,
for I think there are others, such as atmospheric pressnre, &c.; and
the modifications of these three, and the combinations of these

288 RELATION OF FORESTS TO THE

supply an indefinite variety of conditions only some of which will
secure the germination, fructification, and continued reproduction of
any one or more kinds of plants.

Seeds are dispersed widely by the wind and rivers and ocean
currents, by man and bird and beast; but in. order to germination
there is required for each, within a definite range, heat and moisture
and shade; in order to growth there is required, it may be, scme
other measure not less definite of moisture and heat and -sunshine,
and along with these a soil containing certain constituents for each,
in a definite state of disintegration, and in definite states of combina-
tion ; in order to the flowering, and again in order to the fruiting, and
yet again in order to the conservation of the seed in the soil, on until the
period of germination, there are required a succession of definite
varying measures of heat and sunshine and moisture: the range of
each may be more or less considerable, but still it is limited by ex-
tremes beyond which it cannot pass without fatal effects to the re-
production of the plant.

If the seed have decayed before reaching the spot where it finally
rests, if there it be eaten by bird or beast, or if the germ be destroyed
or be consumed by some insect, it will never germinate. If through-
out the various stages of growth and reproduction which I have
referred to, and the intermediate stages connecting these, there be at
any time too much moisture, or too little, too much heat or too
little, too much sunshine—for the effect of this is not confined to
the production of heat alone—or too little, the plant-—be it herb, or
grass, or bush, or tree—will not be reproduced ; and be it noted the
definite measure of heat and moisture and sunshine are not the same
throughout but vary in a definite order of progression ; and should
these fail at any subsequent period, at any point of the progression,
this will be fatal to the continued reproduction of the plant, be it
grass, or herb, or bush, or tree.

Did occasion serve I could produce illustrative cases in point.

And it begins to appear that if, when the seed of a tree was borne
to any spot by the winds, or by the waves of the sea, or by the cur-
rent of a stream, or by bird or by beast, there was on that spot
either excess or deficiency of moisture the seed would not germinate,
Other pre-requisites there are, but with these others these. To many
seeds the stagnant pool and the arid sand would be equally fatal, but
the rainfall evaporating and draining off by infiltration and sacievslte
ment all in excess of what the soil could retain by its hydroscopicity
and capillary attraction, would supply the very amount of humidity

DISTRIBUTION OF THE RAINFALL. 289

required. But fresh supplies varying in quantity with the requisites
of the seedling, the sapling and the tree, and with the requisites of
the tree at the period of flowering, of the setting of the fruit, of the
maturing of the fruit, and of the casting of the seed, are needed. These
the parched land could not supply, neither could the snow covering
the mountain summit, nor the marsh in the valley below, though the
rain failing on the mountain side, with its excess drained off before
it could damage, and its supply from time to time renewed, might to
some extent determine the primary distribution of forests clothing
the mountain side ; and while other kinds of trees perished there,
they might find the conditions of their growth in the moister land
below, kept moist by the rainfall, and the drainage of the rainfall,
from a higher level, or on the banks of streamlets and rivers fed by
this rainfall and dependent thereon for their continuous flow.

We need not to take up, in connection with this subject, the
question, Whence come the seeds? But there is another question,
nearly akin to this, which suggests itself, and which finds in con-
nection with the subject under consideration a ready answer: Might
not other seeds besides those producing the forests also find their way
thither? They might and so might seeds of trees; find their way to
plains where grow only herbs and grass; and where now grow the
trees there may grass and herbage, as well as moss and fern have
formerly flourished ; and on the arid plains seedling trees may have
appeared again and again but only to perish in all the leaves of their
spring. And to the rainfall may be attributed the limitation as well
as the determination of the distribution of each.

It has been intimated by a writer, quoted in the preceding section,
that much depends on the distribution of rain in time as well as in
space.

From what has been advanced we may infer that of the seeds of
grasses, of herbs, and of trees alike, falling anywhere, like the mould
germs alighting on the cheese, the orange, and the pear, those only
which found there all the appropriate conditions of germination, growth
and reproduction would there flourish and be reproduced, and any
failure of the requisite conditions, occurring at any time, would
prove fatal to them. An appropriate supply of moisture is one of
those conditions. Under artificial culture we may see a plant damp
off, turnips braird but never come to maturity, and a seeding tree
perish from drought: thus may seedling trees have perished on the

plain, a consequence of the distribution of the rainfall, and in the
21

290 RELATION OF FORESTS TO THE

account which has been given of the geographical distribution of
forests in India, mention is made of forests near the bed of a river
frequently perishing, through that river changing its course ; all of
these are occurrences indirectly connected with the distribution of
the rainfall. But while the trees perished, the herbage and the grass
flourished ; and it is the converse of this which we see in the growth
of the forest, where, it may be, lichen and moss, and fern and sedge,
and grass and herbage, had successively, alone or conjointly, held
for a time exclusive possession of the field.

In further elucidation of this subject it may be mentioned that by
many it is held that, apart from all that has been alleged in regard
to evolution and development, there is a natural succession of plants
following each other in the occupation of the same ground, the homo-
logue of the natural succession of animals which have inhabited the
world, specified in Genesis as water animals and wingéd fowls, cattle
and creeping thing, and beast of the field and man,—and a struggle
for the possession of it between plants and possession by immigrants :
the homologue of man’s replenishing the earth and colonising with
immigrant families lands previously peopled by other races And
both in connection with the natural snccession and with the succes-
sion by immigration the distribution of rainfall has its function.

It is frequently alleged that the order of natural succession is some-
thing like this: the germ of a lichen, falling upon a rock or stone, it
may be, being moistened by rain, or dew, or a little water lying there,
germinated, produced other germs, and died. Some generations did,
it may be, the same, produced other germs, and died; subsequently,
it may be ages later, the germ of a moss, or of some other more
highy organised vegetable structure, fell there, and found in the
remains of decayed lichens a soil and the conditions favourable to its
germination and growth and reproductiun, and more favourable to its‘
continued reproduction than to that of the lichen, and ultimately it
obtained and maintained exclusive possession, it may have been for
ages, until some other germ or seed of some vegetable holding a still
higher position in the gradation of organic structures—a fern, it may
have been, a grass, a daisy, or some other herb, or all of these in
succession fell there, until at length on the accumulating soil there
appeared in succession, or in contemporaneous growth, a mass of
mixed and tangled vegetation, requiring only to be subdued by man
to make the soil composed of mineral constituents and decomposed
organic matter bring forth “fruits of increase” and “herbs meet for
them by whom it is dressed.”

DISTRIBUTION OF THE RAINFALL. 291

I do not like the expression “ struggle for possession” being applied
to vegetation ; I prefer making use of the corresponding expression,
“ survival of the fittest ;” bnt the expression “ struggle for possession ”
has come into more general use.

In illustration of what has been likened to a struggle for possession
between immigrants and earlier settlers, let me refer to what may
sometimes be seen, in our own day, on a flowery bank of one of our
hedge-rows, or by the side of a country walk. Let it be supposed
that the case is one in which the flowers consist mainly of dog violets
and of pansies in equal proportion. Any other plants would equally
serve for illustration ; these are selected of design. If such a bank
were revisited, after some years of absence, it might be found as
flowery as ever ; but the flowers would not be all of the same kinds,
in the same proportion, as before. Amongst other changes, it may be
that either the pansies or dog-violets would have disappeared, and
the species remaining would be more numerous than either were.
By transmutation or development? Oh, no! not at all; but thus:
the soil exposure, heat, and moisture could scarcely fail to be more
adapted to the requirements of the one than to those of the other:
in an infinitely minute degree it might be, but still the difference
was there; and even if the quantity of seed cast by each plant
should have been precisely equal, this infinitely minute difference of
adaptation would suffice to bring about the change.

I shall magnify the effect to make it more apparent. If there
were a hundred plants of each when first observed, in the year
following there might be 105 of the one and only 95 of the other ;
in the year after there would be the progeny of 105 plants of the one
and the progeny of 95 of the other less favourably situated species,
and this might present us, not with 110 of the one and 90 of the
other, but perhaps 112 of the one and 88 of the other; and the dis-
proportion in years following would go on increasing in a corre-
sponding accelerating ratio. And indications of something like this
having occurred in forests have been observed : a forest of mixed
trees giving place to one of uniform production. And thus may the
successions have occurred, while the seeds of trees which had not
germinated lay dormant, awaiting their time to germinate whenever,
in the changes accompanying progressive desiccation, the dominating
trees should succumb, and they be able with greater success to take
their place.

From a work by Vaupell we learn that the earlier forests of Den-
mark were composed of birches, oaks, firs, aspens, willows, hazel and

292 RELATION OF FORESTS TO THE

maple, the first three being the leading species, but these have now
been succeeded by the beech, which at present is the tree which
greatly predominates. It is a tree more inclined to be exclusive
than any other broad-leaved tree, but it is being encroached upon
again by the fir. And is there not acause? There is; and Vaupell
seems to consider that man is unconsciously—and to his own dis-
advantage—helping forward the encroachment of the Goths and
Vandals on the nobler races at present in possession. And the views
advanced by them may subserve our present aim.

In regard to the removal of fallen leaves he remarks :—‘“‘ The
removal of the leaves is injurious to the forest, not only because it
retards the growth of trees, but still more because it disqualifies the
soil for the production of particular species. When the beech
languishes and the development of its leaves is less vigorous, and its
crown less spreading, it becomes unable to resist the encroachments
of the fir. The latter tree thrives in an inferior soil, and being no
longer stifled by the thick foliage of the beech, it spreads gradually
through the wood, while the beech retreats before it and finally
perishes.” And in connection with this he adverts to the fact that
“ The leaves belong to the soil. Without them it cannot preserve its
fertility, and cannot furnish nutriment to the beech. The trees
languish, produce seed incapable of germination, and the spontaneous
self-sowing, which is an indispensable element in the best systems
of sylviculture, fails altogether in the bared and impoverished soil.”

Thus may the succession of firs to beeches, if it should ultimately
occur, be satisfactorily accounted for. And in a corresponding way
may some of the previous successions of different kinds of trees be
accounted for: I say not in the same way but in some corresponding
way ; and in some corresponding way may much of the grass and
herbage which previously covered the forest ground have given way
to the forest trees, not because the conditions were absolutely un-
favourable to them, but because being also favourable to the growth
of trees, and perhaps comparatively more so, or otherwise simply in
virtue of their more sturdy constitution, these having gained a footing
maintained it, and the others were overpowerea. Now one of the
conditions determining this was a particular distribution of the
rainfall both as to time and space, which was essential to the
growth of the trees which then existed, and but for whch the grass
-and herbage would have been left in undisturbed possession.

Such is in part the effect of the distribution of the rainfall on the
distribution of forests,

DISTRIBUTION OF THE RAINFALL. 293

Sor. IV.—On the Local Effects of Forests on the Distribution of the
Rainfall within the Forest District.

While the primary distribution of forests appears to have been
determined by the general distribution of the rainfall, forests appear
to influence the subordinate distribution of the rainfall, both in time
and space, over the forest district ; and irrespective of this, though
connected therewith, they exercise an important influence on the
disposal or distribution of the rainfall within the district in which
they exist.

The most manifest of the effects of forests on the rainfall is that
which they exercise upon the distribution of it after it has fallen.
Of the water which falls as rain a portion is evaporated, a portion is
absorbed by the ground, and a portion immediately flows back again
toward the sea; each of these is the complement of the others, and
their proportions vary under varying conditions; previous to the
growth of forests the rush was impetuous ; subsequent to the growth
of forests it is restrained. What was then allowed to run to waste,
like the extravagant expenditure of the prodigal, is now husbanded,
as is the income of the typical paterfamilias,

Cézanne, speaking of the whole series of phenomena brought under
review by him in treating of this effect of forests in connection with
geological changes, says in a passage I have cited in a volume on
“ Reboisement in France ” :—

“There may be given in a few words a résumé of the whole series
of these phenomena. t

“The mountains are the result of a series of upheavals following
one upon another in the same region, A final agitation gave to the
different chains of these the existing elevation ; it elevated the
summit and opened up deep fissures or divisions, which have become
the valleys of the present time. From the time this occurred the
waters began to fashion the thalwegs, following the line which best
suited them; wearing down outlets and filling up basins. It is
necessary to admit, or to assume, that the depth or thickness of
the alluvial deposits in the bottom of certain valleys—for instance,
those of the Isére in the Graisivaudan, or of the Rhine in Alsace,—is
to be reckoned by hundreds, and perhaps by thousands, of métres or
yards ; for even yet certain lakes existing in depressions of the Alps
have their bottom below the level of the sea.

“ After a long series of ages the mountains assumed the leading

294 LOCAL EFFECTS OF FORESTS

features which they now exhibit, when, the climate changing, great
glaciers carried on actively the work of erosion ; these have planed
away escarpments, and fashioned into something like horizontal lines
the rocky belts of the valleys.

“ Débdcles, or inundations, from the escape of the waters of pent-
up lakes, and deluges resulting from the tremendous rains of summers
on the extensive fields of ice, have carried away and deposited in the
principal valleys in certain favourable places, but more especially at
the débouchés of lateral gorges, the masses of less which have
formed cones in the higher plains, and in which the water-courses
have subsequently dug out the secondary valleys.

“At a later period, after the melting away of those glaciers, the
torrents seized upon the bared mountains ; and without restraint they
have dug out their basins, and have again taken up the materials
disintegrated by the glaciers, and deposited these in the gigantic
cones which give to certain regions a physiognomy peculiarly their
own.

“ But after a time the forests, spreading by degrees, stifled the waters
under a mantle of verdure ; the torrents became extinct,—an era of
peace and of comparative quiet supervened in the mountains; then
the tribes of men, who during the glacial period rambled over the
low-lying plains, in company with the reindeer, the aurochs, and the
bears, began to spread themselves in the high-lying valleys. The
most ancient settlements were made at the gorges of the torrents,
towards the summit of the cone; in point of fact, there are to be
found in the mountain valleys very few of these gorges in which we
do not meet either with an existing village or with an ancient ruin.

“Tn this location, which was then one favourable to their pursuits,
the primary inhabitants could profit by the exceptional fertility of the
cone of deposits ; they had nothing to fear from the principal river,
which flowed through the lower-lying lands, nor from the torrent,
which was then extinct; they commanded the plain, and found
themselves at the gate of the mountains; the adjacent gorge
supplied them with water, the forest supplied them with wood, the
rock supplied them with stone, and their flocks spread themselves
over the verdant ridges around them.

“Little by little, a reckless use of the forests and of the pasturage
disturbed the equilibrium of the natural forces; and now the old
sore is re-opened, and anew, by man’s deed, the mountains are
inoculated with the leprosy of the torrents, The evil has gone on
increasing during prolonged ages of disorder and recklessness; the

ON DISTRIBUTION OF THE RAINFALL. 295

position of the cultivated grounds, and of the villages established at
the débouchés of the torrents, has now become critical in the extreme ;
and unless we go back, as we have done, to the olden times, we are
unable to account for men having taken up their dwelling in the
spots, of all others, which at this day appear to be those which are
more immediately threatened. ,

“But at last an era of reparation begins; and, thanks to the
eminent men who have in bygone years given their mind to the
work, the next generation may hope to see the final decline of the
modern renewed Torrential Era.”

Views similar to the views thus advanced by Cézanne are advanced
by Costa de Bastelica, with this difference that he considers even the
mounds of detritus attributed to glaciers have been also the products
of torrents, which have become extinct under the effects of the
forests.

In illustration of how the forests may have operated, in those pre-
historic times, in arresting the flow of the rainfall, I adduce the
following, the type of many others which I have brought forward in
the volume referred to. It is from a paper which appeared in Revue
des Eaux et Foréts, for April 1866.

“The State possesses, in the department of Vancluse (says the
Forest Conservator, Labuissiére), a forest of more than 3000 hectares,
situated on a portion of the mountain Luberon nearest to the valley
of the Durance. This region is very much cut up, and traversed in
all directions by very narrow and deeply embanked ravines in the
midst of masses, more or less dense, of Aleppo pines and green oaks.

“These ravines are almost the only outlets for the transport of
woods, in consequence of the difficulties which would be encountered
and the expense which would be incurred in making more practicable
ones on the rapid declivities, strewn with enormous masses of rock.
There exists one so situated, called the Ravine de Saint-Phalez.
The direction is from north to south, in the midst of a mass of Aleppo
pines in a state of growth more or less compact.

“Tts length, and for four kilométres, or from the road from
Cavaillon to Pertuis, to the domain of Saint-Phalez, of an area of
about 50 hectares, forms the bassin de réception of the torrent.

“This land is well cultivated ; there are no declivities too steep for
cultivation ; it comprises vineyards, meadows, and arable land; the
soil is argillaceons

“The ravine of Saint-Phalez receives many affluents, the most

296 LOCAL EFFECTS OF FORESTS

important of which is that of the Combe d’Yeuse, which joins it near
the summit, where are some hundred métres of the cultivated grounds
of which I have spoken.

“The Ravine de la Combe-d’Yeuse is of much less considerable
length than that of Saint-Phalez; it is scarcely two kilometres. It is
strongly embanked, surmounted by steep declines, covered with green
oaks of eight or ten years growth and with Aleppo pines of different
ages. Its bassin de réception, of about 250 hectares (or 113 acres),
comprises the whole slope, precipitately inclined, with a general
southwest aspect ; it is closed at the top by a deep bed of rock cut
into peaks of the most imposing aspect.

“The geological formation is absolutely the same, as are all the
other conditions, at all the points which I have examined. In no
part is to be seen either spring or appearance of humidity ; no water
is seen excepting at the time of storms or great rains, and this water
goon passes away, with the differences which will afterwards be men-
tioned. At all other times these ravines are of a desolating-aridity.

“Tn the night of the 2d or 3d of September, 1864, there fell a
rather abundant rain over all this portion of the mountain. In the
morning the argillaceous grounds of Saint-Phalez were saturated, of
which evidence was found by anyone attempting to cross them. The
ravine of Saint-Phalez, the receptacle of the surplus water, had flowed
but slightly ; that of the Combe-d’Yeuse remained dry.

“The day of the 4th September was very warm; a water-spout
borne along by a southwest wind struck on the Luberon. Its passage
did not last more than forty minutes ; but scarcely had it come when
the torrent of Saint Phalez became awful. Its maximum delivery
was about two cubic métres. It did not flow more than fifty minutes,
but with an average delivery of half a cubic métre; it had then
passed in all 15,000 cubic métres of water; its height had been
0:04", Each square metre had received 40 litres, and the 50 hectares
of Saiut-Phalez 20,000 cubic metres. The ground had only retained
5000, which is sufficiently explained by their argillaceous character
and their state of saturation the night before. But while the torrent of
Saint-Phalez flowed, filled from bank to bank, seizing and carrying off
rocks which had been employed to form a road which was believed to
be safe against all contingencies, that of the Combe-d’Yeuse and all
those traversing wooded lands remained dry, or gave only an insignifi-
cant quantity of water.

“On the slope opposite to that of which I have been speaking, in
the valley of the Peyne, a carriage-road newly formed did not ex-

ON DISTRIBUTION OF THE RAINFALL. 297

perience the least injury throughout the whole of the portion of it
passing through tne forest of the domain; but at its issue, on the
lands of the Libaude and of the Roquette, it had been, so to say,
destroyed. A cart loaded with faggots was upset and smashed by
the waters, which flowed from all the cultivated slopes, and tore
along, with the noise of thunder, at the bottom of the ravine.

“ My good fortune secured to me another subject of study on the
same ground.

“On the 25th October following I went 1o the sale of the fellings
of the Tarascon, where there fell an abundant rain. The next day
(the 26th) the weather was clouded. I set off for the Luberon in the
hope of arriviug there at the same time as would a storm of rain
which I saw approaching. I arrived first ; the ravine of Saint-Phalez
was still moist, from the passage in small quantity of the waters of
the night before; they had served, as appeared, to saturate the
lands of the domain, as had previously happened on the 7th [3rd 4]
September.

“TJ had scarcely gone over two kilométres in the ravine when the
water began to rush with great violence; ten minutes later it pre-
cipitated itself in its ordinary canal d’ecoulement, completing the
work of destruction begun in the month of September. The lands of
Saint-Phalez had then absorbed but little or none of the water that
day.

“The storm was not of long duration—an hour at most. The
time was unfavourable for collecting on the ground exact measure-
ments, but J reckon that the torrent delivered, at its maximum,
somewhat less water, perhaps, than on the 4th of September. The
flood, however, was more frightful; it swept away rocks with so
much the greater ease that nothing had been repaired since the first
storm, which had left the stones dug out, and without bond of co-
hesion among themselves.

“To gain the forester’s house, which was on the slope of the left
bank, it was necessary to make a long circuit—to go round the
domain of Saint-Phalez, and to cross the grounds belonging to it, in
which one sank to the depth of 0:30 métres, or twelve inches. Before
arriving at my home I had still before me the ravine of the Combe-
d’Yeuse, and I feared I should be stopped there by a new obstacle.
I was agreeably surprised to find it dry. An hour after the storm
the ravine of Saint-Phalez had ceased to flow.

“Tt rained throughout the whole of the 28th without there being
anything to remark similar to what had happened on i a

K

298 LOCAL EFFECTS OF FORESTS

days. The only effect of this was that, on the evening of the 30th,
near the forester’s house, and at 200 or 300 métres from the ravine
of Saint-Phalez, there was seen coming down, in that of Yeuse, a
small fillet of clear water; its volume increased perceptibly during
three days, to diminish in like manner during the two which followed;
its passage broke down a little of the foot-path which goes along the
valley, but caused only a damage easily repaired. This foot-path did
not present the same solidity of structure as that of the Combe de
Saint-Phalez, built on enormous blocks of rock which had stood for
several years, and which had allowed of passage with a waggon some
days before its destruction by the storm in September. If the
Combe-d’Yeuse had yielded as much water as that of Phalez, and if
these two masses of water had come at the same time, the damage
caused in the plain would have been considerable, and the Durance,
which received these waters, would have been so much the larger.

“Thus we have two torrents very near and under the same condi-
tions—except that the basin drained by the one comprises 50 hectares
of cultivated lands, that of the other 250 hectares of woodlands. The
first receives, and allows to flow away, the waters of the greater part
of a storm in a few hours at most, causing thereby considerable
damage ; the second, which had received a greater quantity of rain,
stores it—kéeps it for two days—evidently retaining a portion of it,
and takes three or four days to yield up the surplus, which it does in
the form of a limpid and inoffensive stream,”

A question in connection with this subject, which excites much
general interest, is—Do woods and forests increase the quantity of
the rainfall? We have had testimony to the affect that in certain
conditions they increase the quantity of the local rainfall; there is
no evidence that in consequence of this there is a diminished rainfall
elsewhere, and if there be not it follows as a consequence that they
do increase the rainfall, though it should be found that they do so
only by causing the same material to fall again and again in the form
of rain; but the increase, whether tested by local observations care-
fully couducted as were those of Mathieu, and of which have been
cited, [ante p. 64] or by more general observations carefully collected
as were those discussed by Mr Draper, [ante p. 100] appears to be very
trifling ; and when there are brought under consideration such features
of physical geography as are referred to by Cézanne and by Costa de
Bastelica, and attributed to torrents occasioned by the rainfall previous
to the régime of forests in the locality, it may well be doubted whether

ON THE RAINFALL. 299

the amount of rainfall all the world over has not been diminished rather
than increased since was issued the fiat: Let the earth bring forth
grass upon the earth—the herb yielding seed, and the fruit tree
yielding fruit after its kind whose seed is in itself.

I have quoted the statements of Herr Wex in regard to the local
effects of forests on the rainfall, given in his treatise on the “ Diminu-
tion of Water in Streams and Rivers, with the increase at the same
time of occasional inundations in low-lying agricultural districts. ”

The Commission appointed by the Academy of Science at Vienna,
appointed to consider that treatise and to report, reported in regard
to the effect of forests on the rainfall as follows :—‘ The influence of .
forests on the quantity of the rainfall is a subject which has engaged
the attention of many naturalists. From many different pvints of
view has this influence been discussed, the discussion being founded
partly on theoretical considerations, partly on the altered climatal
conditions of country in which forests have been destroyed.

“Tn connection with theoretical considerations it has been ex-
tensively maintained that forests arrest the floating clouds, as do
mountain ranges opposed to a current of clouds, and like these occa-
sion a condensation of moisture ; and further that by the relatively
lower temperature prevailing ina forest than in the open country, thus
occasion a precipitation of that moisture in the form of rain; and in
reference to this point more especially has Dr Berger in Frankfort
devoted attention to the difference in favour of rainfall in the
temperature and condition of moisture in the forest, in comparison
with these in the open country.

“It is on the whole probable that some such influence is produced
by forests; but perhaps on the one hand the importance of this in-
fluence has been over-estimated ; and on the other hand there is a lack
of direct and decisive proof as to the effect ; as the pluviometrical
observations made for this purpose in stations within and outside the
forests extend over too short periods, and to some extent have been
made in conditions or circumstances which do not admit of strict
comparison, such as the difference in condition at different eleva-
tions, inclinations, and exposures in different directions, é&c.

“From the great importance, in the interest of agriculture, of the
alleged diminution in the rainfall, the Scottish Meteorological Society
decided, in 1859, at the request of their president, the Marquis of
Tweeddale, to offer a prize for an essay on the question, Whether any
change had occurred in the quantity of rainfall in the-west of Europe,

300 EFFECTS OF FORESTS

The successful essayist, Mr F. H. Jamieson, found in the observations
of the rainfall over extended periods, to which he had access, no
reason to conclude that there had been any progressive diminution in
the rainfall ; local oscillations alone were apparent, and the causes of
these it would be difficult to determine.

“This essay gave occasion for the institution of other similar in-
vestigations; and algo for the establishment, through the British
Association for the Advancement of Science, of a number of stations
for the observation of the rainfall in different parts of Great Britain
and Ireland. And a committee was appointed by the Association to
give attention to the subject.

“Mr G. J. Symons, in London, undertook the inspection of the
stations and the collating of the observations reported.

“Observations made at several stations in England and Scotland;
‘of which Mr Symons was enabled to avail himself in the investigation,
extended back to 1726.*

“ Thanks to the observatory at Paris, we have still earlier observa-
tions, carrying us back to the year 1688.+

“ According to observations made in England and in France there
is no evidence of a diminution in the annual rainfall ; but on averages

.of ten years there are seen differences in the quantity of the rainfall,
the causes of which have not yet been determined.

* He gives in the Report of the British Association for 1866, by means of registers
received from seventeen stations, the following data iu regard to the rainfall in England
in proportional measurements :—

Period. Proportional measurement. Period. Proportional measurement.
1726-1735 ee 86-7 1806—1815 94 ot 99-3
1736—1745 787 1816 —1825 103-9
1746—1755 78 oh 83°5 1826 —1835 1013 199-8
1756—1765 882 1836—1845 100-29
1766—1775 eo 98°4 1846—1855° peri 98:5
1776—1785 93-2 1856—1865 26°3
1786—1795 96 a 93°2
1796—1805 897

Tf In the Annuaire météorologique de U Observatoire physique central pour 1873, Marié
Davy gives the followlng calculation of the annnal rainfall at Paris :—

Period. Average in milliméejres. Period. Average mm,
1688—1700 517 1791—1798 413
1701—1710 481 1804—1810 518
1711—1720 465 1811—1820 496
1721—1730 378 1821— 1830 514
1731—1740 411 1831—1840 507
1741—1750 420 1841—1850 529
1773~—1780 540 1851—1860 520

1781—-1790 507 1861—1870 493

ON THE RAINFALL. 301

“Tt would be rash to conclude, from the fact that no permanent
change in the direction spoken of has been proved to have occurred
in the west of Europe, that no alteration of the kind has taken place
in the interior of the continent; and there are certain pluviometrical
records made at continental stations which do not indeed go so far
back, but which also, so far as they go, are not unfavourable to the sup-
position of some such diminution having occurred.*

“ Blodget arrived at a similar conclusion from an examination of
pluviometrical observations in North America; although the destruc-
tion of forests had been carried out there to such an extent that a
change in the rainfall might have been expected.

“In reference to the older observations of the rainfall we must
observe that their value is very much diminished by the circumstance
that the observations were not made every day, but sometimes at long
intervals ; besides which, the rain-gauges were often placed in unsuit-
able localities, ag on roofs and on towers, &c. Both of these circum-
stances would produce an effect in the same direction, giving returns
of less than the actual rainfall at the time at which ,they were
made.—

“Tn view of all the facts of the case, although the actuai measure-
ments of the rainfall, extending back for 200 years, cannot be adduced
as evidence of any progressive diminution in the quantity of the rain-
fall, it would not be right to attach no weight to the facts brought
forward by the author, more especially from Milne Home’s paper in
the Journal of the Scottish Meteorological Society, (vol. III. p. 35)
from Becquerel, (Atlas méteorologique de [ Observatoire de Paris, pour
1867) and from a great many other sources, which tend to prove a
deterioration in climate to have taken place in consequence of the
extensive destruction of forests.

“The Commission agrees with him in considering that 2 is pro-
bable, forests have an influence on the quantity of the rainfall, and
especially on the distribution of the rainfall over the year, although
the direct observations in our possession do not as yet seem sufficient
to determine the extent of that influence.”

I am quite aware that there are facts recorded which appear to

*In the Imperial Central-Anstalt fir meteorologie have the obervations in about
120 stations in Europe and North America, been examined on this point.
*On the effect of altitude on the returns of the rain-gauge there are numerous state-
ments, In Méllendorfs works (p. 102) it is shown that at diffsrent stations the lower
rain-gauge received from 13 to 60 per cant, more rain than on a higher place one did.

302 DISPUTED EFFECTS OF FORESTS

point to a different conclusion from that which is thus announced.
But I have to say in reference to this, that it was implied in or covered
by the instructions given to the Commission to consider this matter
and to report; and further, that I find no difficulty in accounting
for any of the apparently conflicting facts referred to, without com-
promising the conclusion arrived at by the Commission, and I know
of numerous facts in accordance with that conclusion.

M. E. Renou, in a paper entitled Théorte de la pluie, which ap-
peared in the Annuaire de la Société Météorologique de France (t. xiv.
p. 89, 1866), writes :—‘‘ When it is seen that the rain depends as its
condition on great atmospheric movements, and is only modified by
the principal accidents of soil, mountains, and seas, what influence
can the cultivation by man, and more especially the forests, have
upon this phenomenon? A generally-existing opinion attributes to
them an important influence on the distribution of the moisture pre-
cipitated from the atmosphere; but this opinion, which is purely
theoretic, has absolutely no foundation: there never has been cited
in support of it a single indisputable observation, and if in certain
lands, as Algeria, it rains more on forests than on the lands devoid
of these, in attributing to them an influence on the rain this is only
to confound the effect with the cause. The rainfall follows in a striking
manner the relzef of the soil, and forests appear nowhere spontaneously
excepting where there is a sufficiency of rain. This observation is
applicable to the analogous cases cited by M. Boussingault in America.
It is precisely at the line of contact of the bare regions and the
wooded regions near the limits of the natural growth of woods that
this can be remarked ; these forests do not generally receive sufficient
rain for them to grow everywhere, and they are found only there
where the position and arrangement of the mountains permit the soil
to receive the greatest quantity of water.

“Charts representing courses followed by storms of rain and storms
of hail do not indicate the least deviation from their course in the
vicinity of forests. The celebrated hail-storm of the 13th June 1788
has long ago shown this to be the case; it followed a line almost
straight, absolutely independent of what was seen on the soil
beneath it.

“The opinion in regard to the influence of forests on rain is just
like all prejudices: it has been repeated for a considerable length of
time without having the least proof. In my opinion, man has not
the least influence on natural phenonena. Formerly, it was sought
to connect meteorological phenomena with dominant local influences ;

ON THE RAINFALL. 303

but, in proportion as the study of them extended, the magnitude,
grandeur, and general character of atmospheric phenomena came to
be recognised.”

In citing these views of M. Renou I am citing what has been cited
in France with approval; and there is much in them with which I
agree, but this so combined with much with which I do not agree
that Iam almost glad to have the opportunity to state wherein we
differ.

T have given evidence of my belief that the primary distribution of
forests is attributable to the previous geographical distribution of the
rainfall; but I consider that this is not incompatible with their
exercising an influence on the subordinate subsequent distribution of
the rainfall within the district in which they have grown: in
other words, that while the primary distribution of forests appears to
have been determined by the rainfall, once established, they may, and
they do, exercise a manifold influence on the rainfall. Sinbad’s
adventures with the Old Man of the sea, and Aisop’s fable of the
horse being saddled and bridled by man, have made us acquainted—
many of us while yet young, acquainted—with the principle that con-
sequences may flow from an action which were not anticipated when
that action was performed. The Spaniards havea proverb to the
effect that Whoever gets a wife gets a master. The Scotch have
another version of the same proverb which is not less pat: their
version of it is—Whoever gets a man gets a master. And in many
lands it is seen that a family often produces on both of the parents a
very marked change of habit. So is it here, the mountains once
clothed with forests, all is changed, And it is to what takes place in
this altered condition that the report cited refers.

M. Renou seems to attach importance to storms of rain and storms
of hail advancing in a direct line, deviating from this in passing near
by a forest. On this subject M. Cézanne writes:—On charts
which have been published by the Academy M. Becquerel has re-
presented the course of certain [thunder] storms. Some people have
thought that they could conclude from these charts that storms avoid
forests. But it should be remarked that these charts having been
prepared from testimony supplied by populations and Assurance
Companies, the abundance of documents establishing the devasta-
tions caused by the hail is not necessarily in exact relative propor-
tion of the frequency and violence of these storms: it depends more
especially on the density of the populations and the richness of the
crops. If the wooded regions do not supply documents towards

304 DISPUTED EFFECTS OF FORESTS

establishing the statistics of storms, it is because in the forests there
are neither notable devastations committed by them nor inhabi-
tants to report them.

“The department of the Gironde furnishes a striking case in
support of this explanation. According to the storm chart of this
department (Atlas meteorologique, 1868) the hail would seem to fall
by preference on the banks of the Garonne, or in the rich canton
which extends between that river and the Dordogne, but particularly
on the inhabited places; and, on the contrary, that the desert landes
were entirely spared by the hail.

“But it is well known that the dandes are traversed by violent
storms ; but the shepherds of the dandes do not send bulletins to the
Observatory. !” ;

So much in regard to storm-charts such as are cited by M. Renou,
In regard to the kind of storms referred to by him, they are such as
were not likely to deviate from the cause in consequence of any such
difference on the surface of the earth as a forest might present.

Of the hailstorm cited by M. Renou, Sir John Herschel writes :—
“Tn the hail-storm of July 13th, 1788, which passed across France
from south to north, two such tracks were marked, of 175 and 200
leagues in length respectively, parallel to each othar, the one four
leagues broad, the other two, and separated by a track five leagues
in breadth, in which only rain fell. A similar character is very com-
mon, though not to such an extent. Such linear hail-storms are
always attended with violent wind, sudden depression of the baro-
meter, indicating a great commotion in the air, and probable mingling
of saturated masses of very different temperature.

And in writing on the Hydrology of South Africa, I had occasion to
state: “According to views advanced by Espy, a distinguished
American meteorologist, the two parallel lines along which the hail-
storm advanced in the case mentioned by Sir John Herschel can be
satisfactorily accounted for. According to one of the laws regulating
storms, many of these advance, as does a wheel, rotating and pro-
gressing horizontally—as a wheel does vertically in advancing along
a road—as is made visible in a small advancing whirlwind of dust, or
leaves, or straw, or chaff. The cyclone, a whirlwind of such extent
as to create a storm, is fed with air as it advances; this, raised to a
great height, expands, cools, precipitates the moisture it contained,
and throws this off in a frozen state—as does a twirled wet mop
throw off drops of water,—and by gravitation it falls. As the rotating
whirlwind advances, the motion of the air forming the forefront will

ON THE RAINFALL. 305

cross the breadth of the circle from left to right, or from right to left,
as the case may be; the air forming the rear will cross the breadth
of the circle in the opposite direction, and scatter the hailstones or rain
over the whole breadth traversed in two showers, minutes, hours, or
days apart; but at the sides the wind blows in but one direction
on the right of the circle, and in one direction, the opposite of this,
on the other, and along the lines followed by these the hail or rain
falls continuously in greater abundance.”

M. Cézanne writes in reference to what he had stated relative to
the fall of rain being determined in a great measure by the contour
of a country, and which I have already quoted :—

“Tt may be said—if the rain acted as if it had caprices and the
protuburances of the soil caused a change in the pluvial current—
will a mass of forests which raises itself on the plain remain without
any influence? Stating the question thus, it must be admitted as un-
questionable that forests may exercise an influence on the rainfall. It
may so happen, for example, that a forest of trees coming to bar up a
valley of little depth may interrupt the pluvial current, and notably
diminish the quantity of water collected in a pluviometer which would
be placed behind it. The town of Erfurt, for example, sheltered
against the west wind by the Thuringian forest, receives less rain than
do adjacent regions.* It is not necessary to speak of a high forest of
timber trees ; a simple wall, suitably disposed, suffices, It is well
known that the face of such a wall, exposed to the pluvial wind, re-
ceives more rain than does the sheltered side,—what is kept on the
one side falling there leaving so much the less to fall on the
other ; and observations show that it is enough to raise up buildings
or other erections in the neighbourhood of a pluviométer to produce
a change in its receipts.”

But the hail-storm cited by Renou was not a fall of rain produced
by a pluvial wind blowing along the surface. The hail was produced
at an elevation far above the loftiest forest, where the forest could
not produce such a deviation as he states did not occur.

And with regard to his belief that it is beyond the power of man
to exercise the least influence over physical phenomena, the expression
given of it would require some qualification in order to exempt at least.
such physical phenomena as are mentioned by M. Cézanne in the state-
ment by him which I have just cited, and who holds the same opinions
as does M. Renou on the point to which I understand him to refer.

* Kaemitz.
Qu

306 EFFECTS OF FORESTS ON RAINFALL.

So far as my own observations have gone it is in accordance with
what has now been advanced. My observations have been made
incidentally and not of purpose, and they are general rather than
precise. They have been made, one class of them in Scotland, the
other in Africa, or countries which are in very different climatal condi-
tions, and for this it may be considered by some that some allowance
should be made; but such as they are they are these : While.the genial
shower or the drizzling mist appears to be a characteristic of wood-
land rain, deluges of rain like thunder plumps are the forms which I
have found most characteristic of rain in the arid regions of South
Africa ; frequent showers and constant damp in spring and autumn
and winter alike are characteristic of woodlands in Britain with which
IT am familiar, a cloudless sky, and a persistent drought broken only
by an occasional deluge, brief in its duration and local in its range,
are the characteristics of the other. In the one we have the rainfall
distributed over eight or ten months of the year, with occasional
showers in the course of the intervening summer; in the other a
drought continued for months, or it may be for years, and a rainfall
of two days or three, or of some hours, or it may be of half an hour at
most. In the one we may have the rainfall distributed over the whole
of the area of a hundred or a thousand square miles, falling not over
the whole simultaneously or continuously, but so distributed in time
as well as in space that no part suffers lack ; in the other we may
have a deluge of rain over twenty square miles at one time within an
area of a thousand, and a deluge over other twenty square miles
at another time, weeks or months, or it may be years thereafter.

The geographical distribution of rain may be attributable to geo-
graphical position and contour of the country. Such deluges of rain
as have now been referred to may be attributable in some cases. to
eddies in one or other of the aerial currents flowing continuously be-
tween the equator and the poles; in other cases to the passage of
a minor cyclone or whirlwind above the place; but the frequent
drizzling genial showers prevailing in a wooded country may be con-
sidered a form given to the rainfall in some measure by an influence
of the woods; and the absence of these in arid woodless regions, in
which the mean annual rainfall is the same and the conditions similar,
may be considered in a corresponding manner attributable to the
absence of forests,

CONCLUSION.

We are told in the book of Proverbs: “ He that is first in his own
cause seemeth just ; but his neighbour cometh and searcheth him.”
I have stated in preceding chapters, with such precision as I could
attain unto, what I consider to be the effect of forests on the humidity
of the soil and character of the districts in which they exist; but I
am aware that a compilation might be prepared of observations made
by men of science which might seem to support a widely-different
conclusion. I have given attentive consideration to all such to which
I have had access, and prepared a statement on their apparent bear-
ing on what I have advanced; but I refrain from inserting this,
not because I consider them unimportant, for I consider them equally
valid and equally important with many—I may say with any—which
Thad advanced. I refrain from inserting this first, and mainly, because
I am unwilling to add to the expense and the bulk of the volume; 2ndly,
and the reason weighs with me almost as much as the first, I wish to.
present the subject to my readers in as simple a form as I can, and
without complications which I do not consider necessary for my pur-
pose ; and I know of nothing which has been advanced as observations
made, or conclusions deduced by reasoning, or phenomena observed,
which are incompatible with what I have advanced.

From what has been advanced it appears to be established as a fact
that there are cases in which an extensive destruction of forests has
been followed by a marked desiccation of soil and aridity of climate,
and some cases in which the replanting of trees has been followed
by a more or less complete restoration of humidity,—or the planting
of trees where there were none has been followed by a degree of
humidity greatly in excess of what had previously been observed ;
that there are cases in which the rainfall within forests, or in their
immediate vicinity, has been perceptibly greater than in the open
country beyond ; but that there are also cases in which it is alleged
that the desiccation of some lands once clothed with forests and

308 CONCLUSION,

fertile, now treeless and barren and dry, may be attributable in part,
if not in whole, to other causes besides the destruction of the forests,
and cases in which the extensive destruction of forests does not
appear to have extensively affected the quantity of the rainfal) over
a wide expanse of country. .

These facts may, by a little latitude in the use of language, be
characterised as antagonistic or conflicting ; but they may neverthe-
less be accepted as facts, and that with the admission that if facts
they must be perfectly compatible with each other, and not only
compatible but consistent with each other in the actually existing
system of things, and necessary to be known in order to a correct con-
ception of this system as a whole.

As it is with these apparently conflicting facts which I have cited
so does it appear to me to be with those apparently conflicting facts,
connected with details, which I have refrained from bringing forward
here: they do not appear to me to invalidate in any way those which
have been founded on in the conclusions I have advanced.

When I was a boy I was told of one of my townsmen, that, being on
trial before one of the magistrates for the theft of a hen, when a
witness testified that he had seen him take it, he broke forth with a
vehement appeal “ Your honour ! I can bring forward twenty men who
did not see me.” And to such testimony might be likened testimonies
to facts which are not in question cited as sufficient to invalidate
explicit testimony to other facts observed. I am prepared to admit
unhesitatingly all that can reasonally be said in regard to my accept-
ance as facts of what I have accepted as such; the conclusions I
have drawn from them I commend to the consideration of my readers ;
and I leave to their judgment to determine to what extent these should
influence deliberations on the adoption of practical measures to avert
the evil and to secure the good which appear to be at our command.

The effects of forests in retarding the flow of the rainfall after its
precipitation has been established, I consider, beyond all question ;
and not less so their effect in maintaining a general humidity of
atmosphere and of soil.

GG AS
WS

\